Your search keyword '"S, Zhu"' showing total 545 results

1. Spatial–temporal variations in riverine carbon strongly influenced by local hydrological events in an alpine catchment

Author

X. Wang, T. Liu, L. Wang, Z. Liu, E. Zhu, S. Wang, Y. Cai, S. Zhu, and X. Feng

Subjects

Hydrology, chemistry.chemical_classification, QE1-996.5, Biogeochemical cycle, Topsoil, Ecology, 010504 meteorology & atmospheric sciences, Biogeochemistry, Geology, STREAMS, 010501 environmental sciences, 01 natural sciences, Life, chemistry, QH501-531, Dissolved organic carbon, Soil water, Environmental science, Organic matter, Surface runoff, QH540-549.5, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Headwater streams drain >70 % of global land areas but are poorly monitored compared with large rivers. The small size and low water buffering capacity of headwater streams may result in a high sensitivity to local hydrological alterations and different carbon transport patterns from large rivers. Furthermore, alpine headwater streams on the “Asian water tower”, i.e., Qinghai–Tibetan Plateau, are heavily affected by thawing of frozen soils in spring as well as monsoonal precipitation in summer, which may present contrasting spatial–temporal variations in carbon transport compared to tropical and temperate streams and strongly influence the export of carbon locked in seasonally frozen soils. To illustrate the unique hydro-biogeochemistry of riverine carbon in Qinghai–Tibetan headwater streams, here we carry out a benchmark investigation on the riverine carbon transport in the Shaliu River (a small alpine river integrating headwater streams) based on annual flux monitoring, sampling at a high spatial resolution in two different seasons and hydrological event monitoring. We show that riverine carbon fluxes in the Shaliu River were dominated by dissolved inorganic carbon, peaking in the summer due to high discharge brought by the monsoon. Combining seasonal sampling along the river and monitoring of soil–river carbon transfer during spring thaw, we also show that both dissolved and particulate forms of riverine carbon increased downstream in the pre-monsoon season due to increasing contribution of organic matter derived from thawed soils along the river. By comparison, riverine carbon fluctuated in the summer, likely associated with sporadic inputs of organic matter supplied by local precipitation events during the monsoon season. Furthermore, using lignin phenol analysis for both riverine organic matter and soils in the basin, we show that the higher acid-to-aldehyde (Ad/Al) ratios of riverine lignin in the monsoon season reflect a larger contribution of topsoil likely via increased surface runoff compared with the pre-monsoon season when soil leachate lignin Ad/Al ratios were closer to those in the subsoil than topsoil solutions. Overall, these findings highlight the unique patterns and strong links of carbon transport in alpine headwater catchments with local hydrological events. Given the projected climate warming on the Qinghai–Tibetan Plateau, thawing of frozen soils and alterations of precipitation regimes may significantly influence the alpine headwater carbon transport, with critical effects on the biogeochemical cycles of the downstream rivers. The alpine headwater catchments may also be utilized as sentinels for climate-induced changes in the hydrological pathways and/or biogeochemistry of the small basin.

Published

2021

2. Tribological characteristics of the dual titanium boride layers (TiB2+TiB) on titanium alloy

Author

Y. S. Zhu, Wen Zhuang Lu, Dong Sun, Xing nong Wei, Yun fei Liu, and Tae Jo Ko

Subjects

010302 applied physics, Materials science, Process Chemistry and Technology, Whiskers, Titanium boride, Uniaxial compression, Titanium alloy, 02 engineering and technology, Tribology, 021001 nanoscience & nanotechnology, 01 natural sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Shear (sheet metal), 0103 physical sciences, Materials Chemistry, Ceramics and Composites, Composite material, 0210 nano-technology, Layer (electronics), Boriding

Abstract

In this study, by producing the dual titanium boride (TiB2 +TiB) layers (DTBLs) on titanium alloy using solid-state boriding with rare earth additions (REs), the friction tests with two different counter-materials (GCr15 and Al2O3) were conducted. It is found that solid-state boriding of titanium alloy with REs can achieve better tribological properties than that of conventional one, without REs; furthermore, with the size of TiB whiskers decreasing, the tribological properties was further improved. To illustrate the size effect of TiB whiskers on the tribological properties, a novel surface uniaxial compression model of DTBLs was developed; then, a surface wear model using Archard wear equation was proposed to quantitatively estimate such size effect of TiB whiskers. It indicates that the above two models can adequately explain the mechanism of the size effect of TiB whiskers on the mechanical and tribological properties. The results of this study showed that the improvement of tribological performance of DTBLs was dominated not only by the “hard” TiB2 layer but also by the “soft” shear accommodating TiB layer; when the size of TiB whiskers is closed to the sub-micron scale, fine-grain strengthening effect would become obvious, causing the tribological properties further improved.

Published

2021

3. Modeled changes in source contributions of particulate matter during the COVID-19 pandemic in the Yangtze River Delta, China

Author

J. Ma, J. Shen, P. Wang, S. Zhu, Y. Wang, G. Wang, J. Chen, and H. Zhang

Subjects

Delta, Atmospheric Science, 010504 meteorology & atmospheric sciences, Physics, QC1-999, 010501 environmental sciences, Particulates, Atmospheric sciences, 01 natural sciences, Aerosol, chemistry.chemical_compound, Chemistry, Nitrate, chemistry, Beijing, Environmental science, Sulfate, Air quality index, QD1-999, 0105 earth and related environmental sciences, CMAQ

Abstract

Within a short time after the outbreak of coronavirus disease 2019 (COVID-19) in Wuhan, Hubei, the Chinese government introduced a nationwide lockdown to prevent the spread of the pandemic. The quarantine measures have significantly decreased the anthropogenic activities, thus improving air quality. To study the impacts caused by the lockdown on specific source sectors and regions in the Yangtze River Delta (YRD), the Community Multiscale Air Quality (CMAQ) model was used to investigate the changes in source contributions to fine particulate matter (PM2.5) from 23 January to 28 February 2020, based on different emission control cases. Compared to case 1 (without emission reductions), the total PM2.5 mass for case 2 (with emission reductions) decreased by more than 20 % over the entire YRD, and the reduction ratios of its components were 15 %, 16 %, 20 %, 43 %, 34 %, and 35 % in primary organic aerosol (POA), elemental carbon (EC), sulfate, nitrate, ammonium, and secondary organic aerosol (SOA), respectively. The source apportionment results showed that PM2.5 concentrations from transportation decreased by 40 %, while PM2.5 concentrations from the residential and power sectors decreased by less than 10 % due to the lockdown. Although all sources decreased, the relative contribution changed differently. Contributions from the residential sector increased by more than 10 % to 35 %, while those in the industrial sector decreased by 33 %. Considering regional transport, the total PM2.5 mass of all regions decreased 20 %–30 % in the YRD, with the largest decreased value of 5.0 µg m−3 in Henan, Hebei, Beijing, and Tianjin (Ha-BTH). In Shanghai, the lower contributions from local emissions and regional transmission (mainly Shandong and Ha-BTH) led to the reduced PM2.5. This study suggests adjustments of control measures for various sources and regions.

Published

2021

4. Emission inventory of air pollutants and chemical speciation for specific anthropogenic sources based on local measurements in the Yangtze River Delta region, China

Author

J. An, Y. Huang, C. Huang, X. Wang, R. Yan, Q. Wang, H. Wang, S. Jing, Y. Zhang, Y. Liu, Y. Chen, C. Xu, L. Qiao, M. Zhou, S. Zhu, Q. Hu, J. Lu, and C. Chen

Subjects

Delta, Pollutant, Atmospheric Science, Ozone, 010504 meteorology & atmospheric sciences, business.industry, Xylene, Chemical industry, 010501 environmental sciences, 01 natural sciences, Ethylbenzene, lcsh:QC1-999, Aerosol, lcsh:Chemistry, chemistry.chemical_compound, lcsh:QD1-999, chemistry, Environmental chemistry, Environmental science, Emission inventory, business, lcsh:Physics, 0105 earth and related environmental sciences

Abstract

A high-resolution air pollutant emission inventory for the Yangtze River Delta (YRD) region was updated for 2017 using emission factors and chemical speciation based mainly on local measurements in this study. The inventory included 424 non-methane volatile organic compounds (NMVOCs) and 43 fine particulate matter (PM2.5) species from 259 specific sources. The total emissions of SO2, NOx, CO, NMVOCs, PM10, PM2.5, and NH3 in the YRD region in 2017 were 1552, 3235, 38 507, 4875, 3770, 1597, and 2467 Gg, respectively. SO2 and CO emissions were mainly from boilers, accounting for 49 % and 73 % of the total. Mobile sources dominated NOx emissions, contributing 57 % of the total. NMVOC emissions, mainly from industrial sources, made up 61 % of the total. Dust sources accounted for 55 % and 28 % of PM10 and PM2.5 emissions, respectively. Agricultural sources accounted for 91 % of NH3 emissions. Major PM2.5 species were OC, Ca, Si, PSO4, and EC, accounting for 9.0 %, 7.0 %, 6.4 %, 4.6 %, and 4.3 % of total PM2.5 emissions, respectively. The main species of NMVOCs were aromatic hydrocarbons, making up 25.3 % of the total. Oxygenated volatile organic compounds (OVOCs) contributed 21.9 % of the total NMVOC emissions. Toluene had the highest comprehensive contribution to ozone (O3) and secondary organic aerosol (SOA) formation potentials, while other NMVOCs included 1,2,4-trimethylbenzene, m,p-xylene, propylene, ethene, o-xylene, and ethylbenzene. Industrial process and solvent-use sources were the main sources of O3 and SOA formation potential, followed by motor vehicles. Among industrial sources, chemical manufacturing, rubber and plastic manufacturing, appliance manufacturing, and textiles made significant contributions. This emission inventory should provide scientific guidance for future control of air pollutants in the YRD region of China.

Published

2021

5. Superconductivity at 40 K in Lithiation-Processed [(Fe,Al)(OH)2][FeSe]1.2 with a Layered Structure

Author

W. Z. Zhuo, Z. Sun, C. S. Zhu, Xianhui Chen, Guobing Hu, Fanghang Yu, Wenxiang Wang, J. H. Cui, M. Z. Shi, and Xigang Luo

Subjects

Superconductivity, Condensed Matter - Materials Science, 010405 organic chemistry, Chemistry, Condensed Matter - Superconductivity, Stacking, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, Heterojunction, 010402 general chemistry, 01 natural sciences, Hydrothermal circulation, 0104 chemical sciences, Superconductivity (cond-mat.supr-con), Inorganic Chemistry, Tetragonal crystal system, Crystallography, Electron diffraction, Lattice (order), Physical and Theoretical Chemistry, Powder diffraction

Abstract

Exploration of new superconductors has always been one of the research directions in condensed matter physics. We report here a new layered heterostructure of [(Fe,Al)(OH)2][FeSe]1.2, which is synthesized by the hydrothermal ion-exchange technique. The structure is suggested by a combination of X-ray powder diffraction and the electron diffraction (ED). [(Fe,Al)(OH)2][FeSe]1.2 is composed of the alternating stacking of tetragonal FeSe layer and hexagonal (Fe,Al)(OH)2 layer. In [(Fe,Al)(OH)2][FeSe]1.2, there exists mismatch between the FeSe sub-layer and (Fe,Al)(OH)2 sub-layer, and the lattice of the layered heterostructure is quasi-commensurate. The as-synthesized [(Fe,Al)(OH)2][FeSe]1.2 is non-superconducting due to the Fe vacancies in the FeSe layer. The superconductivity with a Tc of 40 K can be achieved after a lithiation process, which is due to the elimination of the Fe vacancies in the FeSe layer. The Tc is nearly the same as that of (Li,Fe)OHFeSe although the structure of [(Fe,Al)(OH)2][FeSe]1.2 is quite different from that of (Li,Fe)OHFeSe. The new layered heterostructure of [(Fe,Al)(OH)2][FeSe]1.2 contains an iron selenium tetragonal lattice interleaved with a hexagonal metal hydroxide lattice. These results indicate that the superconductivity is very robust for FeSe-based superconductors. It opens a path for exploring super-conductivity in iron-base superconductors., Comment: 7 pages, 4 figures, published in Inorg. Chem

Published

2021

6. Development of an automatic linear calibration method for high-resolution single-particle mass spectrometry: improved chemical species identification for atmospheric aerosols

Author

S. Zhu, L. Li, S. Wang, M. Li, Y. Liu, X. Lu, H. Chen, L. Wang, J. Chen, Z. Zhou, X. Yang, and X. Wang

Subjects

Atmospheric Science, Materials science, 010504 meteorology & atmospheric sciences, Resolution (mass spectrometry), lcsh:TA715-787, lcsh:Earthwork. Foundations, Analytical chemistry, 010501 environmental sciences, Sea spray, Mass spectrometry, 01 natural sciences, Aerosol, lcsh:Environmental engineering, Mass spectrum, Calibration, Aerosol mass spectrometry, Particle, lcsh:TA170-171, 0105 earth and related environmental sciences

Abstract

The mass resolution of laser desorption ionization (LDI) single-particle aerosol mass spectrometry (SPAMS) is usually low (∼500), which has been greatly improved by the recent development of the delayed ion extraction technique. However, due to large fluctuations among LDI processes during each laser shot, accurate calibration of the mass-to-charge ratio for high-resolution SPAMS (HR-SPAMS) spectra is challenging. Here we developed an automatic linear calibration method to improve the accuracy of mass-to-charge (m∕z) measurement for single atmospheric aerosol particles. Laboratory-generated sea spray aerosol and atmospheric ambient aerosol were tested. After the calibration, the fluctuation ranges of the reference ions' (e.g., Pb+ and SO4+) m∕z reaches ±0.018 for sea spray aerosol and ±0.024 for ambient aerosol in average mass spectra. With such m∕z accuracy, the HR-SPAMS spectra of sea spray aerosol can easily identify elemental compositions of organic peaks, such as Cx, CxHy and CxHyOz. While the chemical compositions of ambient aerosols are more complicated, CxHy, CxHyOz and CNO peaks can also be identified based on their accurate mass. With the improved resolution, the time series of peaks with small m∕z differences can be separated and measured. In addition, it is also found that applying high-resolution data with enhanced mass calibration can significantly affect particle classification (identification) using the ART-2a algorithm, which classify particles based on similarities among single-particle mass spectra.

Published

2020

7. AIMERG: a new Asian precipitation dataset (0.1°/half-hourly, 2000–2015) by calibrating the GPM-era IMERG at a daily scale using APHRODITE

Author

Z. Ma, J. Xu, S. Zhu, J. Yang, G. Tang, Y. Yang, Z. Shi, and Y. Hong

Subjects

lcsh:GE1-350, lcsh:Geology, 010504 meteorology & atmospheric sciences, lcsh:QE1-996.5, 0207 environmental engineering, General Earth and Planetary Sciences, 02 engineering and technology, 020701 environmental engineering, 01 natural sciences, lcsh:Environmental sciences, 0105 earth and related environmental sciences

Abstract

Precipitation estimates with fine quality and spatio-temporal resolutions play significant roles in understanding the global and regional cycles of water, carbon, and energy. Satellite-based precipitation products are capable of detecting spatial patterns and temporal variations of precipitation at fine resolutions, which is particularly useful over poorly gauged regions. However, satellite-based precipitation products are the indirect estimates of precipitation, inherently containing regional and seasonal systematic biases and random errors. In this study, focusing on the potential drawbacks in generating Integrated Multi-satellitE Retrievals for Global Precipitation Measurement (IMERG) and its recently updated retrospective IMERG in the Tropical Rainfall Measuring Mission (TRMM) era (finished in July 2019), which were only calibrated at a monthly scale using ground observations, Global Precipitation Climatology Centre (GPCC, 1.0∘/monthly), we aim to propose a new calibration algorithm for IMERG at a daily scale and to provide a new AIMERG precipitation dataset (0.1∘/half-hourly, 2000–2015, Asia) with better quality, calibrated by Asian Precipitation – Highly Resolved Observational Data Integration Towards Evaluation of Water Resources (APHRODITE, 0.25∘/daily) at the daily scale for the Asian applications. The main conclusions include but are not limited to the following: (1) the proposed daily calibration algorithm (Daily Spatio-Temporal Disaggregation Calibration Algorithm, DSTDCA) is effective in considering the advantages from both satellite-based precipitation estimates and the ground observations; (2) AIMERG performs better than IMERG at different spatio-temporal scales, in terms of both systematic biases and random errors, over mainland China; and (3) APHRODITE demonstrates significant advantages compared to GPCC in calibrating IMERG, especially over mountainous regions with complex terrain, e.g. the Tibetan Plateau. Additionally, results of this study suggest that it is a promising and applicable daily calibration algorithm for GPM in generating the future IMERG in either an operational scheme or a retrospective manner. The AIMERG data are freely accessible at https://doi.org/10.5281/zenodo.3609352 (for the period from 2000 to 2008) (Ma et al., 2020a) and https://doi.org/10.5281/zenodo.3609507 (for the period from 2009 to 2015) (Ma et al., 2020b). Highlights. A new effective daily calibration approach, DSTDCA, for improving the GPM-era IMERG is provided. New AIMERG precipitation data (0.1∘/half-hourly, 2000–2015, Asia) are provided. Bias of AIMERG is significantly improved compared with that of IMERG. APHRODITE is more suitable than GPCC in anchoring IMERG over Asia.

Published

2020

8. Search for in-band transitions in the candidate superdeformed band in 28Si

Author

R. G. T. Zegers, Johann Isaak, A. Bracco, B. Wasilewska, S. Zhu, T. H. Hoang, X. H. Zhou, J. J. Carroll, S. Adachi, C. Sullivan, M. P. Carpenter, M. Kumar Raju, Atsushi Tamii, L. Morris, Y. D. Fang, J. Schmitt, Shumpei Noji, N. Ichige, P. J. Davies, D. G. Jenkins, Eiji Ideguchi, G. Gey, Deniz Savran, Nobumichi Kobayashi, P. Adsley, S. Courtin, G. Fruet, Hooi Jin Ong, P. von Neumann-Cosel, A. S. Brown, Takeshi Koike, D. Montanari, A. Inoue, Nori Aoi, Hisanori Fujita, M.N. Harakeh, C. Iwamoto, V. Werner, Yasuo Yamamoto, M. L. Liu, M. Weinert, F. C. L. Crespi, Université de Strasbourg (UNISTRA), Institut Pluridisciplinaire Hubert Curien (IPHC), and Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)

Subjects

Physics, [PHYS.NUCL]Physics [physics]/Nuclear Theory [nucl-th], 010308 nuclear & particles physics, 0103 physical sciences, Astrophysics, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], 010306 general physics, 01 natural sciences

Abstract

International audience; Background: Superdeformed (SD) bands are suggested by theory around Ca40 and in lighter alpha-conjugate nuclei such as Mg24, Si28, and S32. Such predictions originate from a number of theoretical models including mean-field models and antisymmetrized molecular dynamics (AMD) calculations. While SD bands have been identified in Ca40 and its near neighbors, evidence of their existence in the lighter, midshell nuclei is circumstantial at best. The key evidence of superdeformation would be the observation of transitions with high B(E2) transition strengths connecting states in a rotational sequence. This is challenging information to obtain since the bands lie at a high excitation energy and competition from out-of-band decay is dominant.Purpose: The purpose of the present study is to establish a new methodology to circumvent the difficulties in identifying and quantifying in-band transitions through directly populating candidate states in the SD band in Si28 through inelastic alpha scattering, selecting such states with a spectrometer, and measuring their gamma-ray decay with a large array of high-purity germanium detectors, allowing direct access to electromagnetic transition strengths.Methods: Excited states in Si28 were populated in the Si28(α,α′) reaction using a 130-MeV He4 beam from the K140 AVF cyclotron at the Research Center for Nuclear Physics. Outgoing alpha particles were analyzed using the Grand Raiden spectrometer positioned at an angle of 9.1∘ to favor the population of states with J≈4. Coincident gamma rays were detected with the CAGRA array of 12 HPGe clover detectors augmented by a set of four large LaBr3 detectors.Results: Data analysis showed that it was possible to identify additional low-energy transitions in competition with high-energy decays from excited states in Si28 in the vicinity of 10 MeV. However, while the candidate 4+ SD state at 10.944 MeV was populated, a 1148-keV transition to the candidate 2+ SD state at 9.796 MeV was not observed, and only an upper limit for its transition strength of B(E2)<43 W.u. could be established. This contradicts AMD predictions of ≈200 W.u. for such a transition.Conclusion: The present study strongly rejects the hypothesis that the candidate set of states identified in Si28 represents an SD band, which demonstrates the potential of the methodology devised here.

Published

2021

9. Shapes, Softness and Non-Yrast Collectivity in 186W

Author

C. R. Hoffman, D. Seweryniak, M. P. Carpenter, T. Lauritsen, Alan Mitchell, B. P. Kay, A. Verras, P. Chowdhury, R. V. F. Janssens, D. Cline, R. Shearman, S. Zhu, C. J. Chiara, E. Merchan, S. K. Tandel, C. Y. Wu, A. Korichi, T. L. Khoo, N. D'Olympia, A. B. Hayes, M. Albers, V.S. Prasher, C.J. Guess, Y. Qiu, C J Lister, and L. Afanasieva

Subjects

Physics, Spins, Nuclear Theory, 010308 nuclear & particles physics, Yrast, FOS: Physical sciences, 01 natural sciences, Coriolis coupling, Nuclear Theory (nucl-th), Excited state, 0103 physical sciences, Vibrational bands, Gammasphere, Atomic physics, Nuclear Experiment (nucl-ex), 010306 general physics, Nuclear Experiment, Spin-½

Abstract

Non-yrast, excited states in neutron-rich $^{186}$W were populated via inelastic-scattering reactions using beams of $^{136}$Xe nuclei accelerated to 725 and 800 MeV. Levels populated in the reactions were investigated via particle-$ \gamma $ coincidence techniques using the Gammasphere array of High-Purity Germanium detectors and the compact heavy-ion counter, CHICO2. The $ K^{\pi} = 2 ^{+} $ ($\gamma$), $ K^{\pi} = 0^{+}$ and $ K^{\pi} = 2^{-} $ (octupole) rotational side bands were extended to spins $ 14\hbar $, $ 12\hbar $, and $ 13\hbar $, respectively. A staggering pattern observed in the energies of levels in the $ K^{\pi} = 2^{+} $ band was found to be consistent with a potential that gets softer to vibration in the $ \gamma $ degree of freedom with increasing spin. The odd-even staggering of states in the $ K^{\pi} = 2^{-}$ band was found to exhibit a phase opposite to that seen in the $ \gamma $ band; an effect most probably associated with Coriolis coupling to other, unobserved octupole vibrational bands in $^{186}$W., Comment: 14 pages, 16 figures

Published

2021

10. Investigation of the isoscalar response of Mg24 to Li6 scattering

Author

Shumpei Noji, G. Gey, Y. Yamamoto, L. Batail, S. Zhu, R. Titus, Eiji Ideguchi, P. von Neumann-Cosel, A. Inoue, J. C. Zamora, Hooi Jin Ong, J. Schmitt, Johann Isaak, M. P. Carpenter, Nori Aoi, T. H. Hoang, U. Garg, J. J. Carroll, V. Werner, X. K. Zhou, M. L. Liu, Takeshi Koike, Nobuyuki Kobayashi, C. Kacir, C. J. Guess, D. Bazin, Hisanori Fujita, R. G. T. Zegers, Chihiro Iwamoto, Sophie Péru, N. Ichige, C. Sullivan, Atsushi Tamii, S. Lipschutz, E. Hudson, J. Pereira, M.N. Harakeh, M. Kumar Raju, and Y. D. Fang

Subjects

Physics, 010308 nuclear & particles physics, Scattering, Isoscalar, Nuclear Theory, Resonance, Inelastic scattering, 01 natural sciences, Molecular physics, 0103 physical sciences, Quadrupole, 010306 general physics, Random phase approximation, Ground state, Multipole expansion

Abstract

Background: Mg 24 is a strongly deformed nucleus in the ground state. Deformation effects can be observed in the structure of the isoscalar giant monopole and quadrupole resonances. Mg 24 is also a nucleus that is well known to present different types of cluster-oscillation modes. Both giant resonances and cluster states are strongly populated by isoscalar transitions. Purpose: To extract the E 0 , E 1 , and E 2 transition strengths via Li 6 scattering. The Li 6 probe is a powerful tool for investigating the isoscalar nuclear response with a very favorable ratio of resonance-to-continuum background. Method: Double-differential cross sections of Li 6 inelastic scattering, at the beam energy of 100 MeV/u, were measured in the excitation-energy range 10 – 40 MeV and scattering angles 0 − 3 ∘ . A multipole-decomposition analysis was performed for extracting the isoscalar E 0 , E 1 , and E 2 strength distributions. Results: The extracted multipole strengths were compared with predictions from consistent quasiparticle random phase approximation calculations. The theoretical predictions are in fair agreement with the experimental data. The E 0 strength was also compared with results from antisymmetrized molecular dynamics calculations found in the literature. A few peaks in the experimental data might be associated with clustering in Mg 24 . Conclusions: Ground-state deformation effects were observed in the isoscalar giant monopole resonance (ISGMR) and isoscalar giant quadrupole resonance (ISGQR) distributions. The ISGMR strength is split in two peaks around 19 and 28 MeV. The ISGQR exhibits a pronounced peak at 20 MeV with a broadening at the low-energy region, similar to predictions from microscopic calculations. Signatures of excitation of cluster states were observed in the E 0 response. Further studies including particle-decay measurements will be required to confirm the nature of the observed peaks.

Published

2021

11. Synthesis and evaluation of tetrahydropyrazolopyridine inhibitors of anion exchange protein SLC26A4 (pendrin)

Author

Mark J. Kurth, Peter M. Haggie, Marina E. Shatskikh, Julia Y. Lu, Jung-Ho Son, Alan S. Verkman, Amber A. Rivera, Joseph-Anthony Tan, Jie S. Zhu, and Puay-Wah Phuan

Subjects

Pyridines, Chronic rhinosinusitis, Antiporter, Clinical Biochemistry, Pharmaceutical Science, Pharmacology, 01 natural sciences, Biochemistry, Cystic fibrosis, Mice, Regioselectivity, Drug Discovery, Lung, Inbred F344, Anion transporter, Molecular Structure, biology, Ion exchange, Chemistry, Pharmacology and Pharmaceutical Sciences, Transmembrane protein, Sulfate Transporters, 5.1 Pharmaceuticals, Respiratory, Molecular Medicine, Development of treatments and therapeutic interventions, Medicinal & Biomolecular Chemistry, Article, Small Molecule Libraries, Structure-Activity Relationship, Medicinal and Biomolecular Chemistry, Downregulation and upregulation, SLC26A4, otorhinolaryngologic diseases, medicine, Animals, Pendrin, Hydrazine (antidepressant), Molecular Biology, 010405 organic chemistry, Organic Chemistry, medicine.disease, Rats, Inbred F344, Rats, 0104 chemical sciences, 010404 medicinal & biomolecular chemistry, Pyrazole, biology.protein, Pyrazoles

Abstract

Pendrin is a transmembrane chloride/anion antiporter that is strongly upregulated in the airways in rhinoviral infection, asthma, cystic fibrosis and chronic rhinosinusitis. Based on its role in the regulation of airway surface liquid depth, pendrin inhibitors have potential indications for treatment of inflammatory airways diseases. Here, a completely regioselective route to tetrahydro-pyrazolopyridine pendrin inhibitors based on 1,3-diketone and substituted hydrazine condensation was been developed. Structure-activity relationships at the tetra hydropyridyl nitrogen were investigated using a focused library, establishing the privileged nature of N-phenyl ureas and improving inhibitor potency by greater than 2-fold.

Published

2019

12. Evaluation of the effect of regional joint-control measures on changing photochemical transformation: a comprehensive study of the optimization scenario analysis

Author

L. Li, S. Zhu, J. An, M. Zhou, H. Wang, R. Yan, L. Qiao, X. Tian, L. Shen, L. Huang, Y. Wang, C. Huang, J. C. Avise, and J. S. Fu

Subjects

Pollution, Atmospheric Science, geography, geography.geographical_feature_category, Air pollutant concentrations, Haze, 010504 meteorology & atmospheric sciences, media_common.quotation_subject, Environmental engineering, Air pollution, 010501 environmental sciences, medicine.disease_cause, 01 natural sciences, lcsh:QC1-999, lcsh:Chemistry, lcsh:QD1-999, medicine, Environmental science, Scenario analysis, Air quality index, Channel (geography), NOx, lcsh:Physics, 0105 earth and related environmental sciences, media_common

Abstract

Heavy haze usually occurs in winter in eastern China. To control the severe air pollution during the season, comprehensive regional joint-control strategies were implemented throughout a campaign. To evaluate the effectiveness of these strategies and to provide some insights into strengthening the regional joint-control mechanism, the influence of control measures on levels of air pollution was estimated with an integrated measurement-emission-modeling method. To determine the influence of meteorological conditions, and the control measures on the air quality, in a comprehensive study, the 2nd World Internet Conference was held during 16–18 December 2015 in Jiaxing City, Zhejiang province, in the Yangtze River Delta (YRD) region. We first analyzed the air quality changes during four meteorological regimes and then compared the air pollutant concentrations before, during, and after the regulation under static meteorological conditions. Next, we conducted modeling scenarios to quantify the effects caused due to the air pollution control measures. We found that total emissions of SO2, NOx, PM2.5, and volatile organic compounds (VOCs) in Jiaxing were reduced by 56 %, 58 %, 64 %, and 80 %, respectively, while total emission reductions of SO2, NOx, PM2.5, and VOCs over the YRD region are estimated to be 10 %, 9 %, 10 %, and 11 %, respectively. Modeling results suggest that during the campaign from 8 to 18 December, PM2.5 daily average concentrations decreased by 10 µg m−3 with an average decrease of 14.6 %. Our implemented optimization analysis compared with previous studies also reveals that local emission reductions play a key role in air quality improvement, although it shall be supplemented by regional linkage. In terms of regional joint control, implementing pollution channel control 48 h before the event is of most benefit in getting similar results. Therefore, it is recommended that a synergistic emission reduction plan between adjacent areas with local pollution emission reductions as the core part should be established and strengthened, and emission reduction plans for different types of pollution through a stronger regional linkage should be reserved.

Published

2019

13. Proton decay of 108I and its significance for the termination of the astrophysical rp-process

Author

S. Zhu, D. Seweryniak, P. Copp, M. Albers, Gavin Lotay, S. A. Kuvin, A. M. Rogers, J. Sethi, A. D. Ayangeakaa, Rashi Talwar, R. V. F. Janssens, W. B. Walters, Philip Woods, T. L. Khoo, S. Bottoni, M. P. Carpenter, T. Lauritsen, Calem Hoffman, H. M. David, Catherine Scholey, J. L. Harker, C. J. Chiara, Kalle Auranen, and D. T. Doherty

Subjects

Nuclear and High Energy Physics, alpha decay, Proton decay, Q value, astrofysiikka, Nuclear Theory, 104Sb, 01 natural sciences, astrophysical rp process, 108I, 0103 physical sciences, Mass analyzer, 107Te, 010306 general physics, Nuclear Experiment, Physics, Isotope, ta114, 010308 nuclear & particles physics, Interaction energy, rp-process, lcsh:QC1-999, proton decay, High Energy Physics::Experiment, Atomic physics, ydinfysiikka, lcsh:Physics

Abstract

Employing the Argonne Fragment Mass Analyzer and the implantation-decay-decay correlation technique, a weak 0.50(21)% proton decay branch was identified in 108I for the first time. The 108I proton-decay width is consistent with a hindered l = 2 emission, suggesting a d 5 2 origin. Using the extracted 108I proton-decay Q value of 597(13) keV, and the Q α values of the 108I and 107Te isotopes, a proton-decay Q value of 510(20) keV for 104Sb was deduced. Similarly to the 112,113Cs proton-emitter pair, the Q p ( I 108 ) value is lower than that for the less-exotic neighbor 109I, possibly due to enhanced proton-neutron interactions in N ≈ Z nuclei. In contrast, the present Q p ( Sb 104 ) is higher than that of 105Sb, suggesting a weaker interaction energy. For the present Q p ( Sb 104 ) value, network calculations with the one-zone X-ray burst model Mazzocchi et al. (2007) [18] predict no significant branching into the Sn-Sb-Te cycle at 103Sn.

Published

2019

14. Electric-field-controlled superconductor–ferromagnetic insulator transition

Author

B. Lei, Xianhui Chen, Naizhou Wang, F. B. Meng, Da-Yong Liu, Kaishuai Yang, C. Shang, Liang-Jian Zou, Z. Sun, J. H. Cui, C. S. Zhu, T. Wu, Zhe Sun, and L. K. Ma

Subjects

Superconductivity, Phase transition, Multidisciplinary, Materials science, Condensed matter physics, Magnetism, Gate dielectric, Insulator (electricity), Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, 010502 geochemistry & geophysics, 01 natural sciences, Ion, Condensed Matter::Materials Science, Ferromagnetism, Condensed Matter::Superconductivity, Electric field, Condensed Matter::Strongly Correlated Electrons, 0105 earth and related environmental sciences

Abstract

Superconductivity beyond electron-phonon mechanism is always twisted with magnetism. Based on a new field-effect transistor with solid ion conductor as the gate dielectric (SIC-FET), we successfully achieve an electric-field-controlled phase transition between superconductor and ferromagnetic insulator in (Li,Fe)OHFeSe. A dome-shaped superconducting phase with optimal Tc of 43 K is continuously tuned into a ferromagnetic insulating phase, which exhibits an electric-field-controlled quantum critical behavior. The origin of the ferromagnetism is ascribed to the order of the interstitial Fe ions expelled from the (Li,Fe)OH layers by gating-controlled Li injection. These surprising findings offer a unique platform to study the relationship between superconductivity and ferromagnetism in Fe-based superconductors. This work also demonstrates the superior performance of the SIC-FET in regulating physical properties of layered unconventional superconductors.

Published

2019

15. Two-phonon wobbling in 135Pr

Author

Q. B. Chen, N. Sensharma, A. D. Ayangeakaa, Y. K. Gupta, D. Seweryniak, J. L. Cozzi, J. Sethi, R. V. F. Janssens, F. G. Kondev, G. H. Bhat, S. S. Ghugre, D. J. Hartley, M. P. Carpenter, S. Zhu, J. A. Sheikh, R. P. Singh, S. Frauendorf, K. B. Howard, R. Palit, Wei Li, T. C. McMaken, and U. Garg

Subjects

Physics, Nuclear and High Energy Physics, Condensed matter physics, 010308 nuclear & particles physics, Rotor (electric), Phonon, Shell (structure), Conclusive evidence, 01 natural sciences, lcsh:QC1-999, law.invention, Transverse plane, medicine.anatomical_structure, Character (mathematics), law, 0103 physical sciences, Quasiparticle, medicine, 010306 general physics, Nucleus, lcsh:Physics

Abstract

The second-phonon ( n ω = 2 ) wobbling band has been established in the nucleus 135Pr. Conclusive evidence for its wobbling nature comes from the Δ I = 1 , E2 character of the transitions between the new band and the previously identified transverse wobbler band ( n ω = 1 ) in this nucleus. Theoretical calculations in the framework of the quasiparticle triaxial rotor and triaxial projected shell models are found to be in good agreement with the experimental results.

Published

2019

16. Effects of temperature on the tribological behavior of Al0.25CoCrFeNi high-entropy alloy

Author

Huajie Yang, L.W. Lan, L.M. Du, X.H. Shi, Junwei Qiao, Peter K. Liaw, and S. Zhu

Subjects

Materials science, Polymers and Plastics, Mechanical Engineering, Abrasive, Alloy, Metals and Alloys, 02 engineering and technology, Tribology, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, 0104 chemical sciences, Mechanics of Materials, Materials Chemistry, Ceramics and Composites, Adhesive wear, engineering, Composite material, 0210 nano-technology, Softening

Abstract

The tribological behavior of Al0.25CoCrFeNi high-entropy alloy (HEA) sliding against Si3N4 ball was investigated from room temperature to 600 ℃. The microstructure of the alloys was characterized by simple FCC phase with 260 HV. Below 300 ℃, with increasing temperature, the wear rate increased due to high temperature softening. The wear rate remained stabilized above 300 ℃ due to the anti-wear effect of the oxidation film on the contact interface. The dominant wear mechanism of HEA changed from abrasive wear at room temperature to delamination wear at 200 ℃, then delamination wear and oxidative wear at 300 ℃ and became oxidative above 300 ℃. Moreover, the adhesive wear existed concomitantly below 300 ℃.

Published

2019

17. Market price behavior of wholesale electricity products: Texas

Author

Jay Zarnikau, Chi Keung Woo, S. Zhu, and Chen-Hao Tsai

Subjects

Wind power, business.industry, 020209 energy, Sample (statistics), 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, General Energy, Procurement, 0202 electrical engineering, electronic engineering, information engineering, Econometrics, Market price, Economics, Electricity, business, Energy (signal processing), 0105 earth and related environmental sciences

Abstract

Applying a regression-based approach to a newly developed sample of over 60,000 hourly observations for 01/01/2011–12/30/2017, we answer the question: what moves the day-ahead market (DAM) prices for energy and ancillary services (AS) and the real-time market (RTM) price for energy in the Electric Reliability Council of Texas (ERCOT)? Our answer comprises the following findings that capture the interdependence of ERCOT's energy and AS products: (1) the DAM energy price increases with the day-ahead forecasts of natural gas price, system load and AS requirements but declines with nuclear and wind generation's forecasts; (2) the AS prices increase with the DAM energy price and the AS procurement forecasts but decline with the AS offer forecasts; and (3) the RTM energy price increases with the DAM energy price but diverges from the DAM energy price due to forecasting errors related to the DAM energy price's fundamental drivers. These findings imply that Texas can reduce the prices for day-ahead energy, day-ahead AS and real-time energy via wind generation development and demand-side-management. Further, Texas can improve its electricity trading efficiency by improving ERCOT's forecast accuracy to narrow the RTM energy price's divergence from the DAM energy price.

Published

2019

18. Investigation of trends in extreme significant wave heights in the South China Sea

Author

Y. Luo and L. S. Zhu

Subjects

0106 biological sciences, South china, Ecology, Buoy, 010604 marine biology & hydrobiology, 010501 environmental sciences, Management, Monitoring, Policy and Law, Aquatic Science, 01 natural sciences, Climatology, Typhoon, Generalized extreme value distribution, Environmental science, Submarine pipeline, Extreme value theory, 0105 earth and related environmental sciences

Abstract

The focus of this study was the temporal and spatial variations of extreme significant wave heights and nearshore return-period wave heights in the South China Sea, based on the wave model and European Reanalysis-Interim data from 1979–2016. Measured buoy data were available from near Yongxing Island for comparison with the reanalysis data during the passage of typhoons. Annual maximum significant wave heights showed a statistically significant increasing trend over most of the South China Sea, whereas statistically insignificant decreasing or increasing trends were observed for seasonal maximum significant wave heights associated with the different characteristics of the typhoon events. Nonstationary generalized extreme value analysis was used to investigate the influence of nearshore extreme significant wave heights derived from the Simulating Waves Nearshore model at four offshore locations in the South China Sea. The fastest increase of 100-year return significant wave heights was found to be 0.0033 m yr−1 in the western South China Sea. The results show that, in recent decades, no significant variation trends can be found in return-period wave heights at nearshore of South China Sea, which may be related to tracks of intense typhoons in the region.

Published

2019

19. Revised B(E3) transition rate and structure of the 3− level in 96Zr

Author

T. Lauritsen, M. P. Carpenter, R. Broda, Takaharu Otsuka, R. V. F. Janssens, Ł. W. Iskra, T. Togashi, W. B. Walters, Yusuke Tsunoda, B. Fornal, and S. Zhu

Subjects

Physics, Nuclear and High Energy Physics, Proton, 010308 nuclear & particles physics, Monte Carlo method, Structure (category theory), Transition rate matrix, 01 natural sciences, lcsh:QC1-999, Character (mathematics), Atomic orbital, 0103 physical sciences, Neutron, Atomic physics, 010306 general physics, lcsh:Physics, Line (formation)

Abstract

The B(E3) transition strength from the 1897-keV, 3− level in 96Zr has been reevaluated from six high-statistics, independent data sets. The measured value of 42(3) W.u. is significantly lower than that adopted in recent compilations. It is, however, in line with the global systematics of collective B(E3) rates found throughout the periodic table. Thus, the “exceptional” character of this transition, that challenged theory, no longer applies. Monte Carlo shell-model calculations indicate that the collectivity of the octupole vibration arises from both proton and neutron excitations involving a large number of orbitals. Keywords: 90≤A≤149, 3− level, Octupole excitation, Lifetimes and branching ratios, B(E3) strength, Monte Carlo shell model calculations

Published

2019

20. The structure of low-lying 1− states in 90,94Zr from (α,α′γ) and (p,p′γ) reactions

Author

Miao Liu, T. Hashimoto, J.M. Schmitt, X. K. Zhou, O. Wieland, C. Iwamoto, Norbert Pietralla, B. Wasilewska, S. Zhu, A. Czeszumska, Johann Isaak, T. Klaus, C. Sullivan, A. Inoue, M.K. Raju, Y.D. Fang, Nobuyuki Kobayashi, F. Camera, Yoshihisa Yamamoto, Shumpei Noji, V. Werner, A. Maj, G. Gey, D. G. Jenkins, Hooi Jin Ong, M. Krzysiek, F. C. L. Crespi, Andreas Zilges, M. Ciemała, L. Morris, R. G. T. Zegers, Takeshi Koike, T. Yamamoto, M. P. Carpenter, G. Steinhilber, D. L. Balabanski, A. Bracco, S. Bassauer, V. Derya, Nori Aoi, J. J. Carroll, E.G. Lanza, M. Spieker, A. S. Brown, N. Ichige, Deniz Savran, H. Fujita, S. G. Pickstone, N. Blasi, P. J. Davies, P. von Neumann Cosel, M.N. Harakeh, H.T. Ha, Atsushi Tamii, M. Weinert, L. M. Donaldson, Eiji Ideguchi, and Research unit Nuclear & Hadron Physics

Subjects

Physics, Nuclear and High Energy Physics, Range (particle radiation), Inelastic scattering, Isovector, Proton, 010308 nuclear & particles physics, Isoscalar, Binding energy, 01 natural sciences, Dipole excitation around neutron threshold, lcsh:QC1-999, Dipole, 0103 physical sciences, Neutron, Sum rule in quantum mechanics, Nuclear structure, Atomic physics, 010306 general physics, lcsh:Physics

Abstract

The low-lying dipole strength in the 90,94Zr nuclei was investigated via (p,p′γ) at 80 MeV and (α,α′γ) at 130 MeV. The experiments, made at RCNP, used the magnetic spectrometer Grand Raiden for the scattered particles and the array CAGRA with HPGe detectors for the γ-decay. For 94Zr these are the first data for both reactions and for 90Zr these are the first data with (p,p′γ) and the first ones at high resolution for (α,α′γ). The comparison of the present results for the two nuclei with existing (γ,γ′) data shows that both nuclear probes produce an excitation pattern different than that of the electromagnetic probes. DWBA calculations were made using form factors deduced from transition densities, based on RPA calculations, characterized by a strong neutron component at the nuclear surface. A combined analysis of the two reactions was performed for the first time to investigate the isoscalar character of the 1− states in 90,94Zr. The (p,p′γ) cross section was calculated using values for the isoscalar electric dipole energy-weighted sum rule (E1 ISEWSR) obtained from the (α,α′γ) data. The isoscalar strength for 90Zr was found to exhaust 20 ± 2.5% of the EWSR in the energy range up to 12 MeV. In case of 94Zr, a strength of 9 ± 1.1% of the EWSR was found in the range up to 8.5 MeV. Although an overall general description was obtained in the studied energy intervals, not all proton cross sections were well reproduced using the isoscalar strength from (α,α′γ). This might suggest mixing of isoscalar and isovector components and that this mixing and the degree of collectivity are not the same for all the 1− states below the particle binding energy.

Published

2021

21. Giant tunneling magnetoresistance in van der Waals magnetic tunnel junctions formed by interlayer antiferromagnetic bilayer CoBr2

Author

Xiuwen Han, Xinhua Guo, Yu Yan, Y. S. Zhu, L. N. Jiang, and Z. R. Yan

Subjects

Materials science, Condensed matter physics, Magnetoresistance, Bilayer, 02 engineering and technology, Magnetic semiconductor, Condensed Matter::Mesoscopic Systems and Quantum Hall Effect, 021001 nanoscience & nanotechnology, 01 natural sciences, Condensed Matter::Materials Science, symbols.namesake, Ferromagnetism, 0103 physical sciences, symbols, Antiferromagnetism, Condensed Matter::Strongly Correlated Electrons, Density functional theory, van der Waals force, 010306 general physics, 0210 nano-technology, Quantum tunnelling

Abstract

The discovery of two-dimensional (2D) van der Waals (vdW) intrinsic magnets has opened a promising avenue to design high-performance magnetic tunnel junctions (MTJs) based on 2D materials. In this work, using first-principles calculations, it is demonstrated that bilayer $\mathrm{Co}{\mathrm{Br}}_{2}$ is intrinsically a magnetic semiconductor with intralayer ferromagnetic (FM) and interlayer antiferromagnetic (AFM) couplings and the interlayer AFM coupling in bilayer $\mathrm{Co}{\mathrm{Br}}_{2}$ is independent on the stacking orders. Moreover, using the nonequilibrium Green's function combined with density functional theory, it is found that due to the large difference between interlayer AFM and FM states of the $\mathrm{Co}{\mathrm{Br}}_{2}$ barrier, the conductance of spin filter (SF) vdW MTJs based on the graphene/bilayer $\mathrm{Co}{\mathrm{Br}}_{2}$/graphene heterostructure for the interlayer FM state of the $\mathrm{Co}{\mathrm{Br}}_{2}$ barrier is about 25 times that for the interlayer AFM state of the $\mathrm{Co}{\mathrm{Br}}_{2}$ barrier. Consequently, a high tunneling magnetoresistance (TMR) ratio of $2420%$ is achieved in this SF-vdW MTJ at zero bias. In particular, because the current for the interlayer FM state of the $\mathrm{Co}{\mathrm{Br}}_{2}$ barrier rapidly increases with the increase of bias voltage, a giant TMR ratio of up to about $38\phantom{\rule{0.16em}{0ex}}000%$ can be achieved in this SF-vdW MTJ at 0.2-V bias. Our results suggest that SF-vdW MTJs formed by the interlayer AFM barrier with variable conductivity hold great potential for developing vdW MTJs with a high TMR ratio.

Published

2021

22. Level structure of the Tz=−1 nucleus Ar34 and its relevance for nucleosynthesis in ONe novae

Author

K. Hadyńska-Klȩk, G. L. Wilson, T. Huang, T. Lauritsen, F. G. Kondev, R. V. F. Janssens, Jordi José, D. Seweryniak, Gavin Lotay, Guy Savard, D. T. Doherty, J. Saiz, S. Hallam, M. P. Carpenter, S. Jazrawi, S. Stolze, A. M. Rogers, S. Zhu, Kalle Auranen, W. N. Catford, J. Li, Catherine Deibel, D. E. M. Hoff, A. R. L. Kennington, and Corina Andreoiu

Subjects

Physics, Proton, 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, Coupling (probability), 01 natural sciences, 7. Clean energy, Nuclear physics, Nucleosynthesis, Excited state, 0103 physical sciences, Nuclear astrophysics, Nuclear fusion, 010306 general physics, Spectroscopy, Energy (signal processing)

Abstract

The $^{24}\mathrm{Mg}+^{12}\mathrm{C}$ fusion reaction was used to perform a detailed $\ensuremath{\gamma}$-ray spectroscopy study of the astrophysically important nucleus $^{34}\mathrm{Ar}$. In particular, an experimental setup, coupling the advanced $\ensuremath{\gamma}$-ray tracking array GRETINA with the well-established Argonne fragment mass analyzer (FMA), was employed to obtain excitation energies and spin-parity assignments for excited states in $^{34}\mathrm{Ar}$, both above and below the proton separation energy. For the first time, an angular distribution analysis of in-beam $\ensuremath{\gamma}$ rays from fusion-evaporation reactions, using a tracking array, has been performed and Coulomb energy differences of analog states in the $T=1,$ $A=34$ mirror system, explored from 0 to 6 MeV. Furthermore, we present a comprehensive discussion of the astrophysical $^{33}\mathrm{Cl}(p,\ensuremath{\gamma})$ stellar reaction rate, together with implications for the identification of nova presolar grains from sulfur isotopic abundances.

Published

2021

23. Ground-state and decay properties of neutron-rich Nb106

Author

S. Zhu, U. Patel, R. V. F. Janssens, S. Bottoni, J. M. Allmond, P. Copp, A. D. Ayangeakaa, F. G. Kondev, G. J. Lane, Michael Smith, C. J. Lister, Y. Y. Zhong, M. P. Carpenter, R. Orford, Jason A. Clark, D. A. Gorelov, Alan Mitchell, D. Seweryniak, Guy Savard, and P. Chowdhury

Subjects

Physics, education.field_of_study, Mass excess, 010308 nuclear & particles physics, Fission, Population, 01 natural sciences, Excited state, 0103 physical sciences, Neutron, Atomic physics, 010306 general physics, education, Ground state, Energy (signal processing), Excitation

Abstract

The ground-state properties of neutron-rich $^{106}\mathrm{Nb}$ and its $\ensuremath{\beta}$ decay into $^{106}\mathrm{Mo}$ have been studied using the CARIBU radioactive-ion-beam facility at Argonne National Laboratory. Niobium-106 ions were extracted from a $^{252}\mathrm{Cf}$ fission source and mass separated before being delivered as low-energy beams to the Canadian Penning Trap, as well as the X-Array and SATURN $\ensuremath{\beta}$-decay-spectroscopy station. The measured $^{106}\mathrm{Nb}$ ground-state mass excess of $\ensuremath{-}66202.0(13)$ keV is consistent with a recent measurement but has three times better precision; this work also rules out the existence of a second long-lived, $\ensuremath{\beta}$-decaying state in $^{106}\mathrm{Nb}$ above 5 keV in excitation energy. The decay half-life of $^{106}\mathrm{Nb}$ was measured to be 1.097(21) s, which is $8%$ longer than the adopted value. The level scheme of the decay progeny, $^{106}\mathrm{Mo}$, has been expanded up to $\ensuremath{\approx}4\phantom{\rule{4pt}{0ex}}\mathrm{MeV}$. The distribution of decay strength and considerable population of excited states in $^{106}\mathrm{Mo}$ of $J\ensuremath{\ge}3$ emphasizes the need to revise the adopted ${J}^{\ensuremath{\pi}}={1}_{}^{\ensuremath{-}}$ ground-state spin-parity assignment of $^{106}\mathrm{Nb}$; it is more likely to be $J\ensuremath{\ge}3$.

Published

2021

24. Pressure-controlled anomalous Hall conductivity in the half-Heusler antiferromagnet GdPtBi

Author

Z. Sun, J. H. Cui, Zhen-Hua Wang, C. S. Zhu, W. Z. Zhuo, Xianhui Chen, and Kunling Peng

Subjects

Physics, Condensed matter physics, Magnetism, Fermi level, Hydrostatic pressure, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Magnetic field, symbols.namesake, Hall effect, 0103 physical sciences, symbols, Antiferromagnetism, Condensed Matter::Strongly Correlated Electrons, Berry connection and curvature, 010306 general physics, 0210 nano-technology, Electronic band structure

Abstract

Controlling the intrinsic anomalous Hall conductivity (AHC) induced by Berry curvature is of significance in potential applications. Half-Heusler antiferromagnet GdPtBi provides an excellent platform to design and control the AHC, owing to its simple band structure near the Fermi level. Here, we systematically study the pressure-dependent magnetotransport properties of GdPtBi, in which the AHC can be continuously tuned by applying hydrostatic pressure. While the band structure and magnetism of GdPtBi bear minor changes below 2 GPa, the AHC decreases progressively with increasing pressure, and eventually vanishes at $P=1.5\phantom{\rule{0.16em}{0ex}}\mathrm{GPa}$. The chiral anomaly effect and electronic structure calculations further manifest that the Weyl nodes persist in this pressure range under magnetic field. Further analysis indicates that the disappearance of AHC in GdPtBi originates from the shift of the Fermi level relative to the Weyl nodes or the change of the canted spin structure of Gd ions in finite magnetic field under pressure. Our results show that pressure is an effective way to tune the anomalous Hall effect in magnetic topological semimetals.

Published

2021

25. Decay of the key 92-keV resonance in the 25Mg(p,γ) reaction to the ground and isomeric states of the cosmic γ-ray emitter 26Al

Author

Claudia Lederer-Woods, R. V. F. Janssens, S. Zhu, D. Seweryniak, D. T. Doherty, H. M. Albers, M. P. Carpenter, A. D. Ayangeakaa, Philip Woods, J. L. Harker, C. J. Chiara, M. Albers, Frank Strieder, and Anu Kankainen

Subjects

Nuclear and High Energy Physics, γ spectroscopy, astrofysiikka, Astrophysics::High Energy Astrophysical Phenomena, nuclear astrophysics, 01 natural sciences, 7. Clean energy, 0103 physical sciences, Nuclear astrophysics, 010306 general physics, Spin (physics), Physics, Range (particle radiation), COSMIC cancer database, 010308 nuclear & particles physics, Branching fraction, Resonance, State (functional analysis), lcsh:QC1-999, 26Al, cosmic γ rays, Cosmic γ rays, Atomic physics, ydinfysiikka, Ground state, kosminen säteily, lcsh:Physics

Abstract

The 92-keV resonance in the 25Mg ( p , γ ) 26 Al reaction plays a key role in the production of 26Al at astrophysical burning temperatures of ≈100 MK in the Mg-Al cycle. However, the state can decay to feed either the ground, 26 g Al, or isomeric state, 26 m Al. It is the ground state that is critical as the source of cosmic γ rays. It is therefore important to precisely determine the ground-state branching fraction f 0 of this resonance. Here we report on the identification of four γ-ray transitions from the 92-keV resonance, and determine the spin of the state and its ground-state branching fraction f 0 = 0.52 ( 2 ) s t a t ( 6 ) s y s t . The f 0 value is the most precise reported to date, and at the lower end of the range of previously adopted values, implying a lower production rate of 26 g Al and its cosmic 1809-keV γ rays.

Published

2021

26. 1-BENZYLSPIRO[PIPERIDINE-4,1'-PYRIDO[3,4-b]indole] 'co-potentiators' for minimal function CFTR mutants

Author

Puay-Wah Phuan, Alan S. Verkman, Jie S. Zhu, Jung-Ho Son, Ka Yi Tsui, Peter M. Haggie, Soren Lipman, Mark J. Kurth, Amy Cheung, and Dean J. Tantillo

Subjects

Models, Molecular, Indoles, Cystic Fibrosis, Mutant, Cystic Fibrosis Transmembrane Conductance Regulator, Quinolones, Aminophenols, 01 natural sciences, chemistry.chemical_compound, Piperidines, Models, Drug Discovery, CFTR, Chloride Channel Agonists, Lung, 0303 health sciences, biology, Chemistry, G%22">c.3700A>G, General Medicine, Pharmacology and Pharmaceutical Sciences, Small molecule, Cystic fibrosis transmembrane conductance regulator, Potentiator, Piperidine, Stereochemistry, Medicinal & Biomolecular Chemistry, Modulator, Article, Cell Line, 03 medical and health sciences, Structure-Activity Relationship, Medicinal and Biomolecular Chemistry, Rare Diseases, Potency, Animals, Humans, 030304 developmental biology, Pharmacology, Indole test, 010405 organic chemistry, Organic Chemistry, Molecular, N1303K-CFTR, 0104 chemical sciences, Rats, Mutation, biology.protein, +G%22">c.3700A > G, Function (biology)

Abstract

We previously identified a spiro [piperidine-4,1-pyrido [3,4-b]indole] class of co-potentiators that function in synergy with existing CFTR potentiators such as VX-770 or GLGP1837 to restore channel activity of a defined subset of minimal function cystic fibrosis transmembrane conductance regulator (CFTR) mutants. Here, structure-activity studies were conducted to improve their potency over the previously identified compound, 20 (originally termed CP-A01). Targeted synthesis of 37 spiro [piperidine-4,1-pyrido [3,4-b]indoles] was generally accomplished using versatile two or three step reaction protocols with each step having high efficiency. Structure-activity relationship studies established that analog 2i, with 6′-methoxyindole and 2,4,5-trifluorobenzyl substituents, had the greatest potency for activation of N1303K-CFTR, with EC50 ∼600 nM representing an ∼17-fold improvement over the original compound identified in a small molecule screen.

Published

2021

27. Highly deformed band structures due to core excitations in $^{123}$Xe

Author

A. Korichi, T. Lauritsen, A. Kardan, G. B. Hagemann, P. Fallon, F. G. Kondev, H. Hübel, B. M. Nyakó, S. Zhu, R. V. F. Janssens, Amrendra K. Singh, Anna Wilson, S. Chmel, T. L. Khoo, János Timár, B. Herskind, Martin Carpenter, B. G. Carlsson, G. Sletten, Ingemar Ragnarsson, Anwesha Basu, J. Rogers, Laboratoire de Physique des 2 Infinis Irène Joliot-Curie (IJCLab), and Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS)

Subjects

Physics, 010308 nuclear & particles physics, HIGH-SPIN, ROTATIONAL BANDS, Nuclear Theory, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], Nuclear Structure, 01 natural sciences, Molecular physics, CE, Core (optical fiber), TERMINATION, SHAPES, 0103 physical sciences, 010306 general physics, Nuclear Experiment

Abstract

High-spin states in Xe-123 were populated in the Se-80(Ca-48, 5n) Xe-123 reaction at a beam energy of 207 MeV. gamma-ray coincidence events were recorded with the Gammasphere spectrometer. Four new high-spin bands have been discovered in this nucleus. The bands are compared with those calculated within the framework of cranked Nilsson-Strutinsky and cranked Nilsson-Strutinsky-Bogoliubov models. It is concluded that the configurations of the bands involve two-proton excitations across the Z = 50 as well as excitation of neutrons across the N = 82 shell gaps resulting in a large deformation, epsilon(2) approximate to 0.30 and gamma approximate to 5 degrees.

Published

2021

28. Quasi-two-dimensional superconductivity in SnSe2 via organic ion intercalation

Author

D. H. Ma, L. K. Ma, M. Z. Shi, F. B. Meng, B. Lei, Xianhui Chen, C. S. Zhu, T. Wu, Kunling Peng, B. L. Kang, Z. Sun, Haiqian Wang, and J. H. Cui

Subjects

Superconductivity, Materials science, Physics and Astronomy (miscellaneous), Magnetoresistance, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Magnetic susceptibility, Crystallography, Electrochemical intercalation, Electrical resistivity and conductivity, Condensed Matter::Superconductivity, 0103 physical sciences, General Materials Science, 010306 general physics, 0210 nano-technology, Ion intercalation

Abstract

In this work, two organic-ion-intercalated $\mathrm{Sn}{\mathrm{Se}}_{2}$ superconductors, ${(\mathrm{TBA})}_{x}\mathrm{Sn}{\mathrm{Se}}_{2}$ $({T}_{c}\ensuremath{\sim}6.4\phantom{\rule{0.16em}{0ex}}\mathrm{K})$ and ${(\mathrm{CTA})}_{x}\mathrm{Sn}{\mathrm{Se}}_{2}$ $({T}_{c}\ensuremath{\sim}7.1\phantom{\rule{0.16em}{0ex}}\mathrm{K})$, are synthesized by an electrochemical intercalation method. Via the intercalation of organic ions, the interlayer distance is dramatically enlarged from 6.12 \AA{} of pristine $\mathrm{Sn}{\mathrm{Se}}_{2}$ to 18.62 and 14.74 \AA{} for ${(\mathrm{TBA})}_{x}\mathrm{Sn}{\mathrm{Se}}_{2}$ and ${(\mathrm{CTA})}_{x}\mathrm{Sn}{\mathrm{Se}}_{2}$, respectively. Bulk magnetic susceptibility measurements suggest that both superconductors exhibit a strong anisotropic superconducting shielding effect below ${T}_{c}$. Further measurements of resistivity, I-V characteristic curves, and magnetoresistance reveal a quasi-two-dimensional (2D) superconductivity in ${(\mathrm{CTA})}_{x}\mathrm{Sn}{\mathrm{Se}}_{2}$. The present work suggests that the organic-ion-intercalation method can induce quasi-2D superconductivity in $\mathrm{Sn}{\mathrm{Se}}_{2}$ layers and provides a simple and practical strategy to explore 2D superconductivity as well as other 2D phenomena in layered materials.

Published

2020

29. Study of J/ψ and ψ(3686)→Σ(1385)0Σ¯(1385)0 and Ξ0Ξ¯0

Author

Tao Luo, X. N. Ma, Y. T. Liang, F. De Mori, X. Y. Zhou, F. E. Maas, M. Fritsch, H. H. Liu, J. C. Li, B. X. Yu, T. Hu, S. L. Niu, Zhi Zeng, J. Zhuang, M. Kavatsyuk, F. Y. Li, R. Farinelli, Xiao-Rui Lyu, Z. J. Xiao, X. Q. Li, Y. F. Long, M. X. Luo, G. S. Varner, Zhiqing Liu, C. Hu, M. Maggiora, Ling Zhao, M. Greco, O. Bakina, D. V. Dedovich, X. F. Wang, Minglin Ma, X. Tang, J. Min, T. Johansson, J. F. Chang, H. S. Chen, Lei Zhao, Z. L. Hou, B. X. Zhang, H. L. Ma, D. M. Li, G. F. Xu, Q. M. Ma, O. B. Kolcu, X. Cai, S. Jin, P. X. Shen, H. L. Dai, Igor Boyko, Y. Ding, B. Kopf, M. Y. Dong, Z. Wu, B. J. Liu, K. L. He, B. Kloss, X. Y. Niu, Y. Yuan, L. W. Jiang, Y. S. Zhu, C. Z. Yuan, X. Q. Hao, K. Y. Liu, M. Pelizaeus, Y. B. Zhao, Y. Guo, M. Z. Wang, Xiaozhong Huang, Z. B. Li, W. Ikegami Andersson, Q. Ouyang, Jimin Zhao, Zhiqing Zhang, S. S. Fang, X. Y. Song, K. J. Zhu, W. Shan, Y. H. Zheng, Cong-Feng Qiao, O. Albayrak, T. Holtmann, J. Dong, W. Kühn, J. M. Bian, Z. Y. You, Z. A. Zhu, Bingxuan Liu, Yao Wang, Y. Q. Wang, Q. Liu, Andrzej Kupsc, M. Qi, H. J. Yang, Guangshun Huang, S. Nisar, L. Yan, R. Baldini Ferroli, X. D. Ruan, Y. B. Liu, Z. H. Wang, K. Goetzen, L. L. Ma, L. Gong, C. J. Tang, Y. Hu, Y. P. Lu, B. Wang, A. Calcaterra, Z. G. Zhao, P. L. Wang, X. L. Gao, M. L. Chen, S. J. Zhao, N. Yu. Muchnoi, X. S. Kang, Y. H. Zhang, J. Y. Liu, Y. H. Guan, H. B. Liu, W. G. Li, Q. P. Ji, S. Spataro, X. P. Xu, Y. F. Wang, G. Li, L. Zotti, L. G. Xia, Kai Liu, Y. Y. Liu, C. Leng, P. Musiol, C. F. Redmer, Xiaocong Ai, Lei Li, C. Schnier, D. Xiao, Q. A. Malik, C. Dong, S. Sosio, X. L. Luo, A. Amoroso, C. P. Shen, A. Dbeyssi, F. A. Harris, W. P. Wang, S. B. Liu, M. Kornicer, F. Bianchi, X. Y. Ma, J. H. Zou, M. Bertani, Q. J. Xu, W. X. Gong, Z. Haddadi, Jun-Yi Zhang, Y. P. Guo, Z. P. Zhang, H. H. Zhang, J. C. Chen, X. T. Huang, Z. J. Sun, H. Loehner, Yu Zhang, Magnus Wolke, Y. F. Liang, A. A. Zafar, Q. Gao, Z. Ning, L. Yang, L. J. Wu, Joachim Pettersson, Y. N. Gao, H. M. Liu, Y. Zhang, X. N. Li, C. D. Fu, Z. Y. Wang, C. Q. Feng, X. R. Chen, Y. J. Mo, Z. Y. Deng, A. Julin, Xuanhong Lou, Haiping Peng, G. F. Cao, G. Mezzadri, X. Fang, S. S. Sun, G. Rong, Nasser Kalantar-Nayestanaki, D. P. Jin, Y. Nefedov, Q. An, J. H. Liu, W. C. Yan, Z. L. Huang, Feng Liu, Ke Wang, J. J. Xu, G. R. Liao, Xingguo Li, X. H. Sun, D. W. Bennett, Zujian Wang, J. Z. Fan, A. Zhemchugov, C. Morales Morales, Dayong Wang, N. Qin, T. Weber, Y. J. Mao, Y. B. Li, H. X. Yang, M. Ablikim, Z. G. Wang, H. Y. Zhang, P. F. Duan, E. H. Thorndike, J. Q. Zhang, W. Gradl, I. Garzia, M. Ripka, J. S. Huang, H. B. Li, A. G. Denig, C. L. Luo, J. Z. Bai, X. Y. Jiang, C. X. Liu, G. F. Chen, C. C. Zhang, P. Kiese, G. Felici, Yunlong Zhang, Gianfranco Morello, Fenfen An, L. Q. Qin, B. L. Wang, D. Y. Wang, J. Y. Zhang, F. Feldbauer, B. Zhong, L. B. Guo, S. L. Olsen, R. A. Briere, X. B. Ji, M. Tiemens, S. Ahmed, Y. X. Yang, T. C. Zhao, X. S. Jiang, D. Bettoni, Liqing Xu, Cui Li, J. L. Zhang, P. Patteri, X. Y. Shen, R. Poling, X. C. Chen, H. Muramatsu, Ulrich Wiedner, R. Kliemt, Klaus Peters, L. P. Zhou, J. P. Liu, Y. Pan, J. Chai, Y. K. Heng, H. Leithoff, G. X. Sun, J. V. Bennett, Y. M. Ma, J. G. Messchendorp, Jie Yu, H. J. Li, Jin Li, J. P. Dai, Q. L. Xiu, T. J. Min, Jianping Zheng, S. Zhu, F. Li, T. Ma, Z. Jiao, Fu-Hu Liu, D. H. Zhang, F. C. Ma, O. Cakir, R. E. Mitchell, G. Cibinetto, A. Hafner, Qiunan Xu, S. J. Chen, Z. P. Mao, Q. Zhao, Y. Z. Sun, M. G. Zhao, R. P. Guo, Y. H. Xie, A. Q. Guo, J. Fang, Tao Li, Y. N. Zhang, Xiang Zhou, J. F. Qiu, L. Fava, Gang Zhao, S. Han, J. J. Zhang, M. Destefanis, W. M. Song, Z. Gao, Y. X. Xia, S. H. Zhu, Bibo Ke, L. H. Wu, Ch. Rosner, M. Savrie, Z. H. Qin, L. Xia, H. Liang, W. B. Yan, M. N. Achasov, I. B. Nikolaev, I. Uman, S. Pacetti, P. Larin, D. J. Ambrose, J. F. Sun, S. Z. Chen, M. Albrecht, S. Marcello, W. D. Li, Y. Zeng, Yaquan Fang, Jie Zhao, D. X. Lin, H. M. Hu, K. Li, X. K. Zhou, Fang Liu, I. Tapan, K. Schoenning, Q. Y. Li, B. S. Zou, Y. H. Yan, J. W. Zhang, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, J. W. Zhao, I. Denysenko, Niklaus Berger, Y. C. Zhu, B. Y. Zhang, H. Xiao, T. Held, X. Liu, H. R. Qi, Serkant Ali Cetin, D. Y. Liu, J. B. Jiao, S. Q. Zhang, S. Qian, Jialun Ping, K. Zhang, X. Y. Zhang, M. Lara, J. B. Liu, Y. J. Sun, E. Boger, M. H. Gu, H. Y. Sheng, C. X. Yu, B. Zheng, R. G. Ping, X. L. Ji, Z. T. Sun, G. A. Chelkov, Talib Hussain, Z. A. Liu, V. Prasad, Yanwei Wang, A. Yuncu, Y. G. Xie, Y. Ban, P. Weidenkaff, F. H. Heinsius, S. X. Du, Z. L. Dou, S. P. Wen, X. S. Qin, X. R. Zhou, Cheng Li, X. K. Chu, M. H. Ye, Peilian Liu, Lingxuan Zhang, Zhiyong Zhang, L. D. Liu, L. Y. Dong, W. J. Zheng, F. Nerling, J. H. Yin, K. H. Rashid, M. Shao, Y. T. Gu, E. Fioravanti, X. L. Kang, A. Sarantsev, D. H. Wei, P. R. Li, J. S. Lange, Q. W. Zhao, X. H. Mo, L. S. Wang, L. L. Wang, H. Cai, H. J. Lu, and J. G. Lu

Subjects

Baryon, Nuclear physics, Physics, Nuclear and High Energy Physics, Particle physics, Angular distribution, 010308 nuclear & particles physics, Branching fraction, Isospin, Electron–positron annihilation, 0103 physical sciences, 010306 general physics, 01 natural sciences

Abstract

We study the decays of J / ψ and ψ ( 3686 ) to the final states Σ ( 1385 ) 0 Σ ¯ ( 1385 ) 0 and Ξ 0 Ξ ¯ 0 based on a single baryon tag method using data samples of ( 1310.6 ± 7.0 ) × 10 6 J / ψ and ( 447.9 ± 2.9 ) × 10 6 ψ ( 3686 ) events collected with the BESIII detector at the BEPCII collider. The decays to Σ ( 1385 ) 0 Σ ¯ ( 1385 ) 0 are observed for the first time. The measured branching fractions of J / ψ and ψ ( 3686 ) to Ξ 0 Ξ ¯ 0 are in good agreement with, and much more precise than, the previously published results. The angular parameters for these decays are also measured for the first time. The measured angular decay parameter for J / ψ → Σ ( 1385 ) 0 Σ ¯ ( 1385 ) 0 , α = − 0.64 ± 0.03 ± 0.10 , is found to be negative, different to the other decay processes in this measurement. In addition, the “12% rule” and isospin symmetry in the decays of J / ψ and ψ ( 3686 ) to Ξ Ξ ¯ and Σ ( 1385 ) Σ ¯ ( 1385 ) are tested.

Published

2017

30. Observation and study of the decay J/ψ→ϕηη′

Author

X. L. Ji, Jun-Yi Zhang, Huanhuan Liu, Y. F. Wang, Z. Y. Zhang, G. Felici, D. Y. Liu, J. B. Jiao, T. Hussain, X. Y. Ma, Y. G. Xie, W. X. Gong, D. W. Bennett, Zujian Wang, Bibo Ke, W. B. Yan, F. De Mori, Z. L. Dou, X. Y. Zhou, T. Y. Qi, H. J. Li, G. R. Liao, C. H. Li, X. H. Sun, Y. Ding, M. Kuessner, Q. L. Xiu, J. Y. Liu, Q. Gao, Y. N. Gao, B. J. Liu, Y. Zhang, S. Pacetti, Feng Yan, R. Farinelli, Ke Li, X. K. Chu, Y. X. Xia, X. K. Zhou, M. H. Ye, X. F. Wang, Q. M. Ma, A. Mustafa, H. L. Ma, D. M. Li, H. Muramatsu, J. F. Sun, S. Marcello, Y. Zeng, Zhe Sun, S. Lusso, W. Kühn, Z. Y. You, Z. A. Zhu, M. Y. Dong, M. Pelizaeus, S. Ahmed, Y. X. Yang, Kang Li, H. J. Lu, J. G. Lu, Q. Zhao, Y. Z. Sun, I. K. Keshk, C. X. Lin, Alexander Leon Gilman, Gang Zhao, H. R. Qi, G. A. Chelkov, Xiao-Rui Lyu, M. Richter, Z. Ning, X. Y. Niu, Y. Yuan, Y. S. Zhu, Z. Gao, S. L. Niu, X. Q. Li, Y. F. Long, Zongyuan Wang, L. Y. Dong, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, J. H. Zou, S. S. Sun, Y. P. Guo, F. E. Maas, T. Hu, F. Li, X. Tang, J. J. Song, L. Sun, Serkant Ali Cetin, Yu Zhang, M. M. Ma, S. B. Liu, F. C. Ma, C. P. Shen, L. J. Wu, X. L. Li, O. Bakina, Y. H. Xie, Y. G. Gao, J. Pellegrino, X. Q. Hao, R. E. Mitchell, Yi Zhang, Y. Nefedov, M. Rolo, K. Y. Liu, W. S. Cheng, Yao Zhang, G. Li, M. Bertani, S. Qian, Q. An, Jialun Ping, Q. Liu, Tristan Weber, M. G. Zhao, Y. H. Yang, M. Kuemmel, Matthew Glenn Kurth, Y. J. Mo, S. Q. Qu, Q. Ouyang, Lingxuan Zhang, Z. B. Li, Fang Liu, K. Zhang, X. Y. Zhang, P. X. Shen, M. Maggiora, Ling Zhao, Z. Wu, S. S. Fang, W. Ikegami Andersson, Zhiqing Liu, Z. Haddadi, P. Larin, U. Wiedner, I. Denysenko, L. L. Ma, R. P. Guo, J. Zhu, L. Gong, J. F. Qiu, J. B. Liu, L. Yang, M. Papenbrock, P. Kiese, L. Fava, I. Tapan, Y. B. Liu, Lei Zhao, Z. L. Hou, T. Johansson, J. F. Chang, Zhiqing Zhang, X. H. Mo, B. Y. Zhang, P. L. Wang, F. Nerling, R. A. Briere, L. G. Xia, A. Amoroso, Y. H. Yan, C. D. Fu, C. Q. Feng, X. R. Chen, L. S. Wang, G. S. Huang, Z. A. Liu, Y. J. Sun, Yifan Yang, E. Boger, V. Prasad, X. L. Luo, Q. P. Ji, F. Cossio, I. R. Boyko, K. J. Zhu, Y. P. Lu, Yang Zhang, J. Chai, J. W. Zhao, O. B. Kolcu, X. S. Jiang, L. L. Wang, X. Cai, L. Lavezzi, K. Begzsuren, Dan Wang, A. Dbeyssi, G. Y. Tang, H. Cai, Y. C. Zhu, W. P. Wang, Liqing Xu, X. Y. Shen, S. J. Zhao, F. Bianchi, Y. Ban, P. Weidenkaff, I. B. Nikolaev, C. Z. Yuan, Y. H. Zheng, R. X. Yang, Cong-Feng Qiao, S. P. Wen, Z. Y. Deng, M. Ripka, J. H. Yin, A. Pitka, M. Kornicer, Angelo Rivetti, Jie Zhao, D. X. Lin, X. S. Qin, Alexey Zhemchugov, H. M. Hu, M. Shao, Y. T. Gu, F. H. Liu, G. X. Sun, J. V. Bennett, Li Yan, A. Julin, O. Cakir, Meng Wang, Muhammad Irshad, Yunlong Zhang, Z. Jiao, D. H. Zhang, H. L. Liu, T. Held, D. Bettoni, Nicolas Berger, N. Yu. Muchnoi, X. S. Kang, J. W. Zhang, E. Fioravanti, Y. H. Zhang, X. R. Zhou, Cheng Li, J. L. Zhang, F. A. Harris, Q. J. Xu, J. Q. Zhang, Y. T. Tan, A. Sarantsev, D. H. Wei, P. R. Li, J. S. Lange, C. Sowa, Y. B. Zhao, Jianping Zheng, J. Z. Bai, S. L. Olsen, S. Zhu, W. Shan, Z. P. Zhang, H. Leithoff, J. Dong, W. Gradl, J. C. Chen, T. Khan, M. H. Gu, R. Kiuchi, Xuanhong Lou, Z. Y. Wang, M. Albrecht, W. D. Li, Nasser Kalantar-Nayestanaki, D. Y. Wang, B. T. Tsednee, M. Qi, S. X. Du, C. Morales Morales, S. Nisar, X. H. Liu, C. J. Tang, Y. Hu, H. Y. Sheng, C. X. Yu, J. P. Dai, H. J. Yang, Yue Pan, M. Destefanis, X. L. Gao, B. Zheng, R. G. Ping, F. Feldbauer, D. Xiao, Z. L. Huang, Z. G. Wang, X. P. Xu, X. B. Ji, M. Tiemens, H. Y. Zhang, Feng Liu, M. Ablikim, X. Y. Jiang, H. Liang, C. Dong, S. Sosio, G. F. Chen, P. Patteri, J. Y. Zhang, X. N. Ma, Joachim Pettersson, A. Q. Guo, Z. Y. Peng, J. Min, R. Kliemt, A. Mangoni, A. Guskov, Jie Yu, H. B. Liu, Y. K. Heng, W. M. Song, B. Kopf, B. Wang, K. L. He, S. W. Han, M. Fritsch, M. Kavatsyuk, Jimin Zhao, Z. H. Qin, P. L. Li, X D Shi, C. F. Redmer, G. Cibinetto, Y. J. Mao, H. X. Yang, I. Garzia, B. X. Zhang, B. Garillon, Huihui Liu, Magnus Wolke, Y. F. Liang, J. G. Messchendorp, L. Koch, A. Khoukaz, Qiunan Xu, D. P. Jin, W. G. Li, A. G. Denig, Y. K. Sun, Xiaoyu Zhou, S. Spataro, H. M. Liu, Dayong Wang, N. Qin, J. F. Hu, G. F. Cao, I. Uman, R. Baldini Ferroli, Z. J. Xiao, Ke Liu, P. L. Chen, Xiaozhong Huang, X. L. Wang, Andrzej Kupsc, Krisztian Peters, M. L. Chen, J. Libby, Yaquan Fang, M. Greco, M. Z. Wang, Shou-hua Zhu, X. N. Li, Haiping Peng, K. Schoenning, Q. Y. Li, B. S. Zou, Ke Wang, Q. A. Malik, G. Mezzadri, W. C. Yan, X. Q. He, M. N. Achasov, L. P. Zhou, R. Poling, P. F. Duan, F. H. Heinsius, Y. M. Ma, Z. P. Mao, Fenfen An, J. Fang, Ch. Rosner, B. L. Wang, T. C. Zhao, Tao Luo, B. X. Yu, F. Y. Li, H. S. Chen, Alperen Yuncu, Jin Li, H. L. Dai, G. F. Xu, S. Jin, X. Y. Song, K. Goetzen, L. D. Liu, J. J. Xu, Z. Q. Yang, H. B. Li, C. L. Luo, J. S. Huang, C. X. Liu, Q. Zhou, C. C. Zhang, B. Zhong, Lei Li, M.G. Alekseev, A. N. Zhu, Tao Zhang, T. Ma, Xu Shan, J. C. Li, J. Zhuang, M. X. Luo, D. V. Dedovich, Xu Zhou, A. Calcaterra, Z. G. Zhao, S. Fegan, L. Z. Liao, Yu Bai, H. H. Zhang, Z. J. Sun, S. Maldaner, L. H. Wu, M. Savrie, Yi Jin, J. W. Li, Y. J. Xiao, Z. X. Meng, X. A. Xiong, A. A. Zafar, K. H. Rashid, Y. T. Liang, S. J. Chen, K. J. Li, X. T. Huang, and G. Rong

Subjects

Nuclear physics, Physics, Angular distribution, 010308 nuclear & particles physics, Branching fraction, Electron–positron annihilation, 0103 physical sciences, Detector, High Energy Physics::Experiment, Nuclear Experiment, 010306 general physics, Parity (mathematics), 01 natural sciences

Abstract

We report the observation and study of the decay J/psi -> phi eta eta' phi eta eta' using 1.3 x 10(9) J/psi events collected with the BESIII detector. Its branching fraction, including all possi ...

Published

2019

31. Observation of the W -annihilation decay Ds+→ωπ+ and evidence for Ds+→ωK+

Author

Yaquan Fang, Shou-hua Zhu, Y. H. Zheng, Cong-Feng Qiao, Q. Liu, Tristan Weber, L. L. Ma, L. Gong, N. Yu. Muchnoi, X. S. Kang, M. Richter, K. Schoenning, Q. Y. Li, B. S. Zou, L. G. Xia, A. Amoroso, Y. H. Zhang, Z. Ning, F. De Mori, A. Dbeyssi, X. Y. Zhou, T. Y. Qi, X. F. Wang, Q. M. Ma, A. Mustafa, Y. Yuan, Y. S. Zhu, Yu Zhang, M. Kornicer, Angelo Rivetti, X D Shi, A. Julin, P. Kiese, X. L. Ji, S. L. Olsen, Z. Y. Wang, M. Kuessner, Ke Wang, I. Uman, Y. X. Xia, Y. J. Mao, S. L. Yang, R. A. Briere, H. X. Yang, I. Garzia, G. S. Huang, M. Bertani, Z. Haddadi, Z. Y. Zhang, X. K. Zhou, G. R. Liao, X. S. Jiang, Z. J. Xiao, J. C. Li, R. Poling, P. F. Duan, F. H. Heinsius, J. Zhuang, H. Liang, S. B. Liu, Gianfranco Morello, L. Yang, P. L. Chen, Fenfen An, Yunlong Zhang, H. L. Liu, G. A. Chelkov, Q. P. Ji, B. Q. Wang, D. Bettoni, Y. Ding, J. L. Zhang, B. L. Wang, Z. X. Meng, M. X. Luo, Y. G. Xie, D. V. Dedovich, Xu Zhou, B. J. Liu, B. Garillon, Huihui Liu, Y. Nefedov, A. Pitka, T. C. Zhao, X. H. Liu, J. G. Messchendorp, K. Goetzen, Jianping Zheng, S. Zhu, X. A. Xiong, O. Cakir, Y. G. Gao, W. S. Cheng, Yao Zhang, G. Li, G. Y. Tang, Zhiqing Liu, Z. Gao, L. Koch, A. Khoukaz, J. P. Dai, H. B. Li, M. M. Ma, Qiunan Xu, Y. H. Xie, Xiaozhong Huang, W. Kühn, S. L. Niu, Z. L. Dou, S. X. Du, A. A. Zafar, K. Y. Liu, Z. Y. You, Manuel Lara, X. Q. Li, Y. F. Long, K. Ravindran, C. L. Luo, X. Xia, Q. Zhou, Jie Zhao, C. C. Zhang, D. X. Lin, T. Johansson, J. F. Chang, Alexey Zhemchugov, H. M. Hu, C. D. Fu, B. Zhong, L. B. Guo, R. Baldini Ferroli, C. Q. Feng, J. Pellegrino, Xiao-Rui Lyu, M. Maggiora, Ling Zhao, M. Destefanis, A. Q. Guo, C. W. Wang, Z. A. Zhu, Ke Liu, Y. T. Tan, Lei Li, Z. Y. Deng, M. Ripka, M.G. Alekseev, F. H. Liu, J. Q. Zhang, Krisztian Peters, W. Gradl, A. N. Zhu, Tao Zhang, X. Tang, Q. A. Malik, G. Mezzadri, W. C. Yan, Z. A. Liu, M. Kuemmel, Matthew Glenn Kurth, Bibo Ke, Y. F. Wang, Nicolas Berger, M. Z. Wang, O. B. Kolcu, M. G. Zhao, Y. H. Yang, W. B. Yan, V. Prasad, J. W. Zhang, L. M. Gu, M. N. Achasov, X. X. Ma, R. P. Guo, J. Zhu, L. P. Zhou, X. Cai, K. H. Rashid, Y. M. Ma, W. M. Song, Lei Zhao, Xu Shan, H. J. Lu, T. Holtmann, Andrzej Kupsc, D. Y. Wang, L. Lavezzi, A. Calcaterra, Z. G. Zhao, S. Fegan, J. G. Lu, Xingguo Li, M. Rolo, J. Min, Z. L. Hou, C. P. Shen, L. J. Wu, L. Z. Liao, Yu Bai, H. H. Zhang, Y. Ban, P. Weidenkaff, Z. J. Sun, S. Maldaner, F. E. Maas, T. Hu, Z. G. Wang, J. Chai, G. S. Varner, H. Y. Zhang, G. F. Chen, O. Bakina, H. B. Liu, B. Kopf, Y. T. Liang, S. J. Chen, Y. J. Mo, G. X. Sun, J. V. Bennett, Li Yan, Z. Jiao, D. H. Zhang, F. Cossio, Z. B. Li, W. Ikegami Andersson, C. Z. Yuan, X. P. Xu, X. B. Ji, M. Tiemens, P. Patteri, C. Sowa, Y. B. Zhao, K. J. Zhu, D. Y. Liu, J. B. Jiao, P. L. Wang, X. Q. Hao, S. Nakhoul, R. Kliemt, W. Shan, Dan Wang, S. Gu, X. N. Li, M. L. Chen, Haiping Peng, Tao Luo, Z. H. Qin, S. Pacetti, A. Mangoni, Meng Wang, Muhammad Irshad, S. P. Wen, A. Guskov, J. Y. Zhang, Jie Yu, W. G. Li, A. G. Denig, J. Y. Liu, X. S. Qin, P. Larin, J. F. Sun, K. L. He, S. W. Han, J. Dong, X. R. Zhou, P. X. Shen, Y. K. Sun, T. Hussain, X. Y. Ma, W. X. Gong, B. X. Yu, Xiaoyu Zhou, Ke Li, T. J. Min, Z. Wu, X. L. Gao, Zhi Zeng, Q. Gao, Y. N. Gao, Y. K. Heng, Jimin Zhao, G. F. Xu, S. Nisar, F. A. Harris, G. Cibinetto, S. Jin, S. Spataro, W. L. Chang, S. Marcello, Y. Zhang, P. L. Li, Y. Zeng, I. R. Boyko, S. J. Zhao, C. J. Tang, Y. Hu, Zhiqing Zhang, Fang Liu, Zhe Sun, Cheng Li, C. H. Li, X. H. Sun, Y. P. Lu, C. Dong, Shulei Zhang, F. Y. Li, S. Lusso, Liqing Xu, C. F. Redmer, S. Sosio, X. Y. Shen, H. Leithoff, L. H. Wu, H. M. Liu, U. Wiedner, I. Denysenko, Feng Yan, Q. J. Xu, H. S. Chen, Alperen Yuncu, J. Z. Fan, F. Li, M. Qi, M. Savrie, J. F. Hu, H. J. Yang, J. C. Chen, Xuanhong Lou, D. Xiao, Magnus Wolke, F. C. Ma, Y. B. Chen, S. Leiber, H. L. Dai, Nasser Kalantar-Nayestanaki, G. F. Cao, Y. F. Liang, Xiaofeng Zhu, J. Z. Zhang, Joachim Pettersson, Yi Jin, J. J. Song, B. Y. Zhang, C. Morales Morales, L. Sun, Yue Pan, D. P. Jin, J. W. Li, Jun-Yi Zhang, N. Qin, Y. J. Xiao, Z. P. Zhang, X. Y. Song, J. F. Qiu, M. Papenbrock, M. Y. Dong, X. N. Ma, L. Fava, D. W. Bennett, Zujian Wang, F. Nerling, A. Zallo, J. J. Xu, Yang Zhang, J. H. Zou, Z. Q. Yang, S. S. Sun, J. D. Lu, C. Schnier, Y. Q. Wang, X. T. Huang, G. Rong, R. Farinelli, R. E. Mitchell, M. Fritsch, J. S. Huang, M. Kavatsyuk, C. X. Liu, Lingxuan Zhang, S. Qian, Q. An, Jialun Ping, H. L. Ma, D. M. Li, K. Zhang, M. H. Gu, R. Kiuchi, X. Y. Zhang, H. Y. Sheng, H. Muramatsu, B. X. Zhang, C. X. Yu, T. Khan, J. B. Liu, B. Zheng, R. G. Ping, M. Pelizaeus, Y. J. Sun, Yifan Yang, E. Boger, S. Ahmed, Y. X. Yang, F. Feldbauer, Feng Liu, Q. Zhao, Y. Z. Sun, Z. P. Mao, C. X. Lin, M. Ablikim, X. Y. Jiang, J. Fang, Tao Li, Ch. Rosner, Alexander Leon Gilman, M. Rump, Gang Zhao, Zongyuan Wang, H. R. Qi, Y. P. Guo, Q. Ouyang, Serkant Ali Cetin, S. S. Fang, Y. B. Liu, X. L. Luo, K. Begzsuren, W. P. Wang, F. Bianchi, M. Albrecht, Huanhuan Liu, W. D. Li, B. T. Tsednee, G. Felici, Y. Fu, I. Tapan, I. B. Nikolaev, Y. H. Yan, J. W. Zhao, J. H. Yin, Y. C. Zhu, M. Shao, Y. T. Gu, H. J. Li, Q. L. Xiu, T. Held, Mario Greco, A. Sarantsev, D. H. Wei, P. R. Li, J. S. Lange, X. H. Mo, L. S. Wang, M. H. Ye, L. L. Wang, H. Cai, L. Y. Dong, W. J. Zheng, and J. Libby

Subjects

Physics, Annihilation, Luminosity (scattering theory), 010308 nuclear & particles physics, Electron–positron annihilation, media_common.quotation_subject, Detector, 01 natural sciences, Asymmetry, Nuclear physics, Amplitude, 0103 physical sciences, 010306 general physics, media_common

Abstract

We report the observation of W-annihilation decay Ds+→ωπ+ and evidence for Ds+→ωK+ in a data sample corresponding to an integrated luminosity of 3.19 fb-1 collected with the BESIII detector at a center-of-mass energy s=4.178 GeV. We obtain the branching fractions B(Ds+→ωπ+)=(1.77±0.32stat±0.13sys)×10-3 with a significance of 6.7σ and B(Ds+→ωK+)=(0.87±0.24stat±0.08sys)×10-3 with a significance of 4.4σ. This measurement provides critical information to determine the nonperturbative W-annihilation amplitudes and shows the potential of searching for CP asymmetry in Ds+→ωK+.

Published

2019

32. Search for baryon and lepton number violation in J/ψ→Λc+e−+c.c

Author

Y. J. Mo, Z. X. Meng, X. A. Xiong, C. Sowa, Y. B. Zhao, W. Shan, A. A. Zafar, J. Dong, X. Q. Hao, Qiang Zhao, S. Nisar, C. J. Tang, K. H. Rashid, Y. Hu, Y. H. Zheng, R. Farinelli, Y. P. Lu, Y. T. Liang, A. Calcaterra, Z. G. Zhao, S. Fegan, Xichao Ruan, S. J. Chen, K. J. Li, Q. P. Ji, I. R. Boyko, P. Larin, Cong-Feng Qiao, H. L. Ma, P. L. Wang, D. M. Li, X. L. Luo, M. H. Gu, Liqing Xu, X. Y. Shen, N. Yu. Muchnoi, Yu Bai, X. S. Kang, Y. H. Zhang, H. H. Zhang, D. Xiao, H. Muramatsu, H. Y. Sheng, S. L. Olsen, W. P. Wang, Y. Ding, F. Bianchi, Z. J. Sun, Z. H. Wang, P. Musiol, Z. Y. Wang, C. Schnier, Y. Q. Wang, X. T. Huang, G. Rong, M. Pelizaeus, F. De Mori, C. X. Yu, L. Koch, A. Khoukaz, D. Y. Liu, B. J. Liu, J. F. Sun, X. Y. Zhou, B. Zheng, R. G. Ping, L. H. Wu, T. Holtmann, J. C. Li, M. Savrie, Zongyuan Wang, M. M. Ma, Yi Jin, Bibo Ke, W. Kühn, W. B. Yan, Z. Y. You, Z. A. Zhu, X. H. Mo, L. S. Wang, M. H. Ye, R. Baldini Ferroli, S. Marcello, Y. Zeng, X. K. Chu, Y. J. Xiao, J. Y. Liu, J. Zhuang, M. X. Luo, Q. Ouyang, Krisztian Peters, M. Z. Wang, Q. A. Malik, G. Mezzadri, W. C. Yan, X. H. Liu, Zhe Sun, S. Pacetti, J. P. Dai, X. F. Wang, L. L. Wang, H. Cai, G. Y. Tang, X. Q. He, P. Kiese, D. V. Dedovich, Z. Y. Qu, Q. M. Ma, S. S. Fang, Y. B. Liu, Q. Gao, J. Chai, Y. H. Xie, J. Pellegrino, X. N. Li, C. P. Shen, Y. N. Gao, A. Mustafa, G. X. Sun, J. V. Bennett, Li Yan, Peilian Liu, Z. Jiao, Haiping Peng, Manuel Lara, D. H. Zhang, Y. X. Zhou, Jie Zhao, D. X. Lin, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, Alexey Zhemchugov, H. M. Hu, X. Y. Niu, I. Tapan, S. B. Liu, Y. H. Yan, I. Uman, Y. Nefedov, R. A. Briere, Jun-Yi Zhang, Huanhuan Liu, G. Felici, Lingxuan Zhang, X. N. Ma, Z. P. Zhang, Y. Yuan, Y. S. Zhu, M. Maggiora, Ling Zhao, Lei Zhao, S. Ahmed, Y. X. Yang, Ke Li, Z. L. Hou, J. J. Song, Meng Wang, B. X. Yu, Zhi Zeng, L. Y. Dong, D. W. Bennett, Zujian Wang, F. H. Liu, Nicolas Berger, J. W. Zhang, L. Sun, Yunlong Zhang, Yu Zhang, Q. Liu, Tristan Weber, Kang Li, W. J. Zheng, R. Kliemt, H. J. Li, H. B. Li, Fang Liu, M. N. Achasov, A. Zallo, L. P. Zhou, C. L. Luo, X. Xia, M. Fritsch, Q. L. Xiu, Z. A. Liu, G. S. Huang, X. S. Jiang, C. C. Zhang, D. Bettoni, J. L. Zhang, B. Zhong, L. B. Guo, M. Kavatsyuk, F. A. Harris, S. Q. Zhang, Jie Yu, L. L. Ma, L. Gong, L. G. Xia, A. Amoroso, Y. M. Ma, Zhiqing Liu, F. Y. Li, H. S. Chen, Alperen Yuncu, Z. P. Mao, Y. X. Xia, V. Prasad, I. B. Nikolaev, X. K. Zhou, U. Wiedner, I. Denysenko, J. H. Yin, J. W. Zhao, Y. C. Zhu, H. L. Dai, Lei Li, Y. Z. Sun, Z. J. Xiao, P. L. Chen, H. Leithoff, F. Li, Y. Ban, P. Weidenkaff, B. X. Zhang, M. Shao, Y. T. Gu, A. Dbeyssi, Xiao-Rui Lyu, C. Z. Yuan, Jianping Zheng, A. Pitka, S. Zhu, T. Ma, F. C. Ma, T. J. Min, K. J. Zhu, G. Cibinetto, M. Kuhlmann, T. Johansson, J. F. Chang, Y. G. Gao, S. P. Wen, M. Kornicer, G. R. Liao, X. S. Qin, B. Y. Zhang, X. R. Zhou, J. Fang, Tao Li, Yao Wang, O. Cakir, Gang Zhao, E. Fioravanti, Cheng Li, J. F. Qiu, M. Papenbrock, A. Julin, B. Q. Wang, S. X. Du, M. G. Zhao, Y. H. Yang, R. P. Guo, J. Zhu, G. S. Varner, Ke Wang, K. Y. Liu, L. Fava, X. L. Kang, A. Sarantsev, D. H. Wei, P. R. Li, Y. F. Wang, T. Khan, O. B. Kolcu, F. Nerling, X. Fang, J. S. Lange, X. Cai, J. Q. Li, H. Xiao, F. Feldbauer, J. Z. Bai, Z. L. Huang, Yang Zhang, Feng Liu, M. Destefanis, M. Ablikim, X. Y. Jiang, Ch. Rosner, R. Poling, M. Kuessner, L. Lavezzi, P. F. Duan, F. H. Heinsius, Gianfranco Morello, T. Held, M. Kuemmel, Fenfen An, C. Hu, B. L. Wang, X. Tang, Magnus Wolke, X. L. Ji, T. C. Zhao, T. Hussain, M. Y. Dong, G. A. Chelkov, M. Rolo, Y. F. Liang, D. P. Jin, Z. Y. Zhang, X. Y. Ma, W. X. Gong, Dan Wang, Y. G. Xie, S. Gu, J. M. Bian, Z. L. Dou, S. J. Zhao, M. Richter, Z. Ning, H. Liang, X. P. Xu, X. B. Ji, M. Tiemens, M. Albrecht, W. D. Li, X. L. Gao, C. Dong, S. Sosio, B. T. Tsednee, Dayong Wang, N. Qin, P. Patteri, Joachim Pettersson, J. H. Zou, C. H. Li, Xiaozhong Huang, Q. J. Xu, X. H. Sun, S. S. Sun, J. C. Chen, Xuanhong Lou, Yao Zhang, Z. Gao, G. Li, S. L. Niu, Ke Liu, S. Leiber, Nasser Kalantar-Nayestanaki, X. Q. Li, Y. F. Long, C. D. Fu, C. Morales Morales, Yue Pan, R. E. Mitchell, Z. G. Wang, C. Q. Feng, X. R. Chen, Yaquan Fang, M. Greco, H. Y. Zhang, Shou-hua Zhu, Andrzej Kupsc, Z. Y. Deng, M. Ripka, Z. B. Li, M. L. Chen, W. Ikegami Andersson, G. F. Chen, Xingguo Li, J. Y. Zhang, K. Schoenning, Q. Y. Li, B. S. Zou, Y. K. Heng, G. F. Xu, S. Jin, X. Y. Song, K. Goetzen, L. D. Liu, J. J. Xu, J. S. Huang, C. X. Liu, A. Q. Guo, J. B. Jiao, W. M. Song, S. Qian, Q. An, Jialun Ping, K. Zhang, X. Y. Zhang, J. B. Liu, Y. J. Sun, Yifan Yang, E. Boger, H. R. Qi, Y. P. Guo, Serkant Ali Cetin, Z. H. Qin, W. G. Li, A. G. Denig, Y. K. Sun, S. Spataro, M. Qi, H. J. Yang, H. M. Liu, G. F. Cao, Y. J. Mao, H. X. Yang, I. Garzia, Huihui Liu, J. P. Liu, J. G. Messchendorp, Qiunan Xu, J. Min, H. B. Liu, B. Kopf, K. L. He, C. Leng, S. W. Han, Jimin Zhao, P. L. Li, C. F. Redmer, M. Bertani, Z. Haddadi, L. Yang, J. Q. Zhang, W. Gradl, D. Y. Wang, H. J. Lu, J. G. Lu, F. E. Maas, T. Hu, O. Bakina, P. X. Shen, Z. Wu, Zhiqing Zhang, and L. J. Wu

Subjects

Physics, Particle physics, 010308 nuclear & particles physics, Branching fraction, Electron, 01 natural sciences, Lepton number, law.invention, Baryon, Positron, law, 0103 physical sciences, 010306 general physics, Collider

Abstract

Using 1.31×109 J/ψ events collected by the BESIII detector at the Beijing Electron Positron Collider, we search for the process J/ψ→Λc+e-+c.c. for the first time. In this process, both baryon and lepton number conservation is violated. No signal is found and the upper limit on the branching fraction B(J/ψ→Λc+e-+c.c.) is set to be 6.9×10-8 at the 90% confidence level.

Published

2019

33. Precision measurements of the e+e−→KS0K±π∓ Born cross sections at center-of-mass energies between 3.8 and 4.6 GeV

Author

S. Ahmed, Y. X. Yang, Kang Li, J. F. Qiu, M. Papenbrock, Xichao Ruan, Ke Wang, L. Fava, Y. H. Zheng, Cong-Feng Qiao, N. Yu. Muchnoi, M. H. Gu, H. Y. Sheng, M. Bertani, Z. Haddadi, L. Yang, R. Poling, P. F. Duan, F. H. Heinsius, Gianfranco Morello, Fenfen An, B. L. Wang, Y. Z. Sun, F. Nerling, X. Q. Hao, S. Nakhoul, F. De Mori, M. H. Ye, C. X. Yu, T. C. Zhao, Q. A. Malik, G. Mezzadri, W. C. Yan, Yang Zhang, H. B. Li, X. S. Kang, Y. H. Zhang, S. L. Olsen, M. Kuessner, L. D. Liu, S. B. Liu, L. Koch, A. Khoukaz, B. X. Yu, M. Kuemmel, P. Larin, C. L. Luo, Zhi Zeng, F. Y. Li, X. Y. Zhou, H. S. Chen, Alperen Yuncu, X. Xia, B. Zheng, H. L. Dai, R. Baldini Ferroli, Gang Zhao, L. Y. Dong, R. G. Ping, Zhiqing Liu, M. G. Zhao, Y. H. Yang, Z. Y. Wang, Krisztian Peters, M. Z. Wang, T. Khan, Y. Nefedov, X. N. Li, Z. P. Zhang, Y. T. Tan, R. P. Guo, M. N. Achasov, J. Zhu, L. P. Zhou, Haiping Peng, Y. M. Ma, S. Qian, Q. An, Jialun Ping, C. C. Zhang, B. Zhong, L. B. Guo, Lei Li, Y. Ding, W. Gradl, G. A. Chelkov, Huanhuan Liu, D. Y. Wang, D. W. Bennett, Zujian Wang, B. J. Liu, Z. A. Liu, G. Y. Tang, Z. P. Mao, J. Fang, Tao Li, W. J. Zheng, T. Johansson, J. F. Chang, J. Min, J. J. Xu, K. Zhang, X. L. Ji, X. Y. Zhang, H. B. Liu, J. B. Liu, F. Feldbauer, Manuel Lara, O. B. Kolcu, T. Ma, W. G. Li, X. F. Wang, Jie Zhao, D. X. Lin, V. Prasad, Z. X. Meng, B. Kopf, Dan Wang, Xu Shan, X. H. Liu, R. Farinelli, A. G. Denig, Y. Ban, Y. J. Sun, Yifan Yang, W. Kühn, J. C. Li, E. Boger, P. Weidenkaff, Ch. Rosner, S. Gu, J. P. Dai, J. Libby, Yaquan Fang, Alexey Zhemchugov, H. M. Hu, Y. H. Xie, J. Pellegrino, X. A. Xiong, F. H. Liu, X. Cai, L. Lavezzi, K. L. He, J. S. Huang, C. X. Liu, S. W. Han, G. Felici, S. P. Wen, M. Maggiora, Ling Zhao, R. Kliemt, I. B. Nikolaev, Lei Zhao, Z. L. Hou, G. R. Liao, Z. Y. Zhang, Z. Y. You, Z. A. Zhu, J. M. Zhang, Jimin Zhao, P. L. Li, J. Zhuang, H. L. Ma, M. X. Luo, D. M. Li, B. Q. Wang, Shou-hua Zhu, D. V. Dedovich, H. Muramatsu, M. Pelizaeus, Y. K. Sun, S. Spataro, M. Richter, Z. Ning, C. F. Redmer, K. Schoenning, Q. Y. Li, B. S. Zou, X. S. Qin, X. R. Zhou, Y. P. Lu, Cheng Li, Y. G. Xie, C. P. Shen, Q. M. Ma, J. F. Sun, Nicolas Berger, J. W. Zhang, S. Marcello, C. Sowa, Y. B. Zhao, J. H. Yin, M. Shao, Y. T. Gu, J. Q. Zhang, H. J. Lu, P. L. Wang, C. Z. Yuan, T. Holtmann, L. J. Wu, J. G. Lu, A. Mustafa, X. Y. Niu, Meng Wang, A. A. Zafar, E. Fioravanti, X. K. Chu, M. Qi, Y. Zeng, Zhe Sun, S. Lusso, H. Liang, H. J. Yang, J. Y. Liu, Q. P. Ji, M. Kuhlmann, Z. L. Dou, W. Shan, J. Dong, Y. J. Mo, X. K. Zhou, H. M. Liu, F. E. Maas, Z. L. Huang, K. H. Rashid, T. Hu, Feng Liu, M. Ablikim, X. Y. Jiang, Y. Yuan, Y. S. Zhu, T. Y. Qi, A. Calcaterra, Z. G. Zhao, S. Fegan, Yu Zhang, A. Sarantsev, D. H. Wei, P. R. Li, J. S. Lange, G. F. Xu, H. J. Li, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, Qiang Zhao, S. Nisar, S. Jin, J. J. Song, Q. L. Xiu, A. Guskov, O. Bakina, L. Sun, J. F. Hu, Xiao-Rui Lyu, F. A. Harris, C. J. Tang, Y. Hu, Yu Bai, H. H. Zhang, Y. X. Xia, Lingxuan Zhang, Ke Liu, P. X. Shen, Z. J. Sun, H. Leithoff, Y. T. Liang, Q. Gao, D. Xiao, Z. Gao, Z. Wu, H. R. Qi, X. Y. Song, Q. Liu, G. S. Varner, Y. N. Gao, I. R. Boyko, T. J. Min, K. J. Zhu, S. J. Chen, Y. Zhang, X. H. Mo, L. S. Wang, S. L. Niu, G. F. Cao, M. M. Ma, Y. X. Zhou, Y. G. Gao, Liqing Xu, K. Goetzen, Zhiqing Zhang, G. Cibinetto, X. Y. Shen, K. J. Li, Tristan Weber, Yao Wang, L. L. Ma, J. Z. Fan, L. Gong, Y. P. Guo, L. L. Wang, H. Cai, J. Chai, X. Q. Li, G. X. Sun, J. V. Bennett, Li Yan, X. N. Ma, Z. Jiao, D. H. Zhang, A. Zallo, X. L. Luo, L. G. Xia, A. Amoroso, X. P. Xu, X. B. Ji, M. Tiemens, M. Fritsch, P. Patteri, C. Schnier, Y. Q. Wang, M. Kavatsyuk, X. T. Huang, G. Rong, Y. F. Long, M. Alekseev, Yao Zhang, G. Li, W. P. Wang, B. X. Zhang, Serkant Ali Cetin, F. Bianchi, L. H. Wu, C. D. Fu, M. Savrie, A. Q. Guo, Yi Jin, A. Dbeyssi, C. Q. Feng, X. R. Chen, Y. J. Xiao, D. Y. Liu, J. B. Jiao, M. Kornicer, Zongyuan Wang, A. Julin, Q. Ouyang, S. S. Fang, W. M. Song, Y. B. Liu, K. Y. Liu, Z. H. Qin, Z. B. Li, W. Ikegami Andersson, Y. F. Wang, X D Shi, Y. J. Mao, H. X. Yang, T. Hussain, X. Y. Ma, I. Garzia, W. X. Gong, B. Garillon, Huihui Liu, J. G. Messchendorp, Qiunan Xu, C. H. Li, X. H. Sun, P. Kiese, R. A. Briere, G. S. Huang, X. S. Jiang, A. Pitka, O. Cakir, M. Y. Dong, I. Tapan, Y. H. Yan, J. W. Zhao, J. H. Zou, S. S. Sun, Y. C. Zhu, T. Held, Mario Greco, R. E. Mitchell, Bibo Ke, M. Albrecht, W. B. Yan, W. D. Li, B. T. Tsednee, S. Pacetti, Ke Li, Fang Liu, U. Wiedner, I. Denysenko, Xiaozhong Huang, B. Y. Zhang, Andrzej Kupsc, M. L. Chen, Magnus Wolke, Y. F. Liang, D. P. Jin, Dayong Wang, N. Qin, I. Uman, Z. J. Xiao, P. L. Chen, Yunlong Zhang, D. Bettoni, J. L. Zhang, Jianping Zheng, S. Zhu, S. X. Du, M. Destefanis, X. L. Gao, C. Dong, S. Sosio, S. J. Zhao, Joachim Pettersson, Q. J. Xu, X. Tang, J. C. Chen, Xuanhong Lou, M. Rolo, S. Leiber, Nasser Kalantar-Nayestanaki, C. Morales Morales, Yue Pan, F. Cossio, Z. G. Wang, H. Y. Zhang, G. F. Chen, J. Y. Zhang, Y. K. Heng, Z. Y. Deng, M. Ripka, Xingguo Li, F. Li, and F. C. Ma

Subjects

Nuclear physics, Physics, 010308 nuclear & particles physics, Electron–positron annihilation, 0103 physical sciences, Detector, Pi, Measure (physics), Center of mass, Born approximation, 010306 general physics, 01 natural sciences, Storage ring

Abstract

Using data samples collected by the BESIII detector operating at the BEPCII storage ring, we measure the e+e- → K0SK±π∓ Born cross sections at center-of-mass energies between 3.8 and 4.6 GeV, corre ...

Published

2019

34. Precision Measurement of the Branching Fractions of <math><mrow><msup><mrow><mi>η</mi></mrow><mrow><mo>′</mo></mrow></msup></mrow></math> Decays

Author

Y. B. Zhao, J. Dong, L. Koch, A. Khoukaz, S. Nisar, M. Kuemmel, Matthew Glenn Kurth, W. Shan, D. Y. Liu, J. B. Jiao, R. Baldini Ferroli, C. J. Tang, Y. Hu, Y. P. Lu, Z. A. Liu, S. J. Zhao, P. Kiese, H. J. Lu, J. G. Lu, M. Qi, J. J. Xu, Z. Q. Yang, F. E. Maas, T. Hu, O. Bakina, P. X. Shen, Z. Wu, Zhiqing Zhang, D. Xiao, Q. J. Xu, J. C. Chen, Xuanhong Lou, S. Leiber, Nasser Kalantar-Nayestanaki, Z. X. Meng, X. A. Xiong, Huanhuan Liu, T. Khan, G. Felici, Q. Liu, H. J. Yang, I. Uman, J. S. Huang, C. X. Liu, X. N. Li, Haiping Peng, J. Libby, R. Kliemt, Guangshun Huang, X. L. Ji, A. A. Zafar, Y. Ding, X. Y. Jiang, M. M. Ma, R. A. Briere, X. S. Jiang, Ke Wang, A. Mangoni, L. Yan, M. Kuessner, C. Morales Morales, K. H. Rashid, Z. G. Wang, H. Y. Zhang, Haiwen Liu, F. Feldbauer, A. Guskov, Jie Yu, L. L. Ma, L. Gong, Y. Ban, P. Weidenkaff, F. H. Heinsius, J. C. Li, J. Zhuang, M. X. Luo, D. V. Dedovich, S. Nakhoul, P. Larin, S. F. Zhang, Yaquan Fang, M. Albrecht, Y. T. Liang, W. Imoehl, Y. G. Xie, Z. L. Huang, S. J. Chen, Feng Liu, P. L. Wang, G. F. Xu, M. Ablikim, Y. Pan, Xu Zhou, Krisztian Peters, B. J. Liu, A. Pitka, G. F. Chen, A. Amoroso, K. J. Li, P. F. Duan, S. X. Du, Muhammad Irshad, K. J. Zhu, J. Chai, Fenfen An, V. Prasad, Z. L. Dou, S. Han, W. D. Li, B. L. Wang, G. X. Sun, J. V. Bennett, S. P. Wen, X. R. Zhou, T. Y. Qi, W. Kühn, S. L. Yang, Zhiqing Liu, G. Cibinetto, A. Dbeyssi, R. Farinelli, J. Y. Zhang, T. C. Zhao, G. A. Chelkov, H. J. Li, P. W. Luo, Z. Jiao, Fu-Hu Liu, D. H. Zhang, G. R. Liao, Cheng Li, Y. X. Xia, S. H. Zhu, L. H. Wu, K. Schoenning, Q. Y. Li, B. S. Zou, Z. Y. You, Z. A. Zhu, H. B. Li, A. G. Denig, C. L. Luo, S. Qian, Q. An, Jialun Ping, K. Zhang, X. Xia, Q. Zhou, B. T. Tsednee, T. Johansson, M. Savrie, J. F. Chang, Niklaus Berger, Xiao-Rui Lyu, Q. A. Malik, F. A. Harris, W. L. Chang, Q. L. Xiu, X. N. Ma, H. Leithoff, Yi Jin, H. H. Wang, S. B. Liu, Stephen Lars Olsen, H. L. Ma, Y. H. Xie, J. Pellegrino, T. Weber, J. W. Li, L. Xia, Y. Zhang, Tao Luo, D. M. Li, C. C. Zhang, G. Mezzadri, X. Y. Zhang, B. Zhong, L. B. Guo, Y. J. Xiao, Angelo Rivetti, F. Li, F. C. Ma, Y. G. Gao, L. K. Li, Zongyuan Wang, Jun-Yi Zhang, Y. P. Guo, Y. F. Wang, Y. H. Zheng, Cong-Feng Qiao, O. B. Kolcu, J. L. Zhang, F. F. Sui, L. Zhang, C. P. Shen, Y. Nefedov, Bibo Ke, X. H. Mo, L. S. Wang, J. B. Liu, M. Maggiora, Ling Zhao, W. M. Song, H. Muramatsu, A. N. Zhu, Ulrich Wiedner, N. Yu. Muchnoi, Tao Zhang, Y. J. Sun, Yifan Yang, L. M. Gu, G. Y. Tang, X. Cai, L. Lavezzi, L. P. Zhou, B. Wang, B. X. Yu, Y. M. Ma, Z. P. Zhang, M. H. Ye, X. B. Ji, M. Tiemens, M. H. Gu, R. Kiuchi, X. S. Kang, F. De Mori, W. B. Yan, H. Y. Sheng, Z. P. Mao, L. J. Wu, Jie Zhao, D. X. Lin, J. F. Sun, R. X. Yang, Y. H. Zhang, Xu Shan, Lei Zhao, Z. L. Hou, Alexey Zhemchugov, H. M. Hu, C. F. Redmer, J. F. Qiu, L. Fava, P. Patteri, P. L. Chen, D. W. Bennett, Zujian Wang, X. Q. Hao, Y Q Wang, Z. Y. Wang, Y. H. Yan, Q. Ouyang, C. X. Yu, Y. Bai, M. N. Achasov, Meng Wang, X. Y. Zhou, M. Kavatsyuk, J. Fang, Tao Li, M. Pelizaeus, L. L. Wang, H. Cai, H. S. Chen, A. Calcaterra, Z. G. Zhao, H. L. Dai, Igor Boyko, X. T. Huang, Michael Papenbrock, Bingxuan Liu, F. Yan, S. Marcello, B. Zheng, R. G. Ping, J. Min, Y. Zeng, L. Z. Liao, M. Richter, Z. Ning, S. S. Fang, W. S. Cheng, J. W. Zhao, Yao Zhang, G. Li, T. Hussain, Yang Zhang, X. Y. Ma, Y. C. Zhu, W. X. Gong, Zhe Sun, S. Lusso, H. H. Zhang, Z. Gao, S. Pacetti, A. Gilman, B. X. Zhang, X. Liu, M. Alekseev, H. R. Qi, Ch. Rosner, Z. J. Sun, C. D. Fu, J. Y. Liu, Y. B. Liu, Z. J. Xiao, B. Kopf, X. F. Wang, S. Maldaner, C. Q. Feng, X. R. Chen, X. K. Chu, Z. Y. Deng, Y. K. Heng, Cui Li, C. Z. Yuan, L. D. Liu, Y. B. Chen, Xingguo Li, L. Y. Dong, K. L. He, X. H. Sun, H. Liang, Xiaofeng Zhu, J. Z. Zhang, M. Z. Wang, Q. M. Ma, J. F. Hu, A. Mustafa, Zhiyong Zhang, X. L. Luo, J. J. Song, L. Sun, E. Boger, T. Held, Serkant Ali Cetin, W. J. Zheng, Ke Li, Jimin Zhao, P. L. Li, J. Q. Zhang, S. L. Niu, F. Nerling, Q. Gao, Y. N. Gao, M. Fritsch, F. Y. Li, X. Q. Li, Y. F. Long, M. Greco, M. Bertani, Z. Haddadi, K. Begzsuren, L. Yang, Magnus Wolke, Y. F. Liang, D. P. Jin, K. Y. Liu, Jianhao Zhang, M. Y. Dong, S. Q. Qu, Z. B. Li, W. Ikegami Andersson, I. B. Nikolaev, M. G. Zhao, Y. H. Yang, J. H. Yin, R. P. Guo, J. Zhu, Y. T. Tan, F. Bianchi, W. Gradl, M. Ripka, Dayong Wang, N. Qin, Ke Liu, D. Y. Wang, J. Z. Fan, M. Shao, Y. T. Gu, Xiaozhong Huang, Andrzej Kupsc, S. Ahmed, H. B. Liu, M. L. Chen, Y. X. Yang, A. Sarantsev, D. H. Wei, P. R. Li, J. S. Lange, Kang Li, J. H. Zou, Q. Zhao, S. S. Sun, Y. Z. Sun, Xiang Zhou, I. K. Keshk, X. S. Qin, Niu Xiaoyang, C. X. Lin, Gang Zhao, R. E. Mitchell, X. K. Zhou, Fang Liu, I. Denysenko, W. C. Yan, B. Y. Zhang, Y. Yuan, Y. S. Zhu, Yu Zhang, A. Q. Guo, Z. Y. Peng, C. W. Wang, G. Rong, W. P. Wang, Z. H. Qin, X D Shi, Y. J. Mao, H. X. Yang, I. Garzia, Y. J. Mo, Q. P. Ji, Liqing Xu, X. Y. Shen, B. Garillon, Huihui Liu, J. G. Messchendorp, J. P. Dai, W. G. Li, X. Tang, Y. K. Sun, Xiaoyu Zhou, S. Spataro, X. P. Xu, A. Yuncu, M. Rolo, Lei Li, G. F. Cao, F. Cossio, Yunlong Zhang, H. L. Liu, D. Bettoni, R. Poling, H. L. Jiang, Jianping Zheng, S. Zhu, T. J. Min, X. Y. Song, M. Destefanis, X. L. Gao, Shan Jin, K. Goetzen, C. Dong, S. Sosio, Joachim Pettersson, C. Sowa, and İstanbul Arel Üniversitesi

Subjects

Physics, Branching fraction, Electron–positron annihilation, ComputerSystemsOrganization_COMPUTER-COMMUNICATIONNETWORKS, General Physics and Astronomy, Branching (polymer chemistry), 01 natural sciences, High Energy Physics - Experiment, NO, Crystallography, ComputingMilieux_MANAGEMENTOFCOMPUTINGANDINFORMATIONSYSTEMS, ComputingMethodologies_PATTERNRECOGNITION, 0103 physical sciences, ddc:530, InformationSystems_MISCELLANEOUS, 010306 general physics

Abstract

PubMed ID: 31050481, Based on a sample of (1310.6±7.0)×106J/? events collected with the BESIII detector, we present measurements of J/? and ?? absolute branching fractions using the process J/?????. By analyzing events where the radiative photon converts into an e+e-pair, the branching fraction for J/????? is measured to be (5.27±0.03±0.05)×10-3. The absolute branching fractions of the five dominant decay channels of the ?? are then measured for the first time and are determined to be B(?????+?-)=(29.90±0.03±0.55)%, B(?????+?-)=(41.24±0.08±1.24)%, B(?????0?0)=(21.36±0.10±0.92)%, B(?????)=(2.489±0.018±0.074)%, and B(?????)=(2.331±0.012±0.035)%, where the first uncertainties are statistical and the second systematic. © 2019 authors. Published by the American Physical Society.

Published

2019

35. Determination of the Pseudoscalar Decay Constant fDs+ via Ds+→μ+νμ

Author

M. Richter, Z. Ning, S. J. Zhao, J. L. Zhang, J. Libby, M. H. Gu, Yaquan Fang, A. Pitka, H. Y. Sheng, C. X. Yu, W. G. Li, Q. J. Xu, F. De Mori, Y. K. Sun, Shan Jin, J. C. Chen, Xuanhong Lou, I. Uman, Q. P. Ji, S. Spataro, X. P. Xu, K. Goetzen, S. Leiber, Nasser Kalantar-Nayestanaki, K. Schoenning, Q. Y. Li, B. S. Zou, B. Zheng, R. G. Ping, Y. H. Zheng, Cong-Feng Qiao, Lei Li, C. Morales Morales, S. Nakhoul, Niklaus Berger, G. F. Cao, N. Yu. Muchnoi, Meng Wang, X. Y. Zhou, H. B. Li, A. G. Denig, C. L. Luo, M. Bertani, X. Xia, Q. Zhou, A. Q. Guo, C. W. Wang, G. Rong, Q. A. Malik, G. Mezzadri, X. S. Kang, Y. H. Zhang, Bingxuan Liu, X D Shi, Y. J. Mao, Z. Haddadi, X. K. Zhou, W. P. Wang, C. C. Zhang, B. Zhong, L. B. Guo, H. X. Yang, Z. H. Qin, L. Yang, I. Garzia, Fang Liu, P. Larin, Yao Zhang, G. Li, X. F. Wang, L. M. Gu, L. P. Zhou, Q. M. Ma, X. Y. Jiang, I. Denysenko, W. C. Yan, X. L. Gao, B. Garillon, Huihui Liu, J. G. Messchendorp, J. P. Dai, Z. T. Sun, Y. M. Ma, Z. Y. Wang, A. Gilman, C. D. Fu, A. Mustafa, Y. T. Tan, C. Dong, H. Muramatsu, A. N. Zhu, L. J. Wu, S. Qian, Q. An, Jialun Ping, Z. P. Mao, Qiunan Xu, C. Q. Feng, Z. Y. Deng, B. Y. Zhang, Y. Yuan, Y. S. Zhu, Yu Zhang, S. Sosio, Ulrich Wiedner, Tao Zhang, M. Kornicer, G. Y. Tang, W. Gradl, M. Ripka, D. Y. Wang, K. Zhang, X. Y. Zhang, J. Fang, Tao Li, Xingguo Li, Joachim Pettersson, Kai Liu, Q. Liu, R. Farinelli, Z. Gao, M. Qi, H. J. Yang, M. Lara, J. B. Liu, Y. Ban, P. Weidenkaff, F. H. Heinsius, R. Kliemt, Jie Zhao, D. X. Lin, M. M. Ma, Y. J. Mo, Alexey Zhemchugov, H. M. Hu, Xu Shan, L. L. Ma, L. Gong, X. Tang, A. Mangoni, A. Guskov, A. Amoroso, Ch. Rosner, S. P. Wen, M. G. Zhao, Y. H. Yang, X. X. Ma, Bibo Ke, J. Zhu, J. C. Li, Y. J. Sun, Yifan Yang, A. Yuncu, M. Rolo, W. B. Yan, S. B. Liu, Y. Zhang, A. Dbeyssi, M. N. Achasov, L. Zhang, Z. G. Wang, H. Y. Zhang, Y. P. Lu, K. J. Zhu, B. X. Yu, Zhi Zeng, X. R. Zhou, J. Zhuang, H. L. Ma, Cheng Li, Haiwen Liu, S. Pacetti, Y. Nefedov, J. Min, M. Alekseev, F. Cossio, G. Cibinetto, D. M. Li, Y. H. Xie, J. Pellegrino, A. Julin, M. X. Luo, G. F. Xu, I. B. Nikolaev, G. F. Chen, H. Liang, B. Kopf, Ke Li, K. L. He, D. V. Dedovich, T. Y. Qi, J. Y. Zhang, M. Y. Dong, M. Z. Wang, Y. Pan, Jimin Zhao, P. L. Li, M. Pelizaeus, Yunlong Zhang, M. Maggiora, Ling Zhao, H. B. Liu, J. H. Zou, Y. X. Xia, S. H. Zhu, H. L. Liu, J. Chai, D. Y. Liu, D. Bettoni, Cui Li, H. S. Chen, W. M. Song, S. S. Sun, M. Fritsch, X. B. Ji, M. Tiemens, J. B. Jiao, Liqing Xu, X. Y. Shen, P. Patteri, R. Poling, Jianping Zheng, S. Zhu, X. S. Qin, G. X. Sun, J. V. Bennett, Y. Ding, Jianhao Zhang, J. H. Yin, X. Y. Song, B. J. Liu, T. J. Min, Lei Zhao, R. E. Mitchell, Y. K. Heng, Ke Liu, H. L. Dai, Igor Boyko, M. Destefanis, W. Kühn, Z. L. Hou, Z. Y. You, Z. A. Zhu, J. J. Xu, T. Weber, L. Koch, A. Khoukaz, Z. Jiao, Fu-Hu Liu, D. H. Zhang, A. Calcaterra, Z. G. Zhao, S. Fegan, H. J. Lu, J. G. Lu, C. P. Shen, R. Baldini Ferroli, X. Liu, H. R. Qi, J. S. Huang, M. Shao, Y. T. Gu, C. X. Liu, L. Z. Liao, Serkant Ali Cetin, C. F. Redmer, J. D. Lu, X. N. Li, Haiping Peng, Ke Wang, F. E. Maas, T. Hu, P. F. Duan, Xiao-Rui Lyu, H. H. Zhang, Gianfranco Morello, Fenfen An, B. L. Wang, T. C. Zhao, J. F. Hu, C. Schnier, Z. J. Sun, O. Bakina, Jun-Yi Zhang, Y. P. Guo, Zhiyong Zhang, C. Z. Yuan, P. X. Shen, Z. Wu, Z. P. Zhang, Zhiqing Zhang, X. T. Huang, P. L. Chen, Guangshun Huang, L. Yan, D. W. Bennett, M. Kuessner, Zujian Wang, V. Prasad, S. Han, Y. Bai, G. A. Chelkov, L. H. Wu, M. Savrie, Yi Jin, Y. G. Gao, J. W. Li, L. Xia, Y. J. Xiao, C. Sowa, Y. B. Zhao, G. S. Varner, J. Dong, Z. X. Meng, X. A. Xiong, A. A. Zafar, Y. Q. Wang, Krisztian Peters, K. H. Rashid, Y. T. Liang, S. Nisar, S. J. Chen, T. Khan, C. J. Tang, Y. Hu, Z. A. Liu, A. Sarantsev, D. H. Wei, P. R. Li, J. S. Lange, D. Xiao, F. Feldbauer, X. L. Ji, Z. L. Huang, Feng Liu, S. L. Yang, M. Ablikim, Y. G. Xie, X. H. Mo, L. S. Wang, S. X. Du, Z. L. Dou, M. H. Ye, X. N. Ma, A. Zallo, Y. Fu, L. L. Wang, H. Cai, I. Tapan, G. R. Liao, B. Wang, Y. H. Yan, J. W. Zhao, Y. C. Zhu, L. Y. Dong, M. Kavatsyuk, W. J. Zheng, F. Nerling, B. X. Zhang, T. Held, M. Albrecht, W. D. Li, B. T. Tsednee, M. Kuemmel, Matthew Glenn Kurth, W. Shan, Dan Wang, J. F. Sun, Magnus Wolke, S. Marcello, Y. F. Liang, Y. Zeng, S. Lusso, D. P. Jin, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, J. J. Song, L. Sun, N. Qin, Xiaozhong Huang, Zongyuan Wang, S. F. Zhang, Andrzej Kupsc, M. L. Chen, Zhiqing Liu, T. Holtmann, T. Johansson, Y. F. Wang, J. F. Chang, J. Y. Liu, Q. Ouyang, T. Hussain, O. B. Kolcu, F. Li, Q. Gao, Y. N. Gao, X. Cai, L. Lavezzi, X. Y. Ma, S. S. Fang, W. X. Gong, F. C. Ma, X. Q. Hao, Michael Papenbrock, F. Yan, J. Z. Fan, Y. B. Liu, X. H. Sun, S. Ahmed, Huanhuan Liu, Y. X. Yang, Z. J. Xiao, P. Kiese, J. F. Qiu, G. Felici, L. Fava, S. L. Olsen, R. A. Briere, X. S. Jiang, Q. Zhao, Y. Z. Sun, Xiang Zhou, C. X. Lin, Yang Zhang, H. J. Li, O. Cakir, Gang Zhao, Q. L. Xiu, J. Q. Zhang, S. L. Niu, F. Y. Li, X. Q. Li, Y. F. Long, P. L. Wang, M. Greco, X. L. Luo, K. Begzsuren, Muhammad Irshad, F. A. Harris, F. Bianchi, W. L. Chang, K. Y. Liu, H. Leithoff, R. P. Guo, Z. B. Li, and W. Ikegami Andersson

Subjects

Quantum chromodynamics, Physics, Pseudoscalar, Crystallography, Branching fraction, Cabibbo–Kobayashi–Maskawa matrix, Electron–positron annihilation, Lattice (order), 0103 physical sciences, General Physics and Astronomy, Exponential decay, 010306 general physics, 01 natural sciences

Abstract

Using a 3.19 fb^{-1} data sample collected at an e^{+}e^{-} center-of-mass energy of E_{cm}=4.178 GeV with the BESIII detector, we measure the branching fraction of the leptonic decay D_{s}^{+}→μ^{+}ν_{μ} to be B_{D_{s}^{+}→μ^{+}ν_{μ}}=(5.49±0.16_{stat}±0.15_{syst})×10^{-3}. Combining our branching fraction with the masses of the D_{s}^{+} and μ^{+} and the lifetime of the D_{s}^{+}, we determine f_{D_{s}^{+}}|V_{cs}|=246.2±3.6_{stat}±3.5_{syst} MeV. Using the c→s quark mixing matrix element |V_{cs}| determined from a global standard model fit, we evaluate the D_{s}^{+} decay constant f_{D_{s}^{+}}=252.9±3.7_{stat}±3.6_{syst} MeV. Alternatively, using the value of f_{D_{s}^{+}} calculated by lattice quantum chromodynamics, we find |V_{cs}|=0.985±0.014_{stat}±0.014_{syst}. These values of B_{D_{s}^{+}→μ^{+}ν_{μ}}, f_{D_{s}^{+}}|V_{cs}|, f_{D_{s}^{+}} and |V_{cs}| are each the most precise results to date.

Published

2019

36. Observation of Ds+→pn¯ and confirmation of its large branching fraction

Author

G. F. Xu, S. Jin, L. J. Wu, X. Y. Song, R. Farinelli, H. J. Lu, J. G. Lu, A. Q. Guo, Z. Y. Peng, Y. J. Mo, J. Min, L. D. Liu, Z. G. Wang, H. Y. Zhang, J. J. Xu, Z. Q. Yang, W. M. Song, H. L. Ma, J. S. Huang, K. Goetzen, H. B. Liu, C. X. Liu, I. Uman, F. E. Maas, D. M. Li, T. Hu, H. Muramatsu, G. R. Liao, B. Kopf, G. F. Chen, J. Y. Zhang, Y. H. Xie, J. Pellegrino, Zhiqing Liu, X. L. Li, Z. H. Qin, H. B. Li, M. Pelizaeus, Q. P. Ji, T. Johansson, X. L. Ji, Z. J. Xiao, I. R. Boyko, C. L. Luo, Q. Zhou, P. L. Chen, J. F. Chang, Y. F. Wang, K. L. He, O. Bakina, M. Maggiora, Ling Zhao, M. H. Gu, R. Kiuchi, O. B. Kolcu, C. C. Zhang, Liqing Xu, T. Holtmann, B. Zhong, X. Y. Shen, X. Cai, S. B. Liu, S. W. Han, Z. Y. Zhang, L. Lavezzi, Lei Zhao, H. Y. Sheng, Y. H. Zheng, Y. Nefedov, Lei Li, Y. K. Heng, J. Y. Liu, M.G. Alekseev, Y. Ding, M. Kuemmel, Matthew Glenn Kurth, Cong-Feng Qiao, P. X. Shen, Z. Wu, Z. L. Hou, N. Yu. Muchnoi, X. S. Kang, R. Kliemt, C. X. Yu, M. Richter, Z. Ning, A. N. Zhu, Tao Zhang, X D Shi, H. R. Qi, Y. H. Zhang, B. J. Liu, C. Sowa, Jimin Zhao, Y. J. Mao, Y. G. Xie, L. H. Wu, S. L. Olsen, P. L. Wang, Meng Wang, H. Liang, T. Ma, Muhammad Irshad, Fang Liu, Q. Gao, Y. N. Gao, Y. P. Guo, A. Mangoni, Z. Y. Wang, P. L. Li, Y. Zhang, Zhiqing Zhang, B. Zheng, R. G. Ping, A. Guskov, Jie Yu, Y. B. Zhao, X. K. Zhou, W. Shan, Xu Shan, W. Kühn, H. X. Yang, Serkant Ali Cetin, I. Garzia, Z. L. Dou, J. Dong, M. Savrie, Feng Yan, U. Wiedner, I. Denysenko, X. K. Chu, Yi Jin, C. Z. Yuan, X. H. Liu, Z. Y. You, J. C. Li, Magnus Wolke, S. Qian, Q. An, Jialun Ping, M. G. Zhao, Y. H. Yang, G. S. Huang, K. Zhang, Y. F. Liang, X. Y. Zhang, R. P. Guo, J. Zhu, J. P. Dai, F. A. Harris, Xiao-Rui Lyu, C. F. Redmer, S. Nisar, Z. A. Zhu, D. P. Jin, B. Y. Zhang, J. Zhuang, S. Ahmed, Y. X. Yang, Kang Li, Z. P. Zhang, H. Leithoff, C. J. Tang, M. Qi, B. Garillon, Y. Hu, Huihui Liu, Y. P. Lu, H. J. Yang, F. Li, Dayong Wang, N. Qin, Dan Wang, K. J. Zhu, F. C. Ma, J. B. Liu, Y. J. Sun, Yifan Yang, E. Boger, Lingxuan Zhang, M. X. Luo, D. V. Dedovich, G. S. Varner, J. W. Li, Y. J. Xiao, S. J. Zhao, J. F. Sun, J. G. Messchendorp, Ke Liu, M. Kuessner, C. P. Shen, Q. Zhao, D. Xiao, S. Marcello, Y. Z. Sun, Xu Zhou, G. Cibinetto, M. M. Ma, Xiaozhong Huang, J. F. Qiu, Qiunan Xu, Z. A. Liu, D. Y. Liu, J. B. Jiao, W. G. Li, M. Papenbrock, A. G. Denig, Q. J. Xu, Y. Zeng, Zhe Sun, S. Lusso, Bibo Ke, V. Prasad, J. Libby, L. Fava, C. X. Lin, J. Q. Zhang, Y. K. Sun, Xiaoyu Zhou, G. A. Chelkov, F. Nerling, Alexander Leon Gilman, Gang Zhao, Y. Ban, P. Weidenkaff, W. B. Yan, S. Spataro, Andrzej Kupsc, Yaquan Fang, M. Greco, J. C. Chen, J. Chai, S. P. Wen, Xuanhong Lou, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, X. S. Qin, X. R. Zhou, Nasser Kalantar-Nayestanaki, M. L. Chen, H. M. Liu, W. S. Cheng, X. N. Ma, G. X. Sun, J. V. Bennett, Li Yan, Yang Zhang, Shou-hua Zhu, S. Pacetti, Z. Jiao, J. J. Song, D. H. Zhang, L. Sun, Yao Zhang, G. Li, J. F. Hu, Cheng Li, G. F. Cao, Jun-Yi Zhang, Ke Li, C. D. Fu, C. Morales Morales, Yue Pan, M. Y. Dong, C. Q. Feng, X. R. Chen, D. W. Bennett, Zujian Wang, A. Calcaterra, Z. G. Zhao, S. Fegan, Z. Y. Deng, M. Ripka, L. Z. Liao, J. H. Zou, C. Schnier, Y. Q. Wang, M. Bertani, X. T. Huang, S. S. Sun, G. Rong, Z. Haddadi, Yu Bai, Z. X. Meng, L. Yang, J. Z. Bai, K. Schoenning, Q. Y. Li, B. S. Zou, X. A. Xiong, Ke Wang, A. A. Zafar, H. H. Zhang, Q. A. Malik, Z. J. Sun, R. E. Mitchell, K. H. Rashid, X. P. Xu, X. B. Ji, G. Mezzadri, W. C. Yan, M. Tiemens, R. Poling, P. F. Duan, F. H. Heinsius, X. Q. He, Fenfen An, P. Patteri, B. L. Wang, Y. T. Liang, B. Wang, T. C. Zhao, S. J. Chen, K. J. Li, Y. T. Tan, W. Gradl, M. Fritsch, B. X. Yu, M. N. Achasov, L. P. Zhou, Zhi Zeng, F. Y. Li, H. S. Chen, Alperen Yuncu, Jin Li, Y. M. Ma, M. Kavatsyuk, D. Y. Wang, H. L. Dai, L. Koch, A. Khoukaz, R. Baldini Ferroli, Z. P. Mao, B. X. Zhang, Krisztian Peters, M. Z. Wang, J. Fang, X. N. Li, Haiping Peng, T. Khan, Ch. Rosner, F. Feldbauer, Z. L. Huang, Feng Liu, M. Ablikim, X. Y. Jiang, Huanhuan Liu, G. Felici, I. Tapan, Y. H. Yan, J. W. Zhao, Y. C. Zhu, T. Held, H. J. Li, Q. L. Xiu, M. Albrecht, W. D. Li, B. T. Tsednee, X. L. Luo, K. Begzsuren, W. P. Wang, F. Bianchi, Zongyuan Wang, Q. Ouyang, S. S. Fang, Y. B. Liu, Q. Liu, Tristan Weber, L. L. Ma, L. Gong, L. G. Xia, A. Amoroso, A. Dbeyssi, M. Kornicer, Angelo Rivetti, A. Julin, F. De Mori, X. Y. Zhou, X. F. Wang, Q. M. Ma, A. Mustafa, X. Y. Niu, Y. Yuan, Y. S. Zhu, Yu Zhang, T. Y. Qi, X. H. Mo, L. S. Wang, M. H. Ye, L. L. Wang, H. Cai, I. B. Nikolaev, J. H. Yin, M. Shao, Y. T. Gu, Y. X. Xia, E. Fioravanti, A. Sarantsev, D. H. Wei, P. R. Li, J. S. Lange, L. Y. Dong, Y. G. Gao, G. Y. Tang, Manuel Lara, Jie Zhao, D. X. Lin, Alexey Zhemchugov, H. M. Hu, F. H. Liu, Nicolas Berger, J. W. Zhang, X. Q. Hao, P. Larin, X. Tang, M. Rolo, F. Cossio, Yunlong Zhang, H. L. Liu, D. Bettoni, J. L. Zhang, Jianping Zheng, S. Zhu, S. X. Du, K. Y. Liu, M. Destefanis, X. L. Gao, P. Kiese, C. Dong, S. Sosio, R. A. Briere, Joachim Pettersson, X. S. Jiang, A. Pitka, O. Cakir, T. Hussain, X. Y. Ma, W. X. Gong, C. H. Li, X. H. Sun, Z. Gao, S. L. Niu, X. Q. Li, Y. F. Long, Z. B. Li, and W. Ikegami Andersson

Subjects

Physics, Strange quark, Meson, 010308 nuclear & particles physics, Branching fraction, High Energy Physics::Lattice, Star (game theory), Electron–positron annihilation, High Energy Physics::Phenomenology, Nuclear Theory, Hadron, General Physics and Astronomy, 01 natural sciences, Hadronization, Charm quark, Nuclear physics, Baryon, 0103 physical sciences, High Energy Physics::Experiment, Production (computer science), Nuclear Experiment, 010306 general physics, Energy (signal processing), Topology (chemistry), Bar (unit)

Abstract

We report on the first measurement of charm-strange meson D_{s}^{±} production at midrapidity in Au+Au collisions at sqrt[s_{NN}]=200 GeV from the STAR experiment. The yield ratio between strange (D_{s}^{±}) and nonstrange (D^{0}) open-charm mesons is presented and compared to model calculations. A significant enhancement, relative to a pythia simulation of p+p collisions, is observed in the D_{s}^{±}/D^{0} yield ratio in Au+Au collisions over a large range of collision centralities. Model calculations incorporating abundant strange-quark production in the quark-gluon plasma and coalescence hadronization qualitatively reproduce the data. The transverse-momentum integrated yield ratio of D_{s}^{±}/D^{0} at midrapidity is consistent with a prediction from a statistical hadronization model with the parameters constrained by the yields of light and strange hadrons measured at the same collision energy. These results suggest that the coalescence of charm quarks with strange quarks in the quark-gluon plasma plays an important role in D_{s}^{±}-meson production in heavy-ion collisions.

Published

2019

37. First Measurement of the Form Factors in Ds+→K0e+νe and Ds+→K*0e+νe Decays

Author

J. L. Zhang, M. H. Gu, R. Kiuchi, H. Y. Sheng, C. X. Yu, I. Uman, B. Zheng, R. G. Ping, S. Nakhoul, S. J. Zhao, L. J. Wu, Krisztian Peters, P. Larin, S. Ahmed, Y. X. Yang, Yunlong Zhang, H. L. Liu, D. Bettoni, Q. J. Xu, Y. J. Mo, Z. X. Meng, X. A. Xiong, J. C. Chen, Z. Gao, J. Q. Zhang, S. L. Niu, Xuanhong Lou, X. Y. Jiang, F. Y. Li, S. L. Yang, F. Li, X. Q. Li, Z. A. Liu, V. Prasad, Y. Ban, P. Weidenkaff, F. H. Heinsius, G. R. Liao, S. P. Wen, X. R. Zhou, Michael Papenbrock, F. Yan, Cheng Li, Nasser Kalantar-Nayestanaki, R. Poling, Jianping Zheng, S. Zhu, C. Morales Morales, Yue Pan, Y. F. Long, M. Greco, M. Bertani, Z. Haddadi, M. Albrecht, H. J. Lu, J. G. Lu, F. C. Ma, W. D. Li, X. K. Chu, J. F. Hu, R. Kliemt, Kang Li, Zhiyong Zhang, Q. Liu, L. Yang, A. A. Zafar, A. Mangoni, A. Guskov, Y. H. Xie, J. C. Li, Jie Yu, X. H. Mo, L. S. Wang, M. H. Ye, T. J. Min, M. Destefanis, F. E. Maas, T. Hu, J. F. Qiu, X. L. Gao, L. L. Ma, L. Gong, G. F. Xu, J. Pellegrino, B. Q. Wang, J. Zhuang, T. Khan, L. L. Wang, H. Cai, Y. T. Tan, M. Maggiora, Ling Zhao, W. M. Song, M. X. Luo, G. Y. Tang, W. Gradl, M. Ripka, S. Qian, Q. An, Jialun Ping, O. Bakina, K. Y. Liu, Z. J. Xiao, K. J. Zhu, L. Fava, Q. P. Ji, M. M. Ma, C. Dong, S. Sosio, Jie Zhao, D. X. Lin, S. Leiber, S. Q. Qu, Z. B. Li, W. Ikegami Andersson, L. G. Xia, A. Amoroso, K. H. Rashid, M. Kuemmel, Matthew Glenn Kurth, M. G. Zhao, Y. H. Yang, Q. Zhao, Alexey Zhemchugov, H. M. Hu, Y. Z. Sun, Xiang Zhou, K. Zhang, G. Cibinetto, Liqing Xu, S. F. Zhang, D. Y. Wang, Lei Zhao, M. Qi, H. J. Yang, J. Chai, W. Shan, D. V. Dedovich, Xu Zhou, L. M. Gu, R. P. Guo, Z. L. Hou, Y. T. Liang, X. Y. Shen, P. Kiese, X. Y. Zhang, P. X. Shen, G. X. Sun, J. V. Bennett, Z. Wu, Yang Zhang, A. Dbeyssi, C. X. Lin, J. W. Zhang, R. A. Briere, Gang Zhao, Joachim Pettersson, P. R. Li, S. J. Chen, Z. G. Wang, L. D. Liu, Z. Jiao, Fu-Hu Liu, D. H. Zhang, M. Richter, Y. Ding, Bingxuan Liu, G. S. Huang, X. S. Jiang, H. Y. Zhang, W. S. Cheng, L. Y. Dong, Z. Ning, X. Y. Song, K. J. Li, B. J. Liu, S. B. Liu, Angelo Rivetti, X. Tang, Yao Zhang, G. Li, J. B. Liu, J. J. Xu, M. Alekseev, T. Y. Qi, S. Han, Xiaozhong Huang, W. J. Zheng, L. Zhang, Z. Q. Yang, R. X. Yang, G. F. Chen, A. Julin, C. Z. Yuan, F. Feldbauer, A. Gilman, R. Farinelli, Y. Nefedov, Z. L. Huang, Feng Liu, W. Kühn, Z. Y. You, Z. A. Zhu, F. Nerling, Jun-Yi Zhang, Y. P. Guo, A. Yuncu, M. Rolo, Y. X. Xia, S. H. Zhu, Y. F. Wang, C. D. Fu, C. Q. Feng, X. R. Chen, Y. J. Sun, Yifan Yang, Y. P. Lu, L. H. Wu, J. Y. Zhang, A. Calcaterra, Z. G. Zhao, X. K. Zhou, Z. P. Zhang, H. L. Ma, J. S. Huang, M. Ablikim, S. Fegan, Z. Y. Deng, L. Z. Liao, C. X. Liu, D. M. Li, Xiao-Rui Lyu, Y. G. Gao, J. Zhu, M. Savrie, T. Weber, I. B. Nikolaev, F. Cossio, P. L. Chen, J. Min, Yi Jin, F. De Mori, H. H. Zhang, J. H. Yin, D. W. Bennett, Zujian Wang, T. Hussain, Xingguo Li, X. Y. Ma, Y. K. Heng, Y. Bai, Dan Wang, C. P. Shen, J. W. Li, B. Kopf, Z. J. Sun, M. Shao, Y. T. Gu, M. Pelizaeus, W. X. Gong, Andrzej Kupsc, X. N. Ma, X. L. Ji, K. L. He, Shan Jin, S. Maldaner, K. Goetzen, Zhiqing Liu, J. B. Jiao, Y. J. Xiao, M. Z. Wang, L. Yan, J. Y. Liu, H. B. Li, Jimin Zhao, E. Fioravanti, A. G. Denig, P. L. Li, C. L. Luo, M. Kuessner, X. Y. Zhou, J. F. Sun, X. Xia, Q. Zhou, C. Sowa, Y. B. Zhao, M. L. Chen, M. Kavatsyuk, T. Johansson, J. F. Chang, C. C. Zhang, B. Zhong, L. B. Guo, J. Dong, Q. Gao, Y. N. Gao, S. Marcello, Y. Zeng, Y. G. Xie, A. Sarantsev, D. H. Wei, J. Libby, Cui Li, J. S. Lange, Y. Zhang, X. H. Sun, S. Nisar, C. J. Tang, S. L. Olsen, Zhe Sun, S. Lusso, H. Muramatsu, A. N. Zhu, Ulrich Wiedner, Tao Zhang, S. X. Du, Y. Hu, G. A. Chelkov, B. X. Zhang, M. Kornicer, Z. L. Dou, O. B. Kolcu, Xu Shan, Tao Luo, D. Xiao, X. Cai, X. B. Ji, L. Lavezzi, M. Tiemens, X. F. Wang, Y. B. Chen, C. F. Redmer, B. X. Yu, P. Patteri, Xiaofeng Zhu, J. Z. Zhang, J. J. Song, I. K. Keshk, X. Q. Hao, L. Sun, H. S. Chen, H. L. Dai, Igor Boyko, Q. M. Ma, Ke Wang, X. T. Huang, A. Mustafa, P. F. Duan, Magnus Wolke, G. Rong, Fenfen An, B. L. Wang, T. C. Zhao, Y. F. Liang, D. P. Jin, L. Koch, A. Khoukaz, X. Y. Niu, R. Baldini Ferroli, Dayong Wang, N. Qin, Y. Yuan, Y. S. Zhu, X. N. Li, Yu Zhang, Haiping Peng, X. Liu, H. R. Qi, B. T. Tsednee, Y. H. Yan, J. W. Zhao, Y. C. Zhu, Serkant Ali Cetin, E. Boger, T. Held, M. Y. Dong, H. B. Liu, J. H. Zou, S. S. Sun, X. S. Qin, R. E. Mitchell, Bibo Ke, W. B. Yan, M. N. Achasov, S. Pacetti, P. L. Wang, Meng Wang, Muhammad Irshad, Dean Liu, Ke Li, F. A. Harris, W. L. Chang, H. Leithoff, Fang Liu, I. Denysenko, X D Shi, W. C. Yan, Y. J. Mao, H. X. Yang, I. Garzia, B. Garillon, Huihui Liu, B. Y. Zhang, J. G. Messchendorp, J. P. Dai, W. G. Li, Y. K. Sun, Xiaoyu Zhou, S. Spataro, X. P. Xu, Lei Li, H. M. Liu, G. F. Cao, A. Q. Guo, Z. Y. Peng, C. W. Wang, Z. H. Qin, H. Liang, M. Fritsch, Ke Liu, Q. A. Malik, G. Mezzadri, X. Q. He, Zongyuan Wang, Q. Ouyang, L. P. Zhou, S. S. Fang, Y. M. Ma, Z. P. Mao, Y. B. Liu, X. L. Luo, J. Fang, Tao Li, K. Begzsuren, W. P. Wang, F. Bianchi, Ch. Rosner, D. Y. Liu, Yaquan Fang, A. Pitka, Huanhuan Liu, G. Felici, K. Schoenning, Q. Y. Li, H. J. Li, B. S. Zou, Q. L. Xiu, Niklaus Berger, Zhiqing Zhang, Y. H. Zheng, Cong-Feng Qiao, N. Yu. Muchnoi, X. S. Kang, Y. H. Zhang, and Z. Y. Wang

Subjects

Germanium compounds, Physics, Crystallography, Annihilation, Branching fraction, 0103 physical sciences, Hadron, General Physics and Astronomy, 010306 general physics, 01 natural sciences

Abstract

We report on new measurements of Cabibbo-suppressed semileptonic D_{s}^{+} decays using 3.19 fb^{-1} of e^{+}e^{-} annihilation data sample collected at a center-of-mass energy of 4.178 GeV with the BESIII detector at the BEPCII collider. Our results include branching fractions B(D_{s}^{+}→K^{0}e^{+}ν_{e})=[3.25±0.38(stat)±0.16(syst)]×10^{-3} and B(D_{s}^{+}→K^{*0}e^{+}ν_{e})=[2.37±0.26(stat)±0.20(syst)]×10^{-3}, which are much improved relative to previous measurements, and the first measurements of the hadronic form-factor parameters for these decays. For D_{s}^{+}→K^{0}e^{+}ν_{e}, we obtain f_{+}(0)=0.720±0.084(stat)±0.013(syst), and for D_{s}^{+}→K^{*0}e^{+}ν_{e}, we find form-factor ratios r_{V}=V(0)/A_{1}(0)=1.67±0.34(stat)±0.16(syst) and r_{2}=A_{2}(0)/A_{1}(0)=0.77±0.28(stat)±0.07(syst).

Published

2019

38. Observation of D+→f0(500)e+νe and Improved Measurements of D→ρe+νe

Author

S. J. Zhao, S. Qian, Jialun Ping, K. Zhang, X. Y. Zhang, J. B. Liu, R. Farinelli, Q. J. Xu, Y. J. Sun, Yifan Yang, M. Bertani, Yunlong Zhang, Z. Haddadi, L. Yang, Y. P. Lu, J. C. Chen, Xuanhong Lou, H. L. Liu, D. Bettoni, H. L. Ma, D. M. Li, R. Poling, Nasser Kalantar-Nayestanaki, H. L. Jiang, Jianping Zheng, C. Morales Morales, L. J. Wu, S. Zhu, S. Leiber, M. Pelizaeus, I. B. Nikolaev, J. H. Yin, Michael Papenbrock, Bingxuan Liu, F. Yan, Y. Ban, P. Weidenkaff, Shan Jin, F. H. Heinsius, Y. J. Mo, M. Shao, Y. T. Gu, K. Goetzen, Y. T. Tan, M. Richter, T. J. Min, W. S. Cheng, Yao Zhang, G. Li, L. Zhang, S. P. Wen, Y. Nefedov, W. Gradl, X. L. Ji, M. Ripka, A. Gilman, X. R. Zhou, M. Destefanis, I. Uman, Z. Ning, M. G. Zhao, Y. H. Yang, R. P. Guo, Z. J. Xiao, M. Albrecht, Z. G. Wang, H. Y. Zhang, Cheng Li, Haiwen Liu, C. D. Fu, Q. P. Ji, L. M. Gu, P. Kiese, D. Y. Wang, E. Fioravanti, J. F. Sun, G. F. Chen, Minglin Ma, C. Q. Feng, X. R. Chen, S. Ahmed, Y. X. Yang, W. D. Li, B. T. Tsednee, R. A. Briere, J. Y. Zhang, Liqing Xu, X. K. Zhou, Fang Liu, Kang Li, J. L. Zhang, X. Tang, Z. Y. Deng, P. L. Wang, S. Nakhoul, F. F. Sui, M. H. Gu, R. Kiuchi, J. Min, A. Sarantsev, X. S. Jiang, X. Y. Shen, D. H. Wei, P. R. Li, J. Libby, Cui Li, S. Marcello, Y. Zeng, A. Yuncu, M. Rolo, H. Y. Sheng, F. De Mori, S. L. Olsen, H. J. Lu, J. G. Lu, Zongyuan Wang, I. Denysenko, Xingguo Li, Muhammad Irshad, W. G. Li, Q. Zhao, X. Y. Jiang, J. S. Lange, Meng Wang, D. Y. Liu, J. B. Jiao, Yuekun Heng, Y. H. Yan, Y. K. Sun, J. W. Zhao, W. C. Yan, C. X. Yu, Zhe Sun, S. Lusso, X. Y. Zhou, H. H. Wang, Y. Ding, P. Larin, Y. Z. Sun, B. Kopf, X. Y. Niu, Dean Liu, B. J. Liu, Xiaoyu Zhou, C. F. Redmer, Y. C. Zhu, M. H. Ye, Shuangli Yang, K. L. He, B. Zheng, R. G. Ping, Xiang Zhou, J. Q. Zhang, S. L. Niu, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, Q. Ouyang, A. Calcaterra, Z. G. Zhao, S. Fegan, F. Y. Li, R. Kliemt, L. Z. Liao, W. Kühn, X. N. Ma, A. Mangoni, F. Cossio, C. X. Lin, A. Guskov, S. S. Fang, Jie Yu, Gang Zhao, M. Z. Wang, F. E. Maas, S. Spataro, Y. G. Xie, X. Q. Li, Y. F. Long, M. Greco, B. Y. Zhang, X. F. Wang, Xiaozhong Huang, E. Boger, I. K. Keshk, Z. Y. You, K. J. Zhu, X. P. Xu, Z. A. Zhu, J. J. Song, L. Sun, Jimin Zhao, Q. M. Ma, G. F. Xu, X. K. Chu, T. Held, F. A. Harris, X. T. Huang, W. L. Chang, Y. B. Liu, P. L. Li, H. H. Zhang, T. Weber, A. Mustafa, L. D. Liu, L. Y. Dong, J. Y. Liu, C. P. Shen, G. Y. Tang, Y. H. Zheng, X. L. Luo, Z. J. Sun, G. Cibinetto, S. X. Du, Z. L. Dou, T. Hu, K. Y. Liu, H. Leithoff, Lei Li, V. Prasad, S. Han, F. Li, S. Maldaner, Q. Gao, Y. N. Gao, Krisztian Peters, Yi-Tao Wang, F. C. Ma, Andrzej Kupsc, M. Qi, S. Q. Qu, Z. B. Li, W. Ikegami Andersson, H. J. Yang, Y. Yuan, Y. S. Zhu, Cong-Feng Qiao, Jie Zhao, D. X. Lin, J. F. Hu, N. Yu. Muchnoi, X. L. Gao, K. Begzsuren, Q. An, X. Liu, Yu Zhang, Y. F. Wang, J. C. Li, Alexey Zhemchugov, H. M. Hu, H. R. Qi, W. J. Zheng, Guangshun Huang, T. Hussain, L. H. Wu, Zhiyong Zhang, X. S. Kang, Y. H. Zhang, F. Bianchi, J. Zhuang, Q. Liu, X. Y. Ma, F. Nerling, M. Savrie, M. X. Luo, Y. Pan, X. Y. Song, M. Kavatsyuk, G. R. Liao, O. Bakina, D. V. Dedovich, Bibo Ke, W. B. Yan, W. X. Gong, G. F. Cao, C. Dong, S. Sosio, M. L. Chen, L. Yan, Xu Zhou, M. N. Achasov, Yi Jin, Serkant Ali Cetin, L. L. Ma, L. Gong, J. Chai, Xiao-Rui Lyu, B. Q. Wang, J. W. Li, M. Kuessner, L. Xia, Z. Y. Wang, X. H. Sun, X. B. Ji, M. Tiemens, J. J. Xu, Z. Q. Yang, M. Alekseev, Huanhuan Liu, A. Amoroso, S. Pacetti, Y. J. Xiao, G. X. Sun, J. V. Bennett, P. Patteri, Y. Zhang, T. Y. Qi, Joachim Pettersson, J. F. Qiu, P. X. Shen, M. Kuemmel, Matthew Glenn Kurth, Z. Wu, H. B. Li, G. Felici, A. G. Denig, A. Q. Guo, Z. Y. Peng, Y. G. Gao, J. Zhu, C. L. Luo, L. Fava, Z. X. Meng, X. Xia, Q. Zhou, S. B. Liu, X. A. Xiong, C. W. Wang, G. Rong, W. Shan, A. Dbeyssi, J. S. Huang, C. C. Zhang, Y. X. Xia, S. H. Zhu, A. A. Zafar, B. Zhong, L. B. Guo, C. X. Liu, X. H. Mo, L. S. Wang, Ke Li, Angelo Rivetti, H. Muramatsu, A. N. Zhu, M. Y. Dong, Z. Jiao, Fu-Hu Liu, Ulrich Wiedner, D. H. Zhang, Tao Zhang, H. J. Li, Zhiqing Zhang, Q. L. Xiu, Magnus Wolke, B. X. Zhang, M. Kornicer, A. Julin, R. X. Yang, T. Khan, K. H. Rashid, Y. F. Liang, H. B. Liu, D. P. Jin, L. L. Wang, H. Cai, Xu Shan, Dan Wang, Y. T. Liang, Yang Zhang, S. J. Chen, G. A. Chelkov, W. P. Wang, J. H. Zou, C. Sowa, Y. B. Zhao, S. S. Sun, Z. H. Qin, K. J. Li, X D Shi, Dayong Wang, N. Qin, X. S. Qin, J. Dong, Y. J. Mao, H. X. Yang, I. Garzia, R. E. Mitchell, Y. H. Xie, S. Nisar, C. J. Tang, Y. Hu, B. Garillon, Huihui Liu, J. Pellegrino, Z. A. Liu, F. Feldbauer, J. G. Messchendorp, Z. L. Huang, Feng Liu, M. Maggiora, J. P. Dai, Ling Zhao, D. Xiao, W. M. Song, M. Ablikim, Lei Zhao, S. F. Zhang, Jun-Yi Zhang, Y. P. Guo, Z. P. Zhang, Z. L. Hou, P. L. Chen, D. W. Bennett, Zujian Wang, Y. Bai, C. Z. Yuan, Zhiqing Liu, T. Johansson, J. F. Chang, O. B. Kolcu, X. Cai, L. Lavezzi, X. Q. Hao, L. Koch, A. Khoukaz, R. Baldini Ferroli, X. N. Li, Haiping Peng, Tao Luo, Yaquan Fang, B. X. Yu, A. Pitka, H. S. Chen, H. L. Dai, Igor Boyko, K. Schoenning, Q. Y. Li, B. S. Zou, Niklaus Berger, Ke Wang, Q. A. Malik, G. Mezzadri, X. Q. He, L. P. Zhou, P. F. Duan, Fenfen An, Y. M. Ma, Z. P. Mao, B. L. Wang, T. C. Zhao, J. Fang, Tao Li, Z. Gao, Ch. Rosner, H. Liang, M. Fritsch, Jianhao Zhang, and Ke Liu

Subjects

Nuclear physics, Physics, Cross section (physics), Luminosity (scattering theory), 0103 physical sciences, Detector, General Physics and Astronomy, Sigma, High Energy Physics::Experiment, 010306 general physics, 01 natural sciences, Energy (signal processing)

Abstract

Using a data sample corresponding to an integrated luminosity of 2.93 fb(-1) recorded by the BESIII detector at a center-of-mass energy of 3.773 GeV, we present an analysis of the decays D-0 -> ...

Published

2019

39. Measurement of e+e−→K+K− cross section at s=2.00 – 3.08 GeV

Author

J. F. Sun, Tao Luo, Q. Liu, P. L. Wang, X. L. Gao, Q. A. Malik, G. Mezzadri, X. L. Luo, W. C. Yan, H. J. Lu, K. Begzsuren, W. P. Wang, Tristan Weber, F. Bianchi, D. Y. Liu, Bibo Ke, R. Kliemt, X. Q. He, A. Mangoni, J. G. Lu, A. Guskov, P. Kiese, M. Qi, Y. Ding, B. J. Liu, L. L. Ma, L. Gong, H. J. Yang, W. B. Yan, R. A. Briere, Jie Yu, L. G. Xia, H. B. Li, M. N. Achasov, L. P. Zhou, C. Dong, F. E. Maas, S. Marcello, Y. Zeng, S. Sosio, X. S. Jiang, G. F. Xu, Meng Wang, Muhammad Irshad, A. Amoroso, B. X. Yu, S. Jin, T. Hu, S. Lusso, Magnus Wolke, Y. F. Liang, K. J. Zhu, W. Kühn, M. G. Zhao, Y. H. Yang, A. Dbeyssi, Y. M. Ma, Z. P. Mao, S. Pacetti, G. Cibinetto, R. X. Yang, R. P. Guo, J. Zhu, A. Pitka, X. L. Li, D. P. Jin, M. Kornicer, Y. H. Zheng, Cong-Feng Qiao, C. L. Luo, Q. Zhou, T. Y. Qi, N. Yu. Muchnoi, W. G. Li, M. Kuessner, O. Cakir, O. Bakina, Angelo Rivetti, Z. Y. You, Z. A. Zhu, J. Z. Bai, Joachim Pettersson, F. A. Harris, Z. Gao, S. L. Niu, J. Y. Liu, A. Julin, F. Y. Li, H. S. Chen, Dayong Wang, N. Qin, Alperen Yuncu, Jin Li, X. S. Kang, Y. H. Zhang, S. B. Liu, Z. P. Zhang, H. Leithoff, J. Fang, X. Q. Li, Y. F. Long, Ke Li, X. T. Huang, G. Rong, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, M. M. Ma, Y. X. Xia, M. Albrecht, S. J. Zhao, Yunlong Zhang, A. G. Denig, Y. K. Sun, Xiaoyu Zhou, X. Y. Song, F. De Mori, S. L. Olsen, H. L. Dai, P. X. Shen, J. J. Song, Z. Wu, H. L. Liu, L. D. Liu, Y. Nefedov, L. Sun, X. Y. Zhou, Ch. Rosner, X. K. Zhou, C. P. Shen, X. P. Xu, X. B. Ji, M. Tiemens, P. Patteri, Z. Y. Wang, D. Bettoni, J. L. Zhang, G. A. Chelkov, L. Koch, A. Khoukaz, Yi Zhang, K. Y. Liu, S. Q. Qu, Z. B. Li, W. Ikegami Andersson, I. Uman, M. Y. Dong, J. J. Xu, C. C. Zhang, B. Zhong, F. Li, F. C. Ma, Zhiqing Zhang, W. D. Li, Lei Li, Z. Q. Yang, J. Min, S. Spataro, L. H. Wu, H. Liang, M. Savrie, Z. A. Liu, Q. P. Ji, Q. J. Xu, J. C. Chen, Xuanhong Lou, Zhiqing Liu, Jianping Zheng, S. Zhu, L. J. Wu, H. B. Liu, R. Baldini Ferroli, X. F. Wang, X. H. Liu, Q. M. Ma, Nasser Kalantar-Nayestanaki, J. H. Zou, Y. J. Mo, Z. J. Xiao, M.G. Alekseev, B. Kopf, S. S. Sun, B. T. Tsednee, Yi Jin, J. W. Li, C. Morales Morales, P. L. Chen, Yue Pan, T. Johansson, J. F. Chang, W. S. Cheng, Yao Zhang, G. Li, S. X. Du, Y. H. Xie, J. Pellegrino, K. L. He, J. P. Dai, A. Mustafa, X. Y. Niu, Krisztian Peters, M. Z. Wang, Q. Gao, Y. N. Gao, Y. G. Gao, J. Chai, G. X. Sun, J. V. Bennett, Li Yan, Z. G. Wang, Y. F. Wang, S. W. Han, J. F. Qiu, A. N. Zhu, M. Papenbrock, L. Fava, H. M. Liu, Tao Zhang, Y. J. Xiao, J. F. Hu, J. S. Huang, M. Maggiora, H. Y. Zhang, C. X. Liu, Ling Zhao, V. Prasad, M. Kuemmel, Matthew Glenn Kurth, C. D. Fu, Y. Zhang, O. B. Kolcu, M. Destefanis, C. Q. Feng, X. R. Chen, Jimin Zhao, Z. Y. Deng, M. Ripka, P. L. Li, T. Hussain, F. Nerling, X. Y. Ma, R. E. Mitchell, W. X. Gong, X. Cai, Z. Jiao, D. H. Zhang, Y. Yuan, Y. S. Zhu, Ke Liu, G. F. Chen, Yu Zhang, Y. Ban, L. Lavezzi, X. N. Li, Feng Yan, Haiping Peng, X. Tang, Z. X. Meng, X. A. Xiong, Lei Zhao, Z. L. Hou, X. Q. Hao, C. F. Redmer, I. R. Boyko, Xiaozhong Huang, G. F. Cao, X D Shi, Fang Liu, Yang Zhang, T. Ma, M. Bertani, C. H. Li, J. Q. Zhang, X. H. Sun, A. A. Zafar, P. Weidenkaff, J. Libby, M. Rolo, J. Y. Zhang, M. Richter, Yaquan Fang, M. Greco, Shou-hua Zhu, Z. Haddadi, Liqing Xu, L. Yang, X. Y. Shen, Jun-Yi Zhang, I. Tapan, U. Wiedner, I. Denysenko, X. L. Wang, Ke Wang, Xu Shan, Y. H. Yan, Z. Ning, J. W. Zhao, F. Cossio, P. Larin, B. Y. Zhang, Y. J. Mao, Andrzej Kupsc, H. X. Yang, I. Garzia, G. S. Huang, K. H. Rashid, C. Z. Yuan, R. Poling, P. F. Duan, F. H. Heinsius, Y. T. Tan, M. L. Chen, A. Calcaterra, Z. G. Zhao, S. Fegan, W. Gradl, Y. C. Zhu, L. Z. Liao, K. Schoenning, Q. Y. Li, B. S. Zou, Fenfen An, Dan Wang, D. W. Bennett, Zujian Wang, K. Goetzen, S. P. Wen, Y. K. Heng, D. Y. Wang, B. L. Wang, Y. T. Liang, S. J. Chen, S. Ahmed, Y. X. Yang, T. C. Zhao, B. Garillon, X. S. Qin, Yu Bai, X. R. Zhou, H. H. Zhang, T. Held, Z. J. Sun, S. Maldaner, G. Y. Tang, T. Khan, K. J. Li, J. C. Li, G. R. Liao, J. Zhuang, Cheng Li, Kang Li, Huihui Liu, M. X. Luo, D. V. Dedovich, Xu Zhou, J. G. Messchendorp, C. Sowa, Y. B. Zhao, Jie Zhao, D. X. Lin, Alexey Zhemchugov, H. M. Hu, W. Shan, J. Dong, Qiunan Xu, F. H. Liu, Nicolas Berger, A. Q. Guo, Z. Y. Peng, J. W. Zhang, S. Nisar, C. J. Tang, M. H. Gu, R. Kiuchi, F. Feldbauer, W. M. Song, Y. Hu, Y. P. Lu, H. Y. Sheng, D. Xiao, Z. L. Huang, Q. Zhao, Z. H. Qin, C. X. Yu, Feng Liu, M. Ablikim, Y. Z. Sun, X. Y. Jiang, B. Zheng, R. G. Ping, X. N. Ma, B. Wang, I. K. Keshk, X. K. Chu, M. Fritsch, M. Kavatsyuk, C. X. Lin, Alexander Leon Gilman, Gang Zhao, B. X. Zhang, H. R. Qi, R. Farinelli, Lingxuan Zhang, H. L. Ma, D. M. Li, H. Muramatsu, M. Pelizaeus, Y. P. Guo, Serkant Ali Cetin, S. Qian, Q. An, Jialun Ping, K. Zhang, X. Y. Zhang, J. B. Liu, Y. J. Sun, Yifan Yang, E. Boger, X. L. Ji, J. B. Jiao, Z. Y. Zhang, Y. G. Xie, Z. L. Dou, Xiao-Rui Lyu, M. H. Ye, L. Y. Dong, I. B. Nikolaev, J. H. Yin, M. Shao, Y. T. Gu, E. Fioravanti, A. Sarantsev, D. H. Wei, P. R. Li, J. S. Lange, X. H. Mo, L. S. Wang, L. L. Wang, H. Cai, Huanhuan Liu, G. Felici, H. J. Li, Q. L. Xiu, Zongyuan Wang, Q. Ouyang, S. S. Fang, and Y. B. Liu

Subjects

Physics, 010308 nuclear & particles physics, Electron–positron annihilation, Form factor (quantum field theory), Electron, 01 natural sciences, law.invention, Nuclear physics, Cross section (physics), Positron, Pair production, law, 0103 physical sciences, High Energy Physics::Experiment, Nuclear Experiment, 010306 general physics, Collider, Line (formation)

Abstract

The cross section of the process e+e-→K+K- is measured at a number of center-of-mass energies s from 2.00 to 3.08 GeV with the BESIII detector at the Beijing Electron Positron Collider (BEPCII). The results provide the best precision achieved so far. A resonant structure around 2.2 GeV is observed in the cross section line shape. A Breit-Wigner fit yields a mass of M=2239.2±7.1±11.3 MeV/c2 and a width of Γ=139.8±12.3±20.6 MeV, where the first uncertainties are statistical and the second ones are systematic. In addition, the timelike electromagnetic form factor of the kaon is determined at the individual center-of-mass energy points.

Published

2019

40. Observation of e+e−→ηY(2175) at center-of-mass energies above 3.7 GeV

Author

D. J. Ambrose, F. E. Maas, T. Hu, X. L. Li, O. Bakina, M. Albrecht, Z. G. Wang, H. Y. Zhang, P. L. Wang, W. D. Li, P. X. Shen, Z. Wu, Z. A. Liu, G. F. Chen, L. W. Jiang, V. Prasad, Y. H. Guan, Y. Ban, P. Weidenkaff, S. Ahmed, F. A. Harris, P. Musiol, Xiaocong Ai, J. Y. Zhang, C. Schnier, Y. Q. Wang, Zhiqing Zhang, S. P. Wen, X. S. Qin, X. R. Zhou, X. T. Huang, G. Rong, Z. P. Zhang, H. Leithoff, Y. X. Yang, E. H. Thorndike, X. H. Liu, L. Q. Qin, Kang Li, S. B. Liu, Y. Nefedov, Y. K. Heng, J. P. Dai, X. C. Chen, X. N. Ma, Cheng Li, S. Q. Zhang, A. Hafner, Q. Zhao, Y. Z. Sun, X. K. Chu, F. De Mori, R. Kliemt, L. H. Wu, H. B. Li, B. Kloss, C. L. Luo, B. Wang, M. Fritsch, M. Savrie, M. M. Ma, C. C. Zhang, H. Liang, B. Zhong, L. B. Guo, Bibo Ke, W. B. Yan, J. Chai, X. Y. Zhou, G. X. Sun, J. V. Bennett, Li Yan, Z. Jiao, D. H. Zhang, M. G. Zhao, Lei Li, Ke Wang, M. Kavatsyuk, F. Li, Jie Yu, R. P. Guo, F. C. Ma, Peilian Liu, Lingxuan Zhang, Gang Zhao, Y. N. Zhang, Y. H. Zheng, S. Pacetti, Cong-Feng Qiao, O. Albayrak, C. Leng, Q. P. Ji, I. Tapan, Y. H. Yan, X. F. Wang, J. W. Zhao, J. M. Bian, R. Poling, S. J. Zhao, B. J. Liu, N. Yu. Muchnoi, T. J. Min, K. J. Zhu, Y. F. Wang, Ke Li, X. S. Kang, T. Ma, Y. H. Zhang, B. X. Zhang, G. Cibinetto, P. F. Duan, F. H. Heinsius, Gianfranco Morello, Jiaxi Liu, Q. M. Ma, Y. C. Zhu, A. A. Zafar, Q. J. Xu, X. Q. Hao, J. F. Qiu, M. Papenbrock, Fenfen An, Xichao Ruan, S. L. Olsen, B. L. Wang, Yang Li, Fang Liu, U. Wiedner, I. Denysenko, Z. Y. Wang, J. C. Chen, Xuanhong Lou, Nasser Kalantar-Nayestanaki, J. Q. Zhang, T. Holtmann, T. C. Zhao, H. R. Qi, L. Fava, C. Morales Morales, Yue Pan, M. H. Gu, F. Nerling, B. Y. Zhang, X. H. Mo, L. S. Wang, M. H. Ye, K. H. Rashid, J. Y. Liu, P. Larin, H. Y. Sheng, C. X. Yu, X. Y. Niu, Y. Yuan, Y. S. Zhu, G. F. Xu, S. Jin, Yu Zhang, J. Z. Bai, H. Xiao, T. Held, A. Calcaterra, Z. G. Zhao, Q. A. Malik, G. Mezzadri, Y. T. Liang, S. J. Chen, Y. P. Guo, Serkant Ali Cetin, B. Zheng, R. G. Ping, R. Baldini Ferroli, L. L. Wang, H. Cai, Huanhuan Liu, M. Y. Dong, T. Hussain, X. Y. Ma, W. X. Gong, Yang Zhang, M. N. Achasov, L. P. Zhou, Y. M. Ma, S. Z. Chen, G. S. Huang, F. Feldbauer, Z. L. Huang, Feng Liu, Q. Gao, Y. N. Gao, Dan Wang, J. H. Zou, S. S. Sun, Q. Liu, Tristan Weber, M. Ablikim, J. B. Jiao, Manuel Lara, Jie Zhao, D. X. Lin, Z. P. Mao, J. Fang, Tao Li, Alexey Zhemchugov, H. M. Hu, Krisztian Peters, M. Z. Wang, F. H. Liu, Nicolas Berger, X. Y. Jiang, X. Y. Song, L. D. Liu, L. L. Ma, G. Felici, H. H. Zhang, J. Z. Fan, J. W. Zhang, X. N. Li, X. P. Xu, X. B. Ji, M. Tiemens, R. E. Mitchell, L. Y. Dong, L. Gong, Ch. Rosner, L. G. Xia, A. Amoroso, J. J. Xu, C. H. Li, X. H. Sun, Haiping Peng, Tao Luo, G. R. Liao, Z. J. Sun, H. Loehner, P. Patteri, Yunlong Zhang, Z. Gao, W. J. Zheng, A. Dbeyssi, Jun-Yi Zhang, J. S. Huang, Yao Wang, M. Kornicer, C. X. Liu, L. Zotti, D. W. Bennett, Zujian Wang, S. L. Niu, B. X. Yu, Zhi Zeng, R. Farinelli, Yao Zhang, D. Bettoni, A. Julin, X. Q. Li, G. Li, Y. B. Zhao, J. F. Sun, Y. F. Long, W. Shan, F. Y. Li, J. Dong, M. Bertani, S. Qian, J. L. Zhang, I. B. Nikolaev, Z. Haddadi, S. Nisar, Q. An, Jialun Ping, C. J. Tang, Y. Hu, Y. P. Lu, K. Goetzen, K. Zhang, H. S. Chen, S. Marcello, H. L. Ma, D. M. Li, Alperen Yuncu, Jin Li, Y. Zeng, Yaquan Fang, M. Greco, D. Xiao, Shou-hua Zhu, C. D. Fu, C. Q. Feng, J. C. Li, X. R. Chen, X. Y. Zhang, L. Yang, Zhe Sun, J. H. Yin, M. Shao, Y. T. Gu, H. L. Dai, Z. Y. Deng, M. Ripka, H. Muramatsu, Y. X. Xia, J. Zhuang, J. B. Liu, Jianping Zheng, M. X. Luo, M. Pelizaeus, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, Y. J. Sun, E. Boger, D. V. Dedovich, S. Zhu, X. K. Zhou, E. Fioravanti, K. Schoenning, Q. Y. Li, B. S. Zou, K. Y. Liu, X. L. Kang, A. Sarantsev, D. H. Wei, P. R. Li, J. S. Lange, S. X. Du, Q. W. Zhao, Z. B. Li, W. Ikegami Andersson, H. J. Li, Z. Ning, W. Gradl, J. J. Zhang, M. Destefanis, P. Kiese, D. Y. Wang, C. Hu, X. Tang, Q. L. Xiu, M. Qi, H. J. Yang, R. A. Briere, X. S. Jiang, X. L. Luo, Zhiqing Liu, X. L. Gao, C. Dong, S. Sosio, T. Johansson, J. F. Chang, J. Min, Joachim Pettersson, Y. N. Guo, H. B. Liu, W. P. Wang, O. B. Kolcu, B. Kopf, O. Cakir, K. L. He, X. Cai, F. Bianchi, S. W. Han, Jimin Zhao, C. F. Redmer, D. Y. Liu, W. G. Li, A. G. Denig, S. Spataro, Y. Y. Liu, Zongyuan Wang, H. M. Liu, G. A. Chelkov, G. F. Cao, Y. J. Mao, Xiao-Rui Lyu, Q. Ouyang, H. X. Yang, I. Garzia, G. S. Varner, Y. H. Xie, Huihui Liu, M. Maggiora, Ling Zhao, S. S. Fang, J. P. Liu, J. G. Messchendorp, Lei Zhao, Qiunan Xu, Y. B. Liu, Z. L. Hou, A. Q. Guo, X. L. Ji, W. M. Song, Z. Y. Zhang, C. Z. Yuan, Z. H. Qin, Y. G. Xie, Z. L. Dou, L. J. Wu, Y. J. Mo, I. R. Boyko, Liqing Xu, X. Y. Shen, Y. Ding, W. Kühn, Z. Y. You, Z. A. Zhu, C. P. Shen, I. Uman, Z. J. Xiao, Xiaozhong Huang, Andrzej Kupsc, M. L. Chen, Magnus Wolke, Y. F. Liang, D. P. Jin, N. Qin, H. J. Lu, and J. G. Lu

Subjects

Physics, Nuclear physics, 010308 nuclear & particles physics, Electron–positron annihilation, 0103 physical sciences, Center of mass, 010306 general physics, 01 natural sciences, Storage ring

Abstract

The state Y(2175) is observed in the process e+e-→ηY(2175) with a statistical significance larger than 10 standard deviations using the data collected with the BESIII detector operating at the BEPCII storage ring at center-of-mass energies between 3.7 and 4.6 GeV. This is the first observation of the Y(2175) in this process. The mass and width of the Y(2175) are determined to be (2135±8±9) MeV/c2 and (104±24±12) MeV, respectively, and the production cross section (σ) of e+e-→ηY(2175)→ηϕf0(980)→ηϕπ+π- is at the several hundred femtobarn level. No significant signal for the process e+e-→η′Y(2175) is observed and the upper limit on σ(e+e-→η′Y(2175))/σ(e+e-→ηY(2175)) is estimated to be 0.43 at the 90% confidence level. We also search for ψ(3686)→ηY(2175). No significant signal is observed, indicating a strong suppression relative to the corresponding J/ψ decay, in violation of the “12% rule”.

Published

2019

41. Observation of OZI-suppressed decays χcJ→ωϕ

Author

P. L. Wang, X. L. Luo, R. Farinelli, M. Kuemmel, Matthew Glenn Kurth, K. Begzsuren, H. L. Ma, D. M. Li, W. P. Wang, T. Khan, F. Bianchi, X. L. Gao, H. Muramatsu, H. B. Li, W. S. Cheng, Yao Zhang, G. Li, M. Kuessner, H. Liang, Dan Wang, M. M. Ma, M. Pelizaeus, C. D. Fu, C. Q. Feng, X. R. Chen, C. Dong, R. Kliemt, C. L. Luo, Z. Y. Deng, M. Ripka, M. Y. Dong, A. Mangoni, Q. P. Ji, X. Xia, A. Guskov, Jie Yu, Q. Zhou, T. J. Min, K. J. Zhu, D. Y. Liu, G. Cibinetto, Xiaozhong Huang, Xingguo Li, F. Feldbauer, S. Ahmed, Y. X. Yang, S. Sosio, C. C. Zhang, B. Zhong, L. B. Guo, Z. L. Huang, Feng Liu, Kang Li, Y. Ding, J. Z. Bai, M. G. Zhao, Y. H. Yang, R. P. Guo, J. Zhu, Lei Li, G. A. Chelkov, A. Q. Guo, Z. Y. Peng, C. W. Wang, F. De Mori, Zongyuan Wang, X. P. Xu, X. B. Ji, M. Tiemens, J. Chai, M.G. Alekseev, P. Patteri, J. Min, Zhiqing Liu, T. Y. Qi, A. N. Zhu, Tao Zhang, G. X. Sun, J. V. Bennett, Li Yan, M. Ablikim, X. Y. Jiang, H. B. Liu, Joachim Pettersson, J. H. Zou, G. R. Liao, T. Ma, T. Johansson, J. F. Chang, Meng Wang, Muhammad Irshad, Z. Jiao, D. H. Zhang, Q. Ouyang, Xiao-Rui Lyu, Andrzej Kupsc, Ke Wang, W. M. Song, Ke Liu, B. Q. Wang, Y. Z. Sun, Y. F. Wang, O. B. Kolcu, Y. H. Xie, J. Pellegrino, X. Cai, J. F. Sun, Xu Shan, L. Lavezzi, S. B. Liu, S. S. Sun, X. Y. Zhou, S. S. Fang, I. K. Keshk, J. B. Jiao, M. L. Chen, Z. G. Wang, H. Y. Zhang, S. Marcello, J. C. Li, Z. H. Qin, Y. X. Xia, Y. Nefedov, Jun-Yi Zhang, Y. B. Liu, M. Maggiora, Ling Zhao, B. J. Liu, C. X. Lin, Alexander Leon Gilman, B. Kopf, J. Libby, Gang Zhao, Y. Zeng, X D Shi, Zhe Sun, S. Lusso, R. Poling, M. Richter, F. A. Harris, Z. P. Zhang, J. Zhuang, G. F. Chen, P. F. Duan, F. H. Heinsius, X. K. Zhou, Z. Ning, Y. J. Mao, H. X. Yang, Yaquan Fang, Shou-hua Zhu, X. Tang, Huanhuan Liu, K. L. He, I. Garzia, M. X. Luo, J. Y. Zhang, Fenfen An, G. Felici, D. W. Bennett, Zujian Wang, H. Leithoff, F. Li, S. W. Han, Lei Zhao, Z. L. Hou, I. Tapan, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, Y. H. Yan, D. V. Dedovich, R. E. Mitchell, J. J. Song, W. Kühn, J. Y. Liu, B. L. Wang, F. C. Ma, L. Sun, M. Rolo, Xu Zhou, B. Garillon, Huihui Liu, X. F. Wang, Z. Y. You, Z. A. Zhu, J. W. Zhao, T. C. Zhao, Y. K. Heng, Jimin Zhao, J. G. Messchendorp, Q. Gao, Y. N. Gao, K. Schoenning, Q. Y. Li, B. S. Zou, X. L. Ji, C. Sowa, Y. B. Zhao, Bibo Ke, Q. M. Ma, A. Mustafa, W. Shan, S. J. Zhao, P. L. Li, Qiunan Xu, Y. Zhang, J. F. Qiu, M. Papenbrock, Feng Yan, Y. C. Zhu, Y. G. Gao, J. Dong, W. B. Yan, H. J. Li, L. Koch, A. Khoukaz, W. G. Li, L. Fava, Z. Y. Zhang, Q. A. Malik, G. Mezzadri, W. C. Yan, F. Cossio, X. Q. Hao, Q. J. Xu, Q. L. Xiu, A. G. Denig, C. F. Redmer, Y. K. Sun, Qiang Zhao, X. Y. Niu, C. P. Shen, Xiaoyu Zhou, F. Nerling, Magnus Wolke, X. Q. He, S. Nisar, C. J. Tang, Y. Hu, S. Nakhoul, J. C. Chen, Xuanhong Lou, S. Pacetti, S. Spataro, S. Leiber, Y. P. Lu, Nasser Kalantar-Nayestanaki, R. Baldini Ferroli, Y. Yuan, Y. S. Zhu, A. Calcaterra, Z. G. Zhao, L. J. Wu, S. Fegan, L. Z. Liao, Yang Zhang, C. Z. Yuan, Y. F. Liang, L. M. Gu, M. N. Achasov, M. Bertani, Z. Haddadi, D. P. Jin, C. Morales Morales, Yu Zhang, Yue Pan, Y. J. Mo, L. P. Zhou, Y. G. Xie, Yu Bai, Y. M. Ma, T. Held, L. Yang, J. Q. Zhang, P. Larin, H. M. Liu, Krisztian Peters, D. Xiao, J. F. Hu, Z. L. Dou, Mario Greco, Z. P. Mao, H. H. Zhang, Z. J. Sun, M. Z. Wang, Ke Li, G. F. Cao, Q. Liu, Tristan Weber, J. Fang, Tao Li, Yunlong Zhang, H. L. Liu, Dayong Wang, N. Qin, H. J. Lu, J. G. Lu, S. Maldaner, D. Bettoni, X. N. Li, L. L. Ma, L. Gong, Fang Liu, Ch. Rosner, Haiping Peng, X. N. Ma, G. Y. Tang, F. E. Maas, T. Hu, Y. T. Tan, Tao Luo, J. L. Zhang, L. G. Xia, U. Wiedner, I. Denysenko, I. R. Boyko, I. Uman, A. Amoroso, Jianping Zheng, W. Gradl, Jie Zhao, D. X. Lin, Liqing Xu, X. Y. Shen, B. X. Yu, M. Albrecht, Alexey Zhemchugov, H. M. Hu, D. Y. Wang, S. Zhu, O. Bakina, B. Y. Zhang, A. Dbeyssi, Shulei Zhang, M. Qi, H. J. Yang, F. H. Liu, Nicolas Berger, W. D. Li, B. T. Tsednee, Z. J. Xiao, F. Y. Li, H. S. Chen, Alperen Yuncu, J. W. Zhang, P. X. Shen, P. L. Chen, M. Kornicer, Angelo Rivetti, S. X. Du, Z. Wu, A. Julin, H. L. Dai, K. Y. Liu, Zhiqing Zhang, M. Destefanis, M. Fritsch, M. Kavatsyuk, Y. H. Zheng, Cong-Feng Qiao, B. X. Zhang, N. Yu. Muchnoi, X. S. Kang, Y. H. Zhang, M. H. Ye, S. L. Olsen, H. R. Qi, L. Y. Dong, Z. Y. Wang, Y. P. Guo, Serkant Ali Cetin, W. J. Zheng, S. Qian, X. H. Liu, Z. A. Liu, Q. An, Jialun Ping, K. Zhang, X. Y. Zhang, J. P. Dai, J. B. Liu, Y. J. Sun, Yifan Yang, E. Boger, V. Prasad, Y. Ban, P. Weidenkaff, I. B. Nikolaev, S. P. Wen, J. H. Yin, X. S. Qin, X. R. Zhou, M. Shao, Y. T. Gu, Cheng Li, E. Fioravanti, K. Goetzen, A. Sarantsev, D. H. Wei, P. R. Li, J. S. Lange, M. H. Gu, R. Kiuchi, H. Y. Sheng, C. X. Yu, B. Zheng, R. G. Ping, X. K. Chu, X. H. Mo, L. S. Wang, Lingxuan Zhang, L. L. Wang, H. Cai, G. F. Xu, S. Jin, X. Y. Song, L. D. Liu, J. J. Xu, Z. Q. Yang, J. S. Huang, C. X. Liu, L. H. Wu, M. Savrie, Yi Jin, J. W. Li, Y. J. Xiao, Z. Gao, S. L. Niu, X. Q. Li, Y. F. Long, Z. X. Meng, X. A. Xiong, A. A. Zafar, S. Q. Qu, Z. B. Li, W. Ikegami Andersson, P. Kiese, K. H. Rashid, R. A. Briere, G. S. Huang, X. S. Jiang, R. X. Yang, A. Pitka, O. Cakir, Y. T. Liang, T. Hussain, X. Y. Ma, W. X. Gong, S. J. Chen, C. H. Li, X. H. Sun, K. J. Li, X. T. Huang, and G. Rong

Subjects

Physics, Particle physics, Meson, 010308 nuclear & particles physics, Electron–positron annihilation, 0103 physical sciences, 010306 general physics, Branching (polymer chemistry), 01 natural sciences, Omega

Abstract

Decays χcJ(J=0,1,2)→ωϕ are studied using (448.1±2.9)×106ψ(3686) events collected with the BESIII detector in 2009 and 2012. In addition to the previously established χc0→ωϕ, the first observation of χc1→ωϕ is reported in this paper. The measured product branching fractions are B(ψ(3686)→γχc0)×B(χc0→ωϕ)=(13.83±0.70±1.01)×10-6 and B(ψ(3686)→γχc1)×B(χc1→ωϕ)=(2.67±0.31±0.27)×10-6, and the absolute branching fractions are B(χc0→ωϕ)=(13.84±0.70±1.08)×10-5 and B(χc1→ωϕ)=(2.80±0.32±0.30)×10-5. We also find strong evidence for χc2→ωϕ with a statistical significance of 4.8σ, and the corresponding product and absolute branching fractions are measured to be B(ψ(3686)→γχc2)×B(χc2→ωϕ)=(0.91±0.23±0.12)×10-6 and B(χc2→ωϕ)=(1.00±0.25±0.14)×10-5. Here, the first errors are statistical and the second ones systematic.

Published

2019

42. Measurement of B(J/ψ→η′e+e−) and search for a dark photon

Author

H. J. Lu, J. G. Lu, M. Bertani, Z. Haddadi, F. E. Maas, T. Hu, L. Yang, X. L. Li, O. Bakina, D. Y. Liu, J. B. Jiao, P. X. Shen, Z. Wu, M. M. Ma, Zhiqing Zhang, Yunlong Zhang, H. L. Liu, L. D. Liu, Y. T. Tan, J. Libby, W. Gradl, D. Bettoni, Xiaozhong Huang, X. N. Ma, J. Q. Zhang, D. Y. Wang, Yaquan Fang, M. Greco, Shou-hua Zhu, Y. H. Xie, J. L. Zhang, J. Pellegrino, J. J. Xu, J. Chai, B. Wang, X. Q. Hao, F. De Mori, C. Schnier, Y. Q. Wang, M. Qi, H. J. Yang, G. X. Sun, J. V. Bennett, Li Yan, Jianping Zheng, S. Zhu, M. Maggiora, Ling Zhao, M. Richter, R. Farinelli, Z. Jiao, D. H. Zhang, J. Z. Bai, L. J. Wu, Z. Ning, M. Fritsch, Z. Gao, H. B. Li, Huanhuan Liu, X. T. Huang, J. S. Huang, Lei Zhao, G. Rong, X. H. Liu, G. R. Liao, M. Albrecht, M. Kavatsyuk, S. X. Du, K. Y. Liu, C. X. Liu, Z. L. Hou, H. L. Ma, C. L. Luo, Y. J. Mo, Q. Zhou, S. L. Niu, Andrzej Kupsc, S. B. Liu, K. Schoenning, Q. Y. Li, B. S. Zou, Z. X. Meng, X. A. Xiong, X. Q. Li, A. A. Zafar, W. D. Li, D. M. Li, B. T. Tsednee, M. Destefanis, J. P. Dai, Y. F. Long, G. Felici, H. Muramatsu, X. Y. Zhou, Jun-Yi Zhang, P. Larin, C. C. Zhang, B. Zhong, X. K. Zhou, H. R. Qi, Q. A. Malik, G. Mezzadri, W. C. Yan, B. X. Zhang, Y. Nefedov, X. H. Mo, L. S. Wang, M. L. Chen, M. H. Ye, Lei Li, M.G. Alekseev, M. Pelizaeus, X. Q. He, M. G. Zhao, Y. H. Yang, R. P. Guo, A. N. Zhu, M. H. Gu, Tao Zhang, M. Kuemmel, Matthew Glenn Kurth, D. W. Bennett, J. Zhu, K. H. Rashid, Y. P. Guo, B. X. Yu, Zhi Zeng, T. Khan, S. Ahmed, Y. X. Yang, Kang Li, C. Z. Yuan, X. L. Gao, M. N. Achasov, L. P. Zhou, L. L. Wang, Zujian Wang, Serkant Ali Cetin, Q. P. Ji, T. Ma, I. Tapan, Zhiqing Liu, Y. T. Liang, Y. M. Ma, H. Y. Sheng, J. Min, I. R. Boyko, X. F. Wang, H. Cai, G. Y. Tang, S. J. Chen, G. F. Xu, H. B. Liu, X. P. Xu, X. B. Ji, M. Tiemens, F. Feldbauer, Z. G. Wang, Y. H. Yan, Z. P. Mao, Xu Shan, J. W. Zhao, Q. Zhao, H. Y. Zhang, Liqing Xu, X. Y. Shen, Y. C. Zhu, J. C. Li, S. Jin, C. Sowa, Y. B. Zhao, K. J. Li, C. Dong, T. Johansson, J. F. Chang, Q. M. Ma, G. S. Huang, B. Kopf, S. Qian, Q. An, Jialun Ping, A. Mustafa, F. Y. Li, Z. L. Huang, C. X. Yu, H. S. Chen, Alperen Yuncu, P. Patteri, Feng Liu, Manuel Lara, Y. Z. Sun, X. Y. Jiang, Jin Li, Z. B. Li, K. L. He, J. Fang, W. Shan, Y. Ding, K. Zhang, W. Ikegami Andersson, X. Y. Zhang, G. F. Chen, J. Dong, S. Sosio, J. Zhuang, Y. F. Wang, Dan Wang, M. X. Luo, O. B. Kolcu, S. W. Han, X. Y. Niu, H. L. Dai, Jie Zhao, D. X. Lin, D. V. Dedovich, M. Z. Wang, Alexey Zhemchugov, H. M. Hu, Jimin Zhao, C. X. Lin, B. Zheng, R. G. Ping, T. Held, P. L. Li, L. Y. Dong, B. J. Liu, J. F. Sun, J. Y. Zhang, J. B. Liu, S. Nisar, C. J. Tang, Y. Hu, Y. P. Lu, X. Cai, L. Lavezzi, Y. Yuan, Y. S. Zhu, Yu Zhang, H. J. Li, C. F. Redmer, Alexander Leon Gilman, M. Kuessner, Gang Zhao, T. Hussain, W. Kühn, Y. J. Sun, Yifan Yang, E. Boger, X. Y. Song, X. Y. Ma, S. Marcello, Y. Zeng, Zhe Sun, S. Lusso, Q. Liu, Tristan Weber, W. X. Gong, L. H. Wu, T. Holtmann, Magnus Wolke, Y. H. Zheng, Y. F. Liang, Ch. Rosner, J. Y. Liu, Cong-Feng Qiao, R. Kliemt, Z. A. Liu, V. Prasad, A. Mangoni, A. Guskov, Jie Yu, Z. Y. You, Z. A. Zhu, Ke Wang, D. Xiao, M. Savrie, Yi Jin, D. P. Jin, Y. K. Heng, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, L. L. Ma, L. Gong, G. A. Chelkov, K. Goetzen, J. W. Li, Y. J. Xiao, Y. Ban, P. Weidenkaff, N. Yu. Muchnoi, Q. Gao, F. H. Liu, Nicolas Berger, Joachim Pettersson, Y. N. Gao, J. W. Zhang, X. S. Kang, Dayong Wang, N. Qin, J. J. Song, L. Sun, R. Poling, C. P. Shen, S. J. Zhao, C. H. Li, X. H. Sun, L. G. Xia, A. Amoroso, Q. L. Xiu, Y. Zhang, H. Liang, Feng Yan, Y. H. Zhang, K. J. Zhu, P. F. Duan, F. H. Heinsius, P. Kiese, P. L. Wang, I. B. Nikolaev, I. Uman, Fenfen An, A. Dbeyssi, S. P. Wen, R. A. Briere, G. Cibinetto, S. L. Olsen, B. L. Wang, J. H. Yin, X. Tang, M. Kornicer, X. S. Jiang, Q. J. Xu, T. C. Zhao, M. Shao, Y. T. Gu, X. L. Luo, X. S. Qin, X. R. Zhou, Z. Y. Wang, J. C. Chen, M. Ablikim, A. Julin, Z. J. Xiao, A. Calcaterra, Z. G. Zhao, Xuanhong Lou, S. Fegan, P. L. Chen, A. Pitka, Nasser Kalantar-Nayestanaki, O. Cakir, L. Koch, A. Khoukaz, L. Z. Liao, M. Rolo, Yao Zhang, G. Li, E. Fioravanti, Cheng Li, C. Morales Morales, Yue Pan, T. Y. Qi, R. Baldini Ferroli, Yu Bai, K. Begzsuren, H. H. Zhang, C. D. Fu, Z. J. Sun, C. Q. Feng, Krisztian Peters, X. R. Chen, Y. X. Xia, A. Sarantsev, D. H. Wei, P. R. Li, J. S. Lange, X. N. Li, Z. Y. Deng, M. Ripka, W. P. Wang, X. K. Chu, Haiping Peng, F. Bianchi, F. Cossio, Ke Liu, Y. G. Gao, Lingxuan Zhang, Zongyuan Wang, Q. Ouyang, S. S. Fang, Y. B. Liu, Xiao-Rui Lyu, G. S. Varner, X. L. Ji, F. Li, F. C. Ma, Z. Y. Zhang, Y. G. Xie, J. F. Qiu, M. Papenbrock, L. Fava, Z. L. Dou, F. Nerling, Yang Zhang, Meng Wang, Muhammad Irshad, F. A. Harris, Z. P. Zhang, H. Leithoff, M. Y. Dong, J. H. Zou, S. S. Sun, R. E. Mitchell, Fang Liu, U. Wiedner, I. Denysenko, A. Q. Guo, Z. Y. Peng, B. Y. Zhang, W. M. Song, Bibo Ke, W. B. Yan, S. Pacetti, Z. H. Qin, Ke Li, W. G. Li, A. G. Denig, Y. K. Sun, S. Spataro, H. M. Liu, J. F. Hu, G. F. Cao, X D Shi, Y. J. Mao, H. X. Yang, I. Garzia, B. Garillon, Huihui Liu, J. G. Messchendorp, and Qiunan Xu

Subjects

Physics, Range (particle radiation), Particle physics, Photon, 010308 nuclear & particles physics, Branching fraction, Electron–positron annihilation, 0103 physical sciences, Dalitz plot, 010306 general physics, 01 natural sciences, Dark photon, Vector boson

Abstract

Using a data sample of (1310.6±7.0)×106 J/ψ decay events collected with the BESIII detector at BEPCII, we study the electromagnetic Dalitz decay J/ψ→η′e+e- with two dominant η′ decay modes, η′→γπ+π- and η′→π+π-η. The branching fraction is determined to be B(J/ψ→η′e+e-)=(6.59±0.07±0.17)×10-5, which improves in precision by a factor of 2 over the previous BESIII measurement. A search for the dark photon (γ′) is performed via J/ψ→η′γ′, γ′→e+e-. Excluding the ω and ϕ mass regions, no significant signal is observed in the mass range from 0.1 to 2.1 GeV/c2. We set upper limits at the 90% confidence level on B(J/ψ→η′γ′)×B(γ′→e+e-), B(J/ψ→η′γ′) and the mixing strength as a function of dark photon mass. This is among the first searches for dark photons in charmonium decays.

Published

2019

43. Study of the decay D0→K¯0π−e+νe

Author

F. C. Ma, X. K. Chu, X D Shi, Y. J. Mao, H. X. Yang, I. Garzia, J. F. Qiu, M. Papenbrock, L. Fava, Lingxuan Zhang, B. Garillon, Huihui Liu, Xiao-Rui Lyu, Y. H. Xie, F. Nerling, Ke Wang, J. G. Messchendorp, Yang Zhang, P. W. Luo, J. Pellegrino, A. Q. Guo, Z. Y. Peng, C. W. Wang, W. M. Song, W. G. Li, A. G. Denig, M. Maggiora, Ling Zhao, Y. K. Sun, X. L. Gao, Z. H. Qin, Xiaoyu Zhou, R. Poling, P. F. Duan, F. H. Heinsius, L. J. Wu, S. Spataro, F. De Mori, Fenfen An, Y. J. Mo, B. L. Wang, H. M. Liu, L. H. Wu, Lei Zhao, T. C. Zhao, C. Dong, S. Sosio, J. F. Hu, M. Savrie, Z. L. Hou, H. J. Lu, J. G. Lu, G. F. Cao, F. F. Sui, M. H. Gu, R. Kiuchi, M. Bertani, Yi Jin, J. W. Li, T. Y. Qi, S. J. Zhao, B. J. Liu, H. Y. Sheng, P. L. Wang, Joachim Pettersson, F. E. Maas, T. Hu, C. X. Yu, X. Y. Zhou, X. P. Xu, X. B. Ji, X. L. Ji, Y. J. Xiao, M. Tiemens, Z. X. Meng, X. A. Xiong, Meng Wang, Muhammad Irshad, Q. P. Ji, Y. X. Xia, X. L. Li, C. Z. Yuan, I. R. Boyko, B. Zheng, X. Tang, P. Patteri, A. Calcaterra, Z. G. Zhao, O. Bakina, R. G. Ping, Z. Y. Zhang, A. A. Zafar, Z. Haddadi, L. Yang, Q. J. Xu, X. K. Zhou, Z. A. Liu, L. Z. Liao, S. B. Liu, M. M. Ma, Liqing Xu, X. Y. Shen, F. A. Harris, W. L. Chang, J. C. Chen, Xuanhong Lou, L. Koch, A. Khoukaz, V. Prasad, Y. G. Xie, P. X. Shen, K. H. Rashid, Z. Wu, Y. Ding, M. Albrecht, Y. Nefedov, S. Leiber, Nasser Kalantar-Nayestanaki, Y. Ban, P. Weidenkaff, Yu Bai, M. Rolo, Y. H. Zheng, Cong-Feng Qiao, Z. P. Zhang, H. Leithoff, Fang Liu, H. H. Zhang, X. F. Wang, W. S. Cheng, Yao Zhang, G. Li, N. Yu. Muchnoi, R. Baldini Ferroli, C. Morales Morales, S. P. Wen, Yue Pan, Z. J. Sun, I. B. Nikolaev, Y. G. Gao, Z. L. Dou, M. Kuessner, G. Y. Tang, U. Wiedner, Z. G. Wang, I. Denysenko, H. Y. Zhang, W. Kühn, Z. Y. You, X. S. Kang, W. D. Li, B. T. Tsednee, Krisztian Peters, S. Malde, M. Z. Wang, Z. A. Zhu, Y. T. Liang, S. J. Chen, Jie Zhao, D. X. Lin, C. D. Fu, C. Q. Feng, X. R. Chen, X. S. Qin, X. R. Zhou, Cheng Li, Alexey Zhemchugov, H. M. Hu, X. L. Luo, K. Goetzen, Q. M. Ma, A. Mustafa, B. Y. Zhang, J. H. Yin, X. N. Li, Z. Y. Deng, M. Ripka, Haiping Peng, K. J. Li, G. F. Chen, S. Maldaner, G. A. Chelkov, H. B. Li, C. L. Luo, X. Xia, Q. Zhou, Zhiqing Zhang, M. Kuemmel, Matthew Glenn Kurth, F. Cossio, Tao Luo, H. R. Qi, Y. H. Zhang, C. P. Shen, S. L. Olsen, Z. Y. Wang, F. H. Liu, Nicolas Berger, J. W. Zhang, C. C. Zhang, B. Zhong, L. B. Guo, K. J. Zhu, Y. H. Yan, Y. T. Tan, R. Kliemt, J. Y. Zhang, W. Gradl, X. Y. Niu, X. N. Ma, Y. Yuan, Y. S. Zhu, A. Mangoni, A. Guskov, M. Y. Dong, J. W. Zhao, Lei Li, M.G. Alekseev, B. X. Yu, M. Shao, Y. T. Gu, Y. P. Guo, Jie Yu, A. N. Zhu, K. Begzsuren, Tao Zhang, X. Q. Hao, W. Imoehl, S. Nakhoul, D. Y. Wang, M. Qi, Y. C. Zhu, J. Chai, Shulei Zhang, F. Y. Li, Yu Zhang, J. H. Zou, T. J. Min, W. P. Wang, J. Q. Zhang, H. S. Chen, Alperen Yuncu, P. Larin, F. Bianchi, S. S. Sun, H. J. Yang, L. D. Liu, X. H. Liu, Yunlong Zhang, H. L. Liu, Xu Shan, H. L. Dai, Y. K. Heng, G. X. Sun, J. V. Bennett, G. Cibinetto, Serkant Ali Cetin, D. Bettoni, J. C. Li, Y. Q. Wang, Q. Liu, Tristan Weber, J. Zhuang, J. P. Dai, R. E. Mitchell, Li Yan, T. Held, J. J. Xu, Z. Q. Yang, J. L. Zhang, X. T. Huang, G. Rong, M. X. Luo, A. Sarantsev, B. Wang, D. H. Wei, P. R. Li, Bibo Ke, M. Fritsch, W. B. Yan, J. S. Lange, H. L. Jiang, D. V. Dedovich, Xu Zhou, L. L. Ma, S. Pacetti, Jianping Zheng, M. H. Ye, S. Zhu, L. Gong, M. Kavatsyuk, D. Y. Liu, M. G. Zhao, Y. H. Yang, R. P. Guo, J. Zhu, Ke Li, J. S. Huang, J. B. Jiao, Z. Jiao, D. H. Zhang, L. G. Xia, A. Amoroso, C. X. Liu, G. S. Huang, J. Min, S. X. Du, K. Y. Liu, L. Y. Dong, Huanhuan Liu, A. Dbeyssi, C. Sowa, H. B. Liu, M. Destefanis, G. Felici, B. Kopf, Y. B. Zhao, K. L. He, B. X. Zhang, Angelo Rivetti, Dan Wang, S. W. Han, Magnus Wolke, G. F. Xu, T. Khan, S. Jin, W. J. Zheng, Jimin Zhao, P. L. Li, J. F. Sun, Y. F. Liang, W. Shan, C. F. Redmer, D. P. Jin, S. Marcello, X. Y. Song, Y. Zeng, Zhe Sun, J. Dong, S. Lusso, S. Qian, Q. An, Jialun Ping, H. J. Li, N. Qin, F. Feldbauer, K. Zhang, X. Y. Zhang, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, Q. L. Xiu, Z. L. Huang, Feng Liu, J. J. Song, L. Sun, J. B. Liu, I. Uman, X. H. Mo, L. S. Wang, Y. J. Sun, Yifan Yang, E. Boger, M. Ablikim, X. Y. Jiang, S. Nisar, Y. P. Lu, Zongyuan Wang, L. L. Wang, H. Cai, C. J. Tang, Y. Hu, S. L. Yang, G. R. Liao, Q. Ouyang, S. S. Fang, Z. J. Xiao, Y. B. Liu, P. L. Chen, D. Xiao, Jun-Yi Zhang, D. W. Bennett, Zujian Wang, Zhiqing Liu, T. Johansson, J. F. Chang, Y. F. Wang, O. B. Kolcu, X. Cai, L. Lavezzi, M. Richter, Z. Ning, J. Libby, Yaquan Fang, M. Greco, Shou-hua Zhu, K. Schoenning, Q. Y. Li, B. S. Zou, H. Liang, Ke Liu, Q. A. Malik, G. Mezzadri, W. C. Yan, L. M. Gu, M. N. Achasov, L. P. Zhou, Y. M. Ma, Z. P. Mao, J. Fang, Tao Li, P. Kiese, Ch. Rosner, R. A. Briere, X. S. Jiang, J. Y. Liu, R. X. Yang, H. H. Wang, A. Pitka, Q. Gao, Y. N. Gao, Y. Zhang, T. Hussain, X. Y. Ma, W. X. Gong, Feng Yan, C. H. Li, X. H. Sun, Z. Gao, S. L. Niu, X. Q. Li, Y. F. Long, R. Farinelli, H. L. Ma, S. Q. Qu, Z. B. Li, W. Ikegami Andersson, D. M. Li, H. Muramatsu, M. Pelizaeus, S. Ahmed, Y. X. Yang, Kang Li, Q. Zhao, Y. Z. Sun, I. K. Keshk, C. X. Lin, Alexander Leon Gilman, Gang Zhao, Xiaozhong Huang, Andrzej Kupsc, M. L. Chen, and F. Li

Subjects

Physics, Particle physics, Annihilation, 010308 nuclear & particles physics, Branching fraction, Hadron, 01 natural sciences, law.invention, law, 0103 physical sciences, Pi, 010306 general physics, Collider, Bar (unit)

Abstract

We report a study of the decay D0→K¯0π-e+νe based on a sample of 2.93 fb-1 e+e- annihilation data collected at the center-of-mass energy of 3.773 GeV with the BESIII detector at the BEPCII collider. The total branching fraction is determined to be B(D0→K¯0π-e+νe)=(1.434±0.029(stat.)±0.032(syst.))%, which is the most precise to date. According to a detailed analysis of the involved dynamics, we find this decay is dominated with the K*(892)- contribution and present an improved measurement of its branching fraction to be B(D0→K*(892)-e+νe)=(2.033±0.046(stat.)±0.047(syst.))%. We further access their hadronic form-factor ratios for the first time as rV=V(0)/A1(0)=1.46±0.07(stat.)±0.02(syst.) and r2=A2(0)/A1(0)=0.67±0.06(stat.)±0.01(syst.). In addition, we observe a significant K¯0π- S-wave component accounting for (5.51±0.97(stat.)±0.62(syst.))% of the total decay rate.

Published

2019

44. Search for a strangeonium-like structure Zs decaying into ϕπ and a measurement of the cross section e+e−→ϕππ

Author

J. M. Bian, S. J. Zhao, X. N. Ma, Y. H. Xie, J. Pellegrino, B. J. Liu, M. Y. Dong, M. Maggiora, Ling Zhao, J. F. Qiu, M. Papenbrock, S. B. Liu, Y. X. Xia, A. Calcaterra, Z. G. Zhao, S. Fegan, L. Fava, Q. J. Xu, Y. Nefedov, C. Leng, J. H. Zou, X. K. Zhou, F. Nerling, Lei Zhao, Z. L. Hou, M. Fritsch, Yu Bai, J. C. Chen, H. H. Zhang, S. S. Sun, M. Kavatsyuk, Xuanhong Lou, Nasser Kalantar-Nayestanaki, H. J. Lu, J. G. Lu, Yang Zhang, Xiao-Rui Lyu, F. E. Maas, T. Hu, Z. J. Sun, O. Bakina, F. De Mori, P. X. Shen, J. Q. Zhang, Z. Wu, C. Morales Morales, Yue Pan, Zhiqing Zhang, Y. G. Gao, S. Qian, Q. An, Jialun Ping, K. Zhang, B. X. Zhang, J. Z. Bai, X. Y. Zhang, X. Q. Hao, I. Tapan, X. Y. Zhou, R. E. Mitchell, G. S. Varner, C. Z. Yuan, M. Kuhlmann, Y. H. Yan, I. B. Nikolaev, J. H. Yin, M. Shao, Y. T. Gu, P. Larin, H. B. Li, P. L. Wang, J. W. Zhao, K. Goetzen, Meng Wang, J. B. Liu, X. P. Xu, X. B. Ji, M. Tiemens, C. L. Luo, Fang Liu, Y. F. Wang, Y. J. Sun, E. Boger, E. Fioravanti, X. F. Wang, P. Patteri, Yao Wang, Y. C. Zhu, M. Bertani, Q. M. Ma, C. C. Zhang, Y. P. Lu, Z. Haddadi, U. Wiedner, I. Denysenko, R. Kliemt, B. Zhong, L. Yang, M. G. Zhao, Y. H. Yang, R. P. Guo, J. Zhu, A. Mustafa, Lei Li, L. D. Liu, X. L. Ji, X. L. Kang, A. Sarantsev, D. H. Wei, P. R. Li, J. S. Lange, F. A. Harris, X. Y. Niu, T. Hussain, X. Y. Ma, B. Y. Zhang, Jie Yu, M. H. Gu, H. Y. Sheng, J. J. Xu, T. Khan, H. Leithoff, G. Y. Tang, M. Kuessner, Z. G. Wang, H. Xiao, Y. Yuan, Y. S. Zhu, L. H. Wu, W. X. Gong, H. Y. Zhang, T. J. Min, K. J. Zhu, T. Ma, Bibo Ke, Manuel Lara, Jie Zhao, D. X. Lin, G. F. Chen, Yu Zhang, Q. Liu, Alexey Zhemchugov, H. M. Hu, Z. Y. Zhang, G. R. Liao, B. Q. Wang, J. B. Jiao, C. X. Yu, Tristan Weber, J. Y. Zhang, J. C. Li, J. S. Huang, C. X. Liu, G. Cibinetto, X. H. Mo, L. S. Wang, F. H. Liu, Nicolas Berger, T. Held, G. A. Chelkov, W. B. Yan, J. W. Zhang, Yao Zhang, S. Pacetti, G. Li, Mario Greco, G. F. Xu, F. Feldbauer, Z. L. Huang, Feng Liu, Zhiqing Liu, M. H. Ye, M. Savrie, Yi Jin, C. H. Li, X. H. Sun, L. L. Ma, J. Zhuang, L. Gong, M. X. Luo, Y. H. Zheng, Cong-Feng Qiao, Y. G. Xie, L. G. Xia, Y. J. Xiao, S. Jin, M. Kuemmel, M. Ablikim, Y. K. Heng, C. D. Fu, C. Q. Feng, X. R. Chen, T. Johansson, J. F. Chang, B. Zheng, R. G. Ping, A. Amoroso, D. V. Dedovich, P. Kiese, Ke Li, X. K. Chu, Z. X. Meng, X. Y. Jiang, Z. Y. Deng, M. Ripka, Z. L. Dou, N. Yu. Muchnoi, W. Gradl, X. S. Kang, O. B. Kolcu, X. Cai, X. A. Xiong, L. L. Wang, H. Cai, R. A. Briere, A. Dbeyssi, X. Y. Song, A. A. Zafar, Xingguo Li, G. S. Huang, L. Lavezzi, M. Kornicer, X. S. Jiang, A. Julin, Y. H. Zhang, Huanhuan Liu, S. L. Olsen, M. Richter, Z. Ning, G. Felici, K. H. Rashid, M. Albrecht, A. Pitka, O. Cakir, H. R. Qi, D. Y. Wang, Y. T. Liang, W. D. Li, Dan Wang, S. J. Chen, J. F. Sun, Z. Gao, B. T. Tsednee, Y. P. Guo, M. Qi, K. J. Li, S. L. Niu, Peilian Liu, H. J. Li, X. Q. Li, Y. F. Long, Lingxuan Zhang, H. J. Yang, Serkant Ali Cetin, L. Y. Dong, Q. L. Xiu, Z. Y. Wang, S. Marcello, Y. Zeng, Zhe Sun, X. L. Luo, W. J. Zheng, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, C. Schnier, Y. Q. Wang, J. J. Song, L. Sun, K. Y. Liu, Z. A. Liu, Z. B. Li, W. Ikegami Andersson, X. T. Huang, W. P. Wang, F. Bianchi, G. Rong, Jun-Yi Zhang, V. Prasad, D. Y. Liu, Y. Ban, P. Weidenkaff, Zongyuan Wang, S. P. Wen, Z. P. Zhang, X. H. Liu, X. S. Qin, X. R. Zhou, Cheng Li, Q. Ouyang, S. S. Fang, Y. B. Liu, J. P. Dai, D. W. Bennett, Zujian Wang, A. Q. Guo, W. M. Song, C. Sowa, Y. B. Zhao, W. Shan, J. Dong, Z. H. Qin, W. G. Li, A. G. Denig, Y. K. Sun, Qiang Zhao, S. Nisar, J. Min, C. J. Tang, Y. Hu, S. Spataro, H. B. Liu, H. M. Liu, G. F. Cao, B. Kopf, Y. J. Mao, H. X. Yang, D. Xiao, I. Garzia, K. L. He, S. W. Han, M. M. Ma, Huihui Liu, J. P. Liu, Jimin Zhao, J. G. Messchendorp, P. L. Li, Qiunan Xu, C. F. Redmer, J. Chai, G. X. Sun, J. V. Bennett, Li Yan, Z. Jiao, D. H. Zhang, Y. Ding, W. Kühn, Z. Y. You, Z. A. Zhu, C. P. Shen, L. J. Wu, Y. J. Mo, Q. P. Ji, I. R. Boyko, Liqing Xu, X. Y. Shen, X. L. Gao, C. Dong, S. Sosio, Joachim Pettersson, Yunlong Zhang, D. Bettoni, J. L. Zhang, Jianping Zheng, S. Zhu, S. X. Du, M. Destefanis, B. X. Yu, Zhi Zeng, X. Tang, M. Rolo, F. Y. Li, H. S. Chen, Alperen Yuncu, Jin Li, H. L. Dai, Ke Wang, R. Poling, P. F. Duan, F. H. Heinsius, Fenfen An, B. L. Wang, T. C. Zhao, Magnus Wolke, Y. F. Liang, L. Koch, A. Khoukaz, R. Baldini Ferroli, Krisztian Peters, M. Z. Wang, D. P. Jin, X. N. Li, Haiping Peng, Dayong Wang, N. Qin, Q. A. Malik, G. Mezzadri, W. C. Yan, X. Q. He, M. N. Achasov, L. P. Zhou, Y. M. Ma, Z. P. Mao, J. Fang, Ch. Rosner, Xiaozhong Huang, H. Liang, Andrzej Kupsc, M. L. Chen, I. Uman, Z. J. Xiao, P. L. Chen, Ke Liu, Yaquan Fang, Shou-hua Zhu, K. Schoenning, Q. Y. Li, B. S. Zou, T. Holtmann, J. Y. Liu, Q. Gao, Y. N. Gao, Y. X. Zhou, S. Ahmed, Y. X. Yang, Kang Li, S. Q. Zhang, Y. Z. Sun, Gang Zhao, R. Farinelli, H. L. Ma, D. M. Li, H. Muramatsu, M. Pelizaeus, F. Li, and F. C. Ma

Subjects

Physics, Particle physics, 010308 nuclear & particles physics, Astrophysics::High Energy Astrophysical Phenomena, Electron–positron annihilation, Structure (category theory), Dalitz plot, 01 natural sciences, Luminosity, Cross section (physics), 0103 physical sciences, Mass spectrum, Pi, High Energy Physics::Experiment, Nuclear Experiment, 010306 general physics, Energy (signal processing)

Abstract

Using a data sample of e(+)e(-) collision data corresponding to an integrated luminosity of 108 pb(-1) collected with the BESIII detector at a center-of-mass energy of 2.125 GeV, we study the proce ...

Published

2019

45. Study of the D0→K−μ+νμ Dynamics and Test of Lepton Flavor Universality with D0→K−ℓ+νℓ Decays

Author

Jin Li, J. Y. Liu, X. Y. Jiang, M. M. Ma, Q. Gao, Y. N. Gao, M. G. Zhao, Y. H. Yang, Y. Zhang, R. P. Guo, J. Zhu, Kai Liu, S. B. Liu, L. Zhang, J. Chai, G. X. Sun, J. V. Bennett, Zhiqing Liu, Y. Nefedov, Z. Jiao, Fu-Hu Liu, D. H. Zhang, S. Ahmed, Y. X. Yang, Kang Li, Q. Zhao, Y. Z. Sun, M. Y. Dong, Xiang Zhou, L. J. Wu, C. X. Lin, Gang Zhao, T. Johansson, J. F. Chang, Y. F. Wang, Cui Li, Jun-Yi Zhang, Y. P. Guo, Z. P. Zhang, S. J. Zhao, H. B. Liu, P. Kiese, S. L. Olsen, R. A. Briere, J. Libby, J. H. Zou, R. Farinelli, P. R. Li, X. S. Jiang, P. L. Chen, O. B. Kolcu, L. Koch, X. Cai, L. Lavezzi, H. L. Ma, D. W. Bennett, Zujian Wang, S. S. Sun, D. M. Li, Y. Bai, Y. J. Mo, X. S. Qin, Q. J. Xu, R. E. Mitchell, M. Pelizaeus, O. Cakir, Yaquan Fang, C. Sowa, Y. B. Zhao, X. Q. Hao, Z. Gao, J. Q. Zhang, S. L. Niu, Fang Liu, J. C. Chen, Xuanhong Lou, J. Dong, F. De Mori, M. Richter, F. Y. Li, Y. Q. Wang, Z. Ning, X. Q. Li, H. J. Lu, Nasser Kalantar-Nayestanaki, I. Denysenko, W. C. Yan, J. G. Lu, S. Nisar, C. J. Tang, Y. Hu, Y. F. Long, M. Greco, Z. X. Meng, X. A. Xiong, Y. P. Lu, A. Pitka, B. Y. Zhang, A. Khoukaz, A. Calcaterra, Z. G. Zhao, S. Fegan, D. Xiao, L. Z. Liao, Zongyuan Wang, I. Tapan, F. E. Maas, X. Y. Zhou, Y. H. Yan, Y. H. Zheng, Cong-Feng Qiao, Magnus Wolke, C. Morales Morales, Yue Pan, Z. G. Wang, T. Hu, H. H. Zhang, J. Min, K. Y. Liu, I. B. Nikolaev, X. L. Ji, G. Y. Tang, X. Tang, Bibo Ke, W. B. Yan, A. Q. Guo, Z. Y. Peng, Z. B. Li, K. Schoenning, Q. Y. Li, Y. F. Liang, B. S. Zou, D. P. Jin, H. Y. Zhang, J. W. Zhao, G. F. Chen, N. Yu. Muchnoi, R. Baldini Ferroli, Y. C. Zhu, M. N. Achasov, Z. J. Sun, W. Ikegami Andersson, S. Pacetti, J. Y. Zhang, A. A. Zafar, O. Bakina, X. S. Kang, Niklaus Berger, A. Yuncu, M. Rolo, Dayong Wang, B. Kopf, N. Qin, L. Yan, Q. Ouyang, M. Kuessner, Jie Zhao, Q. P. Ji, Ke Li, D. X. Lin, Alexey Zhemchugov, H. M. Hu, Y. H. Zhang, J. H. Yin, X. F. Wang, S. S. Fang, Y. K. Heng, J. J. Xu, M. Shao, Y. T. Gu, Michael Papenbrock, F. Yan, E. Boger, J. C. Li, T. Held, J. Zhuang, M. Kuemmel, Matthew Glenn Kurth, T. Hussain, Liqing Xu, Y. B. Liu, K. L. He, Z. Q. Yang, P. X. Shen, M. X. Luo, Z. Wu, Q. M. Ma, Z. Y. Wang, A. Mustafa, D. V. Dedovich, F. Cossio, H. Liang, K. J. Zhu, Xu Zhou, X. Y. Ma, Y. G. Xie, X. Y. Shen, P. L. Wang, M. Albrecht, Zhiqing Zhang, Z. J. Xiao, J. W. Zhang, W. X. Gong, G. A. Chelkov, M. Z. Wang, X. Y. Niu, X. N. Li, Jimin Zhao, W. Shan, Y. Yuan, Y. S. Zhu, Yu Zhang, S. X. Du, M. Alekseev, J. S. Huang, X. L. Luo, K. Begzsuren, E. Fioravanti, C. X. Liu, Z. H. Qin, Z. L. Dou, W. P. Wang, W. D. Li, B. T. Tsednee, Haiping Peng, Y. Ding, H. B. Li, A. G. Denig, C. L. Luo, F. Bianchi, Yunlong Zhang, H. L. Liu, D. Bettoni, P. L. Li, Y. H. Xie, M. Qi, J. Pellegrino, Q. Liu, W. G. Li, K. H. Rashid, Y. K. Sun, I. Uman, P. Larin, Xiaozhong Huang, Q. Zhou, R. Poling, Jianping Zheng, S. Zhu, B. J. Liu, Y. T. Liang, Xiaoyu Zhou, Xiao-Rui Lyu, C. C. Zhang, L. L. Ma, L. Gong, H. J. Yang, D. Y. Liu, A. Sarantsev, S. Spataro, B. Zhong, X. P. Xu, M. Maggiora, Ling Zhao, T. Khan, D. H. Wei, J. S. Lange, W. M. Song, X. H. Sun, S. F. Zhang, W. Kühn, M. Fritsch, L. G. Xia, A. Amoroso, Z. Y. You, Y. G. Gao, G. S. Huang, S. J. Chen, Huanhuan Liu, Andrzej Kupsc, Lei Li, M. H. Ye, T. Y. Qi, Lei Zhao, Z. A. Zhu, Z. L. Hou, H. Muramatsu, A. N. Zhu, Ulrich Wiedner, G. S. Varner, A. Dbeyssi, Ke Liu, H. M. Liu, G. Felici, M. Destefanis, F. Feldbauer, B. X. Yu, Zhi Zeng, X. L. Gao, Tao Zhang, Z. L. Huang, M. Kornicer, G. F. Xu, Feng Liu, L. D. Liu, T. Weber, K. J. Li, M. L. Chen, L. Y. Dong, Dan Wang, Q. A. Malik, G. Mezzadri, Y. X. Xia, S. H. Zhu, G. F. Cao, X. K. Zhou, X. Q. He, Angelo Rivetti, T. Ma, A. Julin, X D Shi, S. Jin, M. Ablikim, Xu Shan, Y. J. Mao, S. Han, H. X. Yang, I. Garzia, L. P. Zhou, C. P. Shen, H. J. Li, Dong E. Liu, Y. M. Ma, C. Dong, W. J. Zheng, S. Sosio, Z. P. Mao, Krisztian Peters, H. S. Chen, J. Fang, F. Nerling, Ch. Rosner, Q. L. Xiu, C. Z. Yuan, H. L. Dai, Igor Boyko, B. Garillon, X. N. Ma, Joachim Pettersson, Huihui Liu, M. Bertani, X. Y. Song, L. H. Wu, Ke Wang, J. G. Messchendorp, M. Savrie, K. Goetzen, B. Wang, Z. Haddadi, Yi Jin, L. Yang, J. P. Dai, Qiunan Xu, P. F. Duan, Fenfen An, X. H. Mo, L. S. Wang, B. L. Wang, J. W. Li, M. Kavatsyuk, T. C. Zhao, G. R. Liao, Y. J. Xiao, B. X. Zhang, Y. T. Tan, W. Gradl, M. Ripka, J. F. Sun, C. F. Redmer, Bingxuan Liu, W. S. Cheng, D. Y. Wang, Yao Zhang, G. Li, A. Gilman, C. D. Fu, C. Schnier, C. Q. Feng, X. R. Chen, S. Marcello, Y. Zeng, X. T. Huang, G. Rong, S. Lusso, Y. B. Chen, Xiaofeng Zhu, J. Z. Zhang, Z. Y. Deng, Xingguo Li, R. Kliemt, A. Mangoni, A. Guskov, Jie Yu, J. J. Song, L. Sun, G. Cibinetto, F. Li, F. C. Ma, J. Z. Bai, J. F. Qiu, L. Fava, X. B. Ji, M. Tiemens, Yang Zhang, P. Patteri, Meng Wang, Muhammad Irshad, F. A. Harris, H. Leithoff, J. B. Jiao, L. L. Wang, H. Cai, Z. T. Sun, Z. A. Liu, V. Prasad, Y. Ban, P. Weidenkaff, F. H. Heinsius, S. P. Wen, X. R. Zhou, Cheng Li, X. K. Chu, J. F. Hu, S. Qian, Zhiyong Zhang, Q. An, Jialun Ping, K. Zhang, X. Y. Zhang, J. L. Zhang, M. H. Gu, R. Kiuchi, M. Lara, J. B. Liu, H. Y. Sheng, Y. J. Sun, Yifan Yang, C. X. Yu, B. Zheng, R. G. Ping, X. Liu, H. R. Qi, Serkant Ali Cetin, and T. Holtmann

Subjects

Quantum chromodynamics, Physics, Particle physics, Annihilation, Branching fraction, Electron–positron annihilation, Lattice field theory, General Physics and Astronomy, Elementary particle, 01 natural sciences, Lattice (order), 0103 physical sciences, 010306 general physics, Lepton

Abstract

Using e^{+}e^{-} annihilation data of 2.93 fb^{-1} collected at center-of-mass energy sqrt[s]=3.773 GeV with the BESIII detector, we measure the absolute branching fraction of D^{0}→K^{-}μ^{+}ν_{μ} with significantly improved precision: B_{D^{0}→K^{-}μ^{+}ν_{μ}}=(3.413±0.019_{stat}±0.035_{syst})%. Combining with our previous measurement of B_{D^{0}→K^{-}e^{+}ν_{e}}, the ratio of the two branching fractions is determined to be B_{D^{0}→K^{-}μ^{+}ν_{μ}}/B_{D^{0}→K^{-}e^{+}ν_{e}}=0.974±0.007_{stat}±0.012_{syst}, which agrees with the theoretical expectation of lepton flavor universality within the uncertainty. A study of the ratio of the two branching fractions in different four-momentum transfer regions is also performed, and no evidence for lepton flavor universality violation is found with current statistics. Taking inputs from global fit in the standard model and lattice quantum chromodynamics separately, we determine f_{+}^{K}(0)=0.7327±0.0039_{stat}±0.0030_{syst} and |V_{cs}|=0.955±0.005_{stat}±0.004_{syst}±0.024_{LQCD}.

Published

2019

46. Measurements of e+e−→KS0K±π∓π0 and KS0K±π∓η at center-of-mass energies from 3.90 to 4.60 GeV

Author

X. H. Liu, J. P. Dai, X. H. Mo, L. S. Wang, M. H. Ye, H. R. Qi, X. Tang, L. L. Wang, H. Cai, M. Richter, Z. Ning, Z. X. Meng, X. A. Xiong, Y. P. Guo, Y. Ding, H. B. Li, A. A. Zafar, Y. Fu, B. J. Liu, Serkant Ali Cetin, Y. H. Yan, J. W. Zhao, Y. C. Zhu, M. Rolo, X. Q. Hao, T. Held, Mario Greco, M. M. Ma, Y. H. Zheng, Cong-Feng Qiao, J. J. Xu, L. Koch, A. Khoukaz, X. K. Zhou, S. Nakhoul, W. Kühn, D. Y. Liu, Z. Q. Yang, K. H. Rashid, J. B. Jiao, Z. Y. You, Z. A. Zhu, N. Yu. Muchnoi, M. Albrecht, C. L. Luo, X. Xia, Q. Zhou, X. S. Kang, R. Baldini Ferroli, W. D. Li, B. T. Tsednee, F. Cossio, Y. T. Liang, P. Larin, Y. H. Zhang, L. Y. Dong, K. J. Zhu, N. Hsken, J. S. Huang, F. Li, S. J. Chen, Xiao-Rui Lyu, C. X. Liu, Z. Gao, S. L. Niu, J. Chai, Krisztian Peters, H. J. Lu, S. L. Olsen, A. Pitka, G. X. Sun, J. V. Bennett, Li Yan, T. Khan, J. F. Sun, M. Z. Wang, M. Qi, W. J. Zheng, C. C. Zhang, B. Zhong, L. B. Guo, F. C. Ma, H. Liang, J. G. Lu, C. P. Shen, H. J. Yang, Z. Jiao, Z. Y. Wang, D. H. Zhang, X. Q. Li, Q. P. Ji, Z. A. Liu, V. Prasad, T. Y. Qi, Y. F. Long, I. B. Nikolaev, X. N. Li, L. J. Wu, P. L. Wang, Y. J. Mo, Lei Li, S. Marcello, A. N. Zhu, J. H. Yin, F. E. Maas, Y. X. Xia, M. Shao, Y. T. Gu, Haiping Peng, X. L. Gao, J. F. Qiu, Magnus Wolke, M. Papenbrock, Y. F. Liang, T. Hu, Y. Zeng, Ke Wang, Y. Ban, Zhe Sun, S. Lusso, P. Weidenkaff, D. P. Jin, Jun-Yi Zhang, J. D. Lu, F. Feldbauer, G. F. Xu, Tao Zhang, Z. P. Zhang, L. Fava, X. L. Luo, F. Nerling, Z. L. Huang, O. Bakina, S. Jin, X. T. Huang, D. W. Bennett, Zujian Wang, J. Y. Liu, Xu Shan, A. Sarantsev, C. Dong, S. P. Wen, S. Sosio, Y. B. Chen, S. Qian, Q. An, Jialun Ping, Feng Liu, G. Rong, K. Zhang, X. Y. Zhang, I. R. Boyko, Yang Zhang, Ke Liu, N. Qin, D. H. Wei, P. R. Li, J. S. Lange, R. Poling, P. F. Duan, F. H. Heinsius, X. S. Qin, Y. G. Gao, P. X. Shen, X. L. Ji, Xiaofeng Zhu, J. Z. Zhang, M. Ablikim, Xiaozhong Huang, Liqing Xu, J. C. Li, Zhiqing Liu, K. Begzsuren, Q. A. Malik, G. Mezzadri, Z. Wu, J. B. Liu, C. Sowa, Y. B. Zhao, T. Johansson, J. F. Chang, X. R. Zhou, W. C. Yan, Cheng Li, W. Shan, X. Y. Shen, J. Zhuang, Joachim Pettersson, W. P. Wang, J. Dong, M. X. Luo, G. Y. Tang, Y. J. Sun, Yifan Yang, S. Q. Qu, Z. B. Li, W. Ikegami Andersson, Y. F. Wang, Fenfen An, Zhiqing Zhang, D. V. Dedovich, X. Y. Song, Z. Y. Zhang, O. B. Kolcu, M. Bertani, Z. Haddadi, L. Yang, Andrzej Kupsc, B. L. Wang, F. Bianchi, T. C. Zhao, L. M. Gu, J. J. Song, L. Sun, Qiang Zhao, S. Nisar, Q. Gao, Y. N. Gao, Xu Zhou, L. H. Wu, M. N. Achasov, L. P. Zhou, Y. P. Lu, Y. Zhang, Meng Wang, Muhammad Irshad, X. Cai, L. Lavezzi, C. J. Tang, Y. Hu, Y. M. Ma, X. Y. Jiang, M. L. Chen, Feng Yan, Z. P. Mao, Jie Zhao, D. X. Lin, Yunlong Zhang, H. L. Liu, Alexey Zhemchugov, H. M. Hu, Tao Luo, Y. G. Xie, F. H. Liu, D. Xiao, K. Goetzen, M. Savrie, M. Kuemmel, Matthew Glenn Kurth, J. Z. Fan, D. Bettoni, T. Hussain, F. A. Harris, A. Calcaterra, Z. G. Zhao, S. Fegan, W. L. Chang, B. X. Yu, Z. L. Dou, J. Fang, Tao Li, J. L. Zhang, I. Uman, L. Z. Liao, Jianping Zheng, J. Q. Zhang, Y. T. Tan, X. Y. Ma, Nicolas Berger, W. Gradl, Yi Jin, H. Leithoff, Yu Bai, H. H. Zhang, W. X. Gong, J. W. Zhang, Z. J. Sun, S. Zhu, J. W. Li, R. Farinelli, X. P. Xu, X. B. Ji, Lingxuan Zhang, Shulei Zhang, D. Y. Wang, F. Y. Li, H. S. Chen, S. Maldaner, Alperen Yuncu, Z. J. Xiao, S. X. Du, P. L. Chen, Ch. Rosner, M. Tiemens, J. Min, H. B. Liu, Y. J. Xiao, H. L. Dai, H. L. Ma, X. N. Ma, J. Libby, P. Patteri, B. Kopf, K. Y. Liu, C. H. Li, Zongyuan Wang, X. H. Sun, M. Destefanis, D. M. Li, H. Muramatsu, M. H. Gu, R. Kiuchi, K. L. He, Yaquan Fang, M. Fritsch, S. W. Han, P. Kiese, Shou-hua Zhu, H. Y. Sheng, M. Kavatsyuk, C. X. Yu, R. A. Briere, M. Pelizaeus, Jimin Zhao, Fang Liu, S. Ahmed, Y. X. Yang, P. L. Li, U. Wiedner, I. Denysenko, B. X. Zhang, Q. Ouyang, G. S. Huang, B. Zheng, R. G. Ping, X. S. Jiang, R. Kliemt, C. F. Redmer, Dan Wang, S. S. Fang, A. Mangoni, A. Guskov, Y. B. Liu, K. Schoenning, Q. Y. Li, B. S. Zou, R. X. Yang, B. Y. Zhang, Huanhuan Liu, Jie Yu, S. L. Yang, G. Felici, Y. Z. Sun, T. J. Min, G. R. Liao, G. Cibinetto, B. Q. Wang, I. K. Keshk, M. Alekseev, W. S. Cheng, Yao Zhang, G. Li, M. Y. Dong, C. X. Lin, Alexander Leon Gilman, H. J. Li, Q. L. Xiu, C. D. Fu, F. De Mori, C. Q. Feng, A. Q. Guo, C. W. Wang, Z. Y. Deng, M. Ripka, X. Y. Zhou, M. Rump, Gang Zhao, Xingguo Li, X. F. Wang, W. M. Song, Q. M. Ma, J. H. Zou, A. Mustafa, S. S. Sun, Y. Yuan, Y. S. Zhu, Yu Zhang, R. E. Mitchell, Z. H. Qin, Q. Liu, Tristan Weber, X D Shi, Bibo Ke, L. L. Ma, W. B. Yan, Y. J. Mao, S. B. Liu, L. Gong, Y. Nefedov, H. X. Yang, I. Garzia, L. G. Xia, A. Amoroso, S. Pacetti, M. G. Zhao, Y. H. Yang, X. X. Ma, R. P. Guo, J. Zhu, A. Dbeyssi, Ke Li, M. Kornicer, Angelo Rivetti, A. Julin, Z. G. Wang, B. Garillon, Huihui Liu, H. Y. Zhang, G. F. Chen, J. G. Messchendorp, J. Y. Zhang, Y. K. Heng, S. J. Zhao, W. G. Li, A. G. Denig, Y. K. Sun, Q. J. Xu, Xiaoyu Zhou, J. C. Chen, Xuanhong Lou, S. Leiber, Nasser Kalantar-Nayestanaki, S. Spataro, C. Morales Morales, Yue Pan, H. M. Liu, J. F. Hu, G. F. Cao, Y. H. Xie, J. Pellegrino, M. Maggiora, Ling Zhao, Lei Zhao, Z. L. Hou, C. Z. Yuan, M. Kuessner, and G. A. Chelkov

Subjects

Physics, Nuclear physics, Annihilation, 010308 nuclear & particles physics, 0103 physical sciences, Detector, Pi, Resonance, Center of mass, 010306 general physics, 01 natural sciences, Measure (mathematics)

Abstract

Using 5.2 fb-1 e+e- annihilation data samples collected with the BESIII detector, we measure the cross sections of e+e-→KS0K±π∓π0 and KS0K±π∓η at center-of-mass energies from 3.90 to 4.60 GeV. In addition, we search for the charmoniumlike resonance Y(4260) decays into KS0K±π∓π0 and KS0K±π∓η, and Zc0,±(3900) decays into KS0K±π∓,0 and KS0K±η. Corresponding upper limits are provided since no clear signal is observed.

Published

2019

47. Intrinsic electric quadrupole moment of the Kπ=8− isomeric state in Hf178

Author

S. Zhu

Subjects

Physics, 010308 nuclear & particles physics, 0103 physical sciences, Quadrupole, Center (category theory), Gammasphere, State (functional analysis), Atomic physics, 010306 general physics, Hpge detector, 01 natural sciences, Effective nuclear charge

Abstract

The lifetime of the ${9}^{\ensuremath{-}}$ state in the rotational band based on the 4.0 s, ${K}^{\ensuremath{\pi}}={8}^{\ensuremath{-}}$, isomeric state ($^{178}\mathrm{Hf}^{{m}_{1}}$) from the decay of the 31-yr isomer ($^{178}\mathrm{Hf}^{{m}_{2}}$) was determined to be 99(2) ps by means of the fast-timing technique using two ${\mathrm{LaBr}}_{3}$(Ce) scintillators. The $\ensuremath{\delta}(E2/M1)$ mixing ratios of the $\mathrm{\ensuremath{\Delta}}I=1\phantom{\rule{4pt}{0ex}}\ensuremath{\gamma}$ rays depopulating levels in this band were deduced from $\ensuremath{\gamma}\text{\ensuremath{-}}\ensuremath{\gamma}$ angular correlations by using a $^{178}\mathrm{Hf}^{{m}_{2}}$ radioactive source located at the center of the Gammasphere HPGe detector array. The new results, together with previous spectroscopic information, provide a different way to extract the intrinsic quadrupole moment of ${Q}_{0}=6.45(14)\phantom{\rule{4pt}{0ex}}e\text{b}$ for the $^{178}\mathrm{Hf}^{{m}_{1}}$ band. A possible explanation for the reduction of the $^{178}\mathrm{Hf}^{{m}_{1}}$ nuclear charge radius is presented.

Published

2020

48. Impact of reduced anthropogenic emissions during COVID-19 on air quality in India

Author

M. Zhang, A. Katiyar, S. Zhu, J. Shen, M. Xia, J. Ma, S. H. Kota, P. Wang, and H. Zhang

Subjects

Pollutant, Atmospheric Science, Ozone, 010504 meteorology & atmospheric sciences, Air pollution, 010501 environmental sciences, medicine.disease_cause, 01 natural sciences, lcsh:QC1-999, lcsh:Chemistry, chemistry.chemical_compound, Nitrate, chemistry, lcsh:QD1-999, Environmental chemistry, medicine, Environmental science, Ammonium, Sulfate, Air quality index, lcsh:Physics, 0105 earth and related environmental sciences, CMAQ

Abstract

To mitigate the impacts of the pandemic of coronavirus disease 2019 (COVID-19), the Indian government implemented lockdown measures on 24 March 2020, which prohibited unnecessary anthropogenic activities, thus leading to a significant reduction in emissions. To investigate the impacts of this lockdown measure on air quality in India, we used the Community Multi-Scale Air Quality (CMAQ) model to estimate the changes of key air pollutants. From pre-lockdown to lockdown periods, improved air quality is observed in India, indicated by the lower key pollutant levels such as PM2.5 (−26 %), maximum daily 8 h average ozone (MDA8 O3) (−11 %), NO2 (−50 %), and SO2 (−14 %). In addition, changes in these pollutants show distinct spatial variations with the more important decrease in northern and western India. During the lockdown, our results illustrate that such emission reductions play a positive role in the improvement of air quality. Significant reductions of PM2.5 concentration and its major components are predicted, especially for secondary inorganic aerosols that are up to 92 %, 57 %, and 79 % for nitrate (NO3-), sulfate (SO42-), and ammonium (NH4+), respectively. On average, the MDA8 O3 also decreases 15 % during the lockdown period although it increases slightly in some VOC-limited urban locations, which is mainly due to the more significant reduction of NOx than VOCs. More aggressive and localized emission control strategies should be implemented in India to mitigate air pollution in the future.

Published

2020

49. Search for intermediate resonances and dark gauge bosons in J/ψ→γπ0η′

Author

Kun Zhang, M. Richter, Xinying Song, M. Bertani, B. J. Liu, L. Yang, T. Holtmann, Hai-Bo Li, C. L. Luo, Yuanbo Chen, Marcel Rump, B. Zhong, Ryan Mitchell, Lei Li, Ulrich Wiedner, Andreas Pitka, Viktor Rodin, Qiao Zhou, L. J. Wu, H. J. Lu, Jiawen Zhang, C.-H. Rosner, Gang Chen, Tao Hu, M. X. Luo, D. V. Dedovich, Z. Y. Wang, Qian Liu, H. Q. Zhang, Z. J. Sun, Yajun Mao, J. F. Chang, Y. S. Zhu, I. Garzia, Johannes Bloms, Chengwei Wang, Khurelbaatar Begzsuren, F. Feldbauer, X. K. Zhou, R. Kliemt, Kai Zhu, K. Goetzen, M. Maggiora, Ling Zhao, Sebastian Jaeger, Chang-Zheng Yuan, Y. J. Mo, V. Prasad, S. H. Zhu, Gang Li, Yubin Zhao, Fang Liu, L. L. Wang, X. W. Tang, Zongyuan Wang, Tao Yu, Yongjie Sun, Houbing Jiang, Thomas Lenz, X.S. Li, H. X. Yang, Bo Zheng, Viktor Thorén, Iman Keshk, Feng Liu, J. C. Chen, Sifan Zhang, X. A. Xiong, M. Rolo, Zhenyu Zhang, Xiang Liu, Jacek Biernat, M. Kuemmel, Ming Qi, W. Gradl, Fengcai Ma, Y. Bai, Xuan Zhang, Zhenjun Xiao, A. Mangoni, Xianglei Zhu, Nasser Kalantar-Nayestanaki, Xinyu Shan, Lingyun Liu, I. Denysenko, Yang Gao, X. S. Jiang, P. Weidenkaff, Jie Yu, H. R. Qi, Mengzhen Wang, Hailong Ma, Will Imoehl, Lei Zhao, P. Kiese, Bing Liu, X. Y. Jiang, Xiao Cai, A. A. Zafar, M. J. Chen, Zhonghua Qin, Q. Ouyang, Bin Wang, Huihui Liu, Yi Fang, Jianbin Jiao, I. B. Nikolaev, Bing-Song Zou, Jiaheng Zou, Mathew Glenn Kurth, G. A. Chelkov, Alexander Gilman, J. H. Yin, R. A. Briere, Yunpeng Lu, Tong Liu, Yongzhao Sun, S. S. Fang, O. Bakina, P. R. Li, X. S. Qin, M. Albrecht, T. J. Min, Jingwen Li, Y. B. Liu, H. Y. Sheng, Jens Soeren Lange, Suyu Xiao, Y. T. Gu, Serkant Ali Cetin, Q. An, G. Y. Tang, Q. J. Li, Li Zhou, Z. L. Hou, F. H. Heinsius, Yasemin Schelhaas, Xiaodong Shi, G. S. Huang, K. H. Rashid, Z.Q. Zhang, J. G. Messchendorp, X. R. Zhou, Xingtao Huang, Hao Cai, Rinaldo Baldini Ferroli, Muzaffar Irshad, J. P. Dai, Stephen Lars Olsen, Xiongfei Wang, Xuan Wang, H. S. Chen, Michela Greco, J. W. Zhao, C. B. Zhang, Weishuai Cheng, Huanhuan Liu, Y. Pan, Tobias Weber, D. X. Lin, A. Sarantsev, Klaus Peters, D. H. Wei, Jing Chen, Jing Dong, J. Chai, Meng Wang, Cheng Li, Xin Shi, J. J. Xu, Longzhou Liao, Ming Shao, Y. Z. Sun, Sneha Malde, Thomas Held, Jian Zhuang, Yuehong Xie, J. V. Bennett, Xiaokang Zhou, L. G. Xia, F. Cossio, Fengfei Sui, Jialun Ping, C. F. Liu, Yingchun Zhu, Qingqing Song, Y. J. Zhang, Evelina Gersabeck, Alexey Zhemchugov, M. H. Ye, Xiaoqing Yuan, B. T. Tsednee, Dapeng Jin, H. Y. Zhang, Wanling Chang, Z. Jiao, Fu-Hu Liu, Shuang Han, P. X. Shen, Jingzhi Zhang, K. J. Zhu, Peirong Li, Fabrizio Bianchi, Zhigang Wang, Mathilde Himmelreich, Bingxin Zhang, X. Y. Shen, Yanjia Xiao, Xinchou Lou, Yingrui Hou, Jingwei Zhao, Cui Li, Zhenghao Zhang, L. Y. Dong, Weiping Wang, Yifan Yang, Liang Liu, C. Sowa, Dahua Zhang, Jianbei Liu, M. Y. Dong, S. P. Wen, Xiaoyan Ma, Xinchen Dai, Y. X. Yang, Ning Cao, Duanyou Chen, Y. Nefedov, R. P. Guo, Y. H. Xie, Q. P. Ji, Yun Zeng, S. Gu, Cong-Feng Qiao, Zhibing Li, F. A. Harris, X. B. Ji, L. Koch, A. Khoukaz, Jiada Lu, H. Leithoff, S. Ahmed, J. Min, Kanglin He, F. Nerling, Boxiang Yu, W. Shan, S. Liu, A. Q. Guo, P. L. Wang, Y.Y. Zhang, Francesca De Mori, X. L. Luo, Krishnakumar Ravindran, Aonan Zhu, N. Y.-U. Muchnoi, Y. H. Zheng, B. Kopf, Stefano Lusso, X. S. Kang, Lipeng Zhou, Zhiqing Liu, Y. Q. Wang, Qiang Zhao, S. Nisar, Y. Hu, Pengwei Luo, Kai Liu, Liang Sun, Stefano Spataro, Magnus Wolke, Junfeng Sun, G. Cibinetto, Zhengguo Zhao, X. Q. Hao, Wenjing Zhu, Yong Ban, Rongxing Yang, C. Dong, S. Sosio, J. L. Hu, L. Yan, Haijun Yang, Shuangli Yang, P. Larin, T. Hussain, D. Y. Wang, Hongbang Liu, Junguang Lu, Yangheng Zheng, Y. Guo, J. F. Qiu, X. P. Xu, Z. L. Dou, Dianyu Liu, Q. J. Xu, Yong Ding, G. R. Liao, Yu Lu, J. M. Zhang, Ziyuan Li, Zhaoxia Meng, B. Q. Wang, M. H. Gu, L. H. Wu, Yuqing Wang, W. X. Gong, J. Li, S. Marcello, Xiaofei Cui, Ye Yuan, Dong Liu, L. L. Ma, Y. F. Liang, L. Gong, Libo Guo, O. B. Kolcu, L. Z. Wang, J. Liu, M. Ye, X. H. Mo, L. Fava, Shengsen Sun, P. Patteri, Limin Gu, Ying Fu, Sen Qian, Ronggang Ping, Chuangxin Lin, Wolfgang Kuehn Kühn, Joachim Pettersson, Changjian Tang, Shan Jin, Simon Nakhoul, G. X. Sun, H. H. Li, A. Amoroso, L. Lavezzi, Fang Yan, F. E. Maas, Haiping Peng, Shuaiying Li, Xiaolu Ji, Tianchi Zhao, Meike Kuessner, Sanqiang Qu, Y.N. Gao, Z. A. Zhu, Yan Zhang, Xiaoping Qin, Yao Zhang, Tao Luo, Tianyu Xing, Achim Denig, H. M. Hu, Z. Gao, Alexey Guskov, Tingting Han, Yuekun Heng, F. Y. Li, Y. G. Gao, M. G. Zhao, N. Qin, Sai-Juan Chen, Maxim Alekseev, Longke Li, W. B. Yan, D. Bettoni, Y. F. Long, Yanchu Wang, Guang Zhao, Patrik Adlarson, C. D. Fu, M. N. Achasov, A. Dbeyssi, Ryuta Kiuchi, C. Q. Feng, Rosa Kappert, R. Poling, C. S. Yu, Xiang Pan, Xiaozhong Huang, Wei Xu, Jianping Zheng, Jingzhou Zhao, Alperen Yuncu, X. Y. Gao, Z. Y. Deng, Yanjian Lin, Giulietto Felici, Zhenan Liu, Youhua Yang, S. Pacetti, Shujun Zhao, J. G. Zhang, S. X. Du, H. L. Dai, Igor Boyko, K. Y. Liu, Xuhong Li, Angelo Rivetti, Yi Zhang, Y. T. Liang, Walter Ikegami Andersson, Z. Y. You, Guy Wilkinson, Frederik Weidner, M. Destefanis, J. J. Song, Y. Jin, Ke Li, H. H. Liu, Tord Johansson, Tianjiao Zhang, Z. Wu, R. Farinelli, C. Morales, Andrzej Kupsc, C. F. Redmer, G. F. Cao, Jingzhou Fan, Jiang Zhu, Q. M. Ma, A. Mustafa, Mingming Ma, Yaxing Tan, X. N. Li, D. M. Li, M. Fritsch, Xuyang Liu, Yu Zhang, C. P. Shen, Xiaolong Wang, J. Zhang, M. Kavatsyuk, Y. D. Wang, H. Muramatsu, Hongwei Wen, J. W. Zhang, M. Pelizaeus, Wei Li, B. X. Zhang, Michael Papenbrock, I. Uman, C. Schnier, Lei Zhang, Tianyu Qi, B. C. Ke, Nils Huesken, Stephan Maldaner, M. Ablikim, G. Rong, Z. P. Mao, H. Liang, W. D. Li, Xinxin Ma, A. Calcaterra, Ke Wang, Ke Liu, Q. A. Malik, G. Mezzadri, W. C. Yan, Guofa Xu, Y. M. Ma, J. Fang, Zhe Ning, X. B. Ma, J. Libby, Xiao-Rui Lyu, Ilaria Balossino, K. Schoenning, and Niklaus Berger

Subjects

Physics, Gauge boson, Particle physics, 010308 nuclear & particles physics, Electron–positron annihilation, 0103 physical sciences, Pi, CP violation, Gauge (firearms), 010306 general physics, 01 natural sciences, Prime (order theory)

Abstract

We report on an analysis of the decay J/ψ→γπ0η′ using a sample of (1310.6±7.0)×106J/ψ events collected with the BESIII detector. We search for the CP-violating process ηc→π0η′ and a dark gauge boso ...

Published

2020

50. Observation of X(2370) and search for X(2120) in $$J/\psi \rightarrow \gamma K{\bar{K}} \eta '$$

Author

M. Ablikim, M. N. Achasov, P. Adlarson, S. Ahmed, M. Albrecht, M. Alekseev, A. Amoroso, Q. An, null Anita, Y. Bai, O. Bakina, R. Baldini Ferroli, I. Balossino, Y. Ban, K. Begzsuren, J. V. Bennett, N. Berger, M. Bertani, D. Bettoni, F. Bianchi, J Biernat, J. Bloms, I. Boyko, R. A. Briere, H. Cai, X. Cai, A. Calcaterra, G. F. Cao, N. Cao, S. A. Cetin, J. Chai, J. F. Chang, W. L. Chang, G. Chelkov, D. Y. Chen, G. Chen, H. S. Chen, J. C. Chen, M. L. Chen, S. J. Chen, Y. B. Chen, W. Cheng, G. Cibinetto, F. Cossio, X. F. Cui, H. L. Dai, J. P. Dai, X. C. Dai, A. Dbeyssi, D. Dedovich, Z. Y. Deng, A. Denig, I. Denysenko, M. Destefanis, F. De Mori, Y. Ding, C. Dong, J. Dong, L. Y. Dong, M. Y. Dong, Z. L. Dou, S. X. Du, J. Z. Fan, J. Fang, S. S. Fang, Y. Fang, R. Farinelli, L. Fava, F. Feldbauer, G. Felici, C. Q. Feng, M. Fritsch, C. D. Fu, Y. Fu, X. L. Gao, Y. Gao, Y. G. Gao, Z. Gao, I. Garzia, E. M. Gersabeck, A. Gilman, K. Goetzen, L. Gong, W. X. Gong, W. Gradl, M. Greco, L. M. Gu, M. H. Gu, S. Gu, Y. T. Gu, A. Q. Guo, L. B. Guo, R. P. Guo, Y. P. Guo, A. Guskov, S. Han, X. Q. Hao, F. A. Harris, K. L. He, F. H. Heinsius, T. Held, Y. K. Heng, M. Himmelreich, T. Holtmann, Y. R. Hou, Z. L. Hou, H. M. Hu, J. F. Hu, T. Hu, Y. Hu, G. S. Huang, J. S. Huang, X. T. Huang, X. Z. Huang, N. Huesken, T. Hussain, W. Ikegami Andersson, W. Imoehl, M. Irshad, S. Jaeger, Q. Ji, Q. P. Ji, X. B. Ji, X. L. Ji, H. B. Jiang, X. S. Jiang, X. Y. Jiang, J. B. Jiao, Z. Jiao, D. P. Jin, S. Jin, Y. Jin, T. Johansson, N. Kalantar-Nayestanaki, X. S. Kang, R. Kappert, M. Kavatsyuk, B. C. Ke, I. K. Keshk, A. Khoukaz, P. Kiese, R. Kiuchi, R. Kliemt, L. Koch, O. B. Kolcu, B. Kopf, M. Kuemmel, M. Kuessner, A. Kupsc, M. G. Kurth, W. Kühn, J. S. Lange, P. Larin, L. Lavezzi, H. Leithoff, T. Lenz, C. Li, Cheng Li, D. M. Li, F. Li, G. Li, H. B. Li, H. J. Li, J. C. Li, J. W. Li, Ke Li, L. K. Li, Lei Li, P. L. Li, P. R. Li, Q. Y. Li, S. Y. Li, W. D. Li, W. G. Li, X. H. Li, X. L. Li, X. N. Li, Z. B. Li, Z. Y. Li, H. Liang, Y. F. Liang, Y. T. Liang, G. R. Liao, L. Z. Liao, J. Libby, C. X. Lin, D. X. Lin, Y. J. Lin, B. Liu, B. J. Liu, C. X. Liu, D. Liu, D. Y. Liu, F. H. Liu, Fang Liu, Feng Liu, H. B. Liu, H. M. Liu, Huanhuan Liu, Huihui Liu, J. B. Liu, J. Y. Liu, K. Liu, K. Y. Liu, Ke Liu, L. Liu, L. Y. Liu, Q. Liu, S. B. Liu, T. Liu, X. Liu, X. Y. Liu, Y. B. Liu, Z. A. Liu, Z. Q. Liu, Y. F. Long, X. C. Lou, H. J. Lu, J. D. Lu, J. G. Lu, Y. Lu, Y. P. Lu, C. L. Luo, M. X. Luo, P. W. Luo, T. Luo, X. L. Luo, S. Lusso, X. R. Lyu, F. C. Ma, H. L. Ma, L. L. Ma, M. M. Ma, Q. M. Ma, X. N. Ma, X. X. Ma, X. Y. Ma, Y. M. Ma, F. E. Maas, M. Maggiora, S. Maldaner, S. Malde, Q. A. Malik, A. Mangoni, Y. J. Mao, Z. P. Mao, S. Marcello, Z. X. Meng, J. G. Messchendorp, G. Mezzadri, J. Min, T. J. Min, R. E. Mitchell, X. H. Mo, Y. J. Mo, C. Morales Morales, N. Yu. Muchnoi, H. Muramatsu, A. Mustafa, S. Nakhoul, Y. Nefedov, F. Nerling, I. B. Nikolaev, Z. Ning, S. Nisar, S. L. Olsen, Q. Ouyang, S. Pacetti, Y. Pan, M. Papenbrock, P. Patteri, M. Pelizaeus, H. P. Peng, K. Peters, J. Pettersson, J. L. Ping, R. G. Ping, A. Pitka, R. Poling, V. Prasad, H. R. Qi, M. Qi, T. Y. Qi, S. Qian, C. F. Qiao, N. Qin, X. P. Qin, X. S. Qin, Z. H. Qin, J. F. Qiu, S. Q. Qu, K. H. Rashid, K. Ravindran, C. F. Redmer, M. Richter, A. Rivetti, V. Rodin, M. Rolo, G. Rong, Ch. Rosner, M. Rump, A. Sarantsev, M. Savrié, Y. Schelhaas, C. Schnier, K. Schoenning, W. Shan, X. Y. Shan, M. Shao, C. P. Shen, P. X. Shen, X. Y. Shen, H. Y. Sheng, X. Shi, X. D Shi, J. J. Song, Q. Q. Song, X. Y. Song, S. Sosio, C. Sowa, S. Spataro, F. F. Sui, G. X. Sun, J. F. Sun, L. Sun, S. S. Sun, Y. J. Sun, Y. K Sun, Y. Z. Sun, Z. J. Sun, Z. T. Sun, Y. X. Tan, C. J. Tang, G. Y. Tang, X. Tang, V. Thoren, B. Tsednee, I. Uman, B. Wang, B. L. Wang, C. W. Wang, D. Y. Wang, K. Wang, L. L. Wang, L. S. Wang, M. Wang, M. Z. Wang, Meng Wang, P. L. Wang, W. P. Wang, X. Wang, X. F. Wang, X. L. Wang, Y. Wang, Y. D. Wang, Y. F. Wang, Y. Q. Wang, Z. Wang, Z. G. Wang, Z. Y. Wang, Zongyuan Wang, T. Weber, D. H. Wei, P. Weidenkaff, F. Weidner, H. W. Wen, S. P. Wen, U. Wiedner, G. Wilkinson, M. Wolke, L. H. Wu, L. J. Wu, Z. Wu, L. Xia, S. Y. Xiao, Y. J. Xiao, Z. J. Xiao, Y. G. Xie, Y. H. Xie, T. Y. Xing, X. A. Xiong, G. F. Xu, J. J. Xu, Q. J. Xu, W. Xu, X. P. Xu, F. Yan, L. Yan, W. B. Yan, W. C. Yan, H. J. Yang, H. X. Yang, L. Yang, R. X. Yang, S. L. Yang, Y. H. Yang, Y. X. Yang, Yifan Yang, M. Ye, M. H. Ye, J. H. Yin, Z. Y. You, B. X. Yu, C. X. Yu, J. S. Yu, T. Yu, C. Z. Yuan, X. Q. Yuan, Y. Yuan, A. Yuncu, A. A. Zafar, Y. Zeng, B. X. Zhang, B. Y. Zhang, C. C. Zhang, D. H. Zhang, H. H. Zhang, H. Y. Zhang, J. Zhang, J. L. Zhang, J. Q. Zhang, J. W. Zhang, J. Y. Zhang, J. Z. Zhang, K. Zhang, L. Zhang, Lei Zhang, S. F. Zhang, T. J. Zhang, X. Y. Zhang, Y. H. Zhang, Y. T. Zhang, Yan Zhang, Yao Zhang, Yi Zhang, Yu Zhang, Z. H. Zhang, Z. P. Zhang, Z. Y. Zhang, G. Zhao, J. W. Zhao, J. Y. Zhao, J. Z. Zhao, Lei Zhao, Ling Zhao, M. G. Zhao, Q. 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Subjects

Combinatorics, Physics, Physics and Astronomy (miscellaneous), 010308 nuclear & particles physics, Product (mathematics), 0103 physical sciences, 010306 general physics, 01 natural sciences, Engineering (miscellaneous), Bar (unit)

Abstract

Using a sample of $$1.31\times 10^{9} ~J/\psi $$1.31×109J/ψ events collected with the BESIII detector, we perform a study of $$J/\psi \rightarrow \gamma K{\bar{K}}\eta '$$J/ψ→γKK¯η′. X(2370) is observed in the $$K{\bar{K}}\eta '$$KK¯η′ invariant-mass distribution with a statistical significance of $$8.3\sigma $$8.3σ. Its resonance parameters are measured to be $$M=2341.6\pm 6.5 \, \text {(stat.)} \pm 5.7 \, \text {(syst.)}~ \hbox {MeV}/c^{2}$$M=2341.6±6.5(stat.)±5.7(syst.)MeV/c2 and $$\Gamma = 117\pm 10 \, \text {(stat.)}\pm 8 \, \text {(syst.)}~\hbox {MeV}$$Γ=117±10(stat.)±8(syst.)MeV. The product branching fractions for $$J/\psi \rightarrow \gamma X(2370),X(2370)\rightarrow K^{+}K^{-}\eta '$$J/ψ→γX(2370),X(2370)→K+K-η′ and $$J/\psi \rightarrow \gamma X(2370),X(2370)\rightarrow K_{S}^{0}K_{S}^{0}\eta '$$J/ψ→γX(2370),X(2370)→KS0KS0η′ are determined to be $$(1.79\pm 0.23\, \text {(stat.)}\pm 0.65\,\text {(syst.)})\times 10^{-5}$$(1.79±0.23(stat.)±0.65(syst.))×10-5 and $$(1.18\pm 0.32\, \text {(stat.)}\pm 0.39\, \text {(syst.)})\times 10^{-5}$$(1.18±0.32(stat.)±0.39(syst.))×10-5, respectively. No evident signal for X(2120) is observed in the $$K{\bar{K}}\eta '$$KK¯η′ invariant-mass distribution. The upper limits for the product branching fractions of $${\mathcal {B}}(J/\psi \rightarrow \gamma X(2120)\rightarrow \gamma K^{+} K^{-} \eta ')$$B(J/ψ→γX(2120)→γK+K-η′) and $${\mathcal {B}}(J/\psi \rightarrow \gamma X(2120)\rightarrow \gamma K_{S}^{0} K_{S}^{0} \eta ')$$B(J/ψ→γX(2120)→γKS0KS0η′) are determined to be $$1.49\times 10^{-5}$$1.49×10-5 and $$6.38\times 10^{-6}$$6.38×10-6 at the 90% confidence level, respectively.

Published

2020