Your search keyword '"Liu Xiao-Jing"' showing total 1,470 results

1. No obvious unintended effects was found in gene editing rice through transcriptional and proteomic analysis

Author

Liu Xiao-Jing, Xing Bao, Wang Meng-Yu, Li Xiao-Man, Wang Xu-Jing, and Wang Zhi-Xing

Subjects

Gene edit, proteome, transcriptome, unintended effects, Plant culture, SB1-1110, Genetics, QH426-470

Abstract

ABSTRACTUnintended effects of gene edit crops may pose safety issues. Omics is a useful tool for researchers to evaluate these unexpected effects. Transcriptome and proteomics analyses were performed for two gene editors, CRISPR-Cas9 and adenine base editor (ABE) gene edit rice, as well as corresponding wild-type plants (Nipponbare). Transcriptome revealed 520 and 566 rice differentially expressed genes (DEGs) in the Cas9/Nip and ABE/Nip comparisons, respectively. Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analysis showed that most DEGs participated in metabolism of terpenoids and polyketones, plant–pathogen interactions, and plant signal transduction. It mainly belongs to environmental adaptation. Proteomics revealed 298 and 54 rice differentially expressed proteins (DEPs) in the Cas9/Nip and ABE/Nip comparisons, respectively. KEGG pathway enrichment analysis showed that most DEPs participated in the biosynthesis of secondary metabolite and metabolic pathways.According to integrated transcriptomes and proteomics analysis, the results showed that no newly generated genes were identified as new transcripts of these differentially expressed genes, and gene edit tools had little effect on rice transcription levels and no new proteins were generated in the gene-edited rice.

Published

2023

2. Crystal structure of (E)-amino(2-(3-ethoxy-4-hydroxybenzylidene)hydrazineyl)methaniminium nitrate hemihydrate C10H16N5O5.5

Author

Jin Ze-Sen, Liu E., Liu Xiao-Jing, Jian Fang-Fang, and Liang Tongling

Subjects

2168515, Physics, QC1-999, Crystallography, QD901-999

Abstract

C10H16N5O5.5, monoclinic, C2/c (no. 15), a = 17.7836(8) Å, b = 9.4796(4) Å, c = 15.8740(8) Å, β = 97.093(5)°, V = 2655.6(2) Å3, Z = 8, Rgt(F) = 0.0469, wRref(F2) = 0.1289, T = 170 K.

Published

2022

3. Crystal structure of (E)-amino(2-(thiazol-2-ylmethylene)hydrazineyl)methaniminium nitrate, C10H16N12O6S2

Author

Jin Ze-Sen, Liu E., Liu Xiao-jing, Li Zhuang-yu, Jian Fang-fang, and Liang Tongling

Subjects

2150119, Physics, QC1-999, Crystallography, QD901-999

Abstract

C10H16N12O6S2, triclinic, P1‾ $P\overline{1}$ (no. 2), a = 7.6977(2) Å, b = 11.5353(3) Å, c = 11.7533(3) Å, α = 67.973(2)°, β = 87.916(2)°, γ = 88.347(2)°, V = 966.69(5) Å3, Z = 2, R gt(F) = 0.0290, wR ref(F 2) = 0.0818, T = 170K.

Published

2022

4. Crystal structure of (E)-amino(2-((5-methylfuran-2-yl)methylene)hydrazinyl) methaniminium nitrate monohydrate, C14H26N10O10

Author

Jin Ze-Sen, Liu E., Liu Xiao-jing, Jian Fang-fang, and Liang Tongling

Subjects

2125809, Physics, QC1-999, Crystallography, QD901-999

Abstract

C14H26N10O10, monoclinic, P21 (no. 4), a = 12.3337(3) Å, b = 3.87010(10) Å, c = 24.2368(6) Å, β = 97.644(2)°, V = 1146.61(5) Å3, Z = 2, Rgt(F) = 0.0400, wRref(F2) = 0.1092, T = 170 K.

Published

2022

5. Crystal structure of diaqua-bis(2,4-dinitrophenolato-κ2O,O′)copper(II) 1.5 hydrate, C12H13CuN4O13.5

Author

Liu Xiao-Jing, Li Wen-Yu, Guo Zi-Yu, Liu E., Jian Fang-Fang, and Liang Tongling

Subjects

2077731, Physics, QC1-999, Crystallography, QD901-999

Abstract

C24H26Cu2N8O27, triclinic, P1‾$P‾{1}$ (no. 2), a = 4.7705(1) Å, b = 14.6219(5) Å, c = 14.7418(3) Å, α = 61.225(3)°, β = 85.342(2)°, γ = 83.938(2)°, V = 895.73(5) Å3, Z = 1, Rgt(F) = 0.0485, wRref(F2) = 0.1341, T = 170.0 K.

Published

2021

6. Multiple mediation effects of health locus of control and hope on the relationship between stroke patients’ social support and self-management

Author

Lei Ting-Ting, Han Hong-Mei, and Liu Xiao-Jing

Subjects

social support, health locus of control, hope, self-management, multiple mediation effects, Nursing, RT1-120

Abstract

This study aimed to identify the mediation effects of health locus of control (HLC) and hope between stroke patients’ social support and self-management.

Published

2020

7. Crystal structure of 1,3-bis(octyl)benzimidazolium perchlorate C23H39ClN2O4

Author

Liu Xiao-jing, Li Zhuang-yu, Liu E, Jian Fang-fang, and Liang Tong-ling

Subjects

747918, Physics, QC1-999, Crystallography, QD901-999

Abstract

C23H39ClN2O4, triclinic, P1‾$P‾{1}$ (no. 2), a = 9.0752(19) Å, b = 9.542(2) Å, c = 16.049(3) Å, α = 99.088(4)°, β = 94.422(4)°, γ = 107.146(4)°, V = 1300.0(5) Å3, Z = 2, Rgt(F) = 0.0646, wRref(F2) = 0.2298, T = 293.0 K.

Published

2021

8. Crystal structure of dichlorido-bis(1-hexyl-1H-benzotriazole-k1N)zinc(II), C24H34N6Cl2Zn

Author

Liu Xiao-jing, Liu E., Jin Ze-shen, Li Zhuang-yu, Jian Fang-fang, and Liang Tong-ling

Subjects

2046616, Physics, QC1-999, Crystallography, QD901-999

Abstract

C24H34N6Cl2Zn, monoclinic, P21/c (no. 14), a = 9.513(3) Å, b = 9.546(3) Å, c = 30.956(10) Å, β = 101.228(9)°, V = 2757.3(15) Å3, Z = 4, Rgt(F) = 0.0452, wRref(F2) = 0.1299, T = 293 K.

Published

2021

9. Crystal structure of 1,1′-bis(diphenylphosphino)ferrocene-(1,1′-bis(diphenylphosphino)ferrocene-κ2P,P′)-(O-isobutyl sulfurodithioito-κ2S,S′)copper(I), C39H37CuFeOP2S2

Author

Li Zhuang-yu, Liu Xiao-jing, Liu E., Jian Fang-fang, and Liang Tongling

Subjects

1877712, Physics, QC1-999, Crystallography, QD901-999

Abstract

C39H37CuFeOP2S2, triclinic, P1̄ (no. 2), a = 9.6132(10) Å, b = 11.5667(12) Å, c = 16.8739(18) Å, α = 99.732(2)°, β = 96.342(2)°, γ = 93.446(2)°, V = 1832.0(3) Å3, Z = 2, Rgt(F) = 0.0455, wRref(F2) = 0.1212, T = 293.0 K.

Published

2020

10. Crystal structure of bis(N,2-bis(4-ethoxybenzylidene)hydrazine-1-carbohydrazonothioato-κ2N,S)nickel(II) — N,N-dimethylformamide (1/2), C44H56N10S2O6Ni

Author

Li Zhuang-Yu, Liu E., Liu Xiao-Jing, Jian Fang-Fang, and Liang Tong-ling

Subjects

1986652, Physics, QC1-999, Crystallography, QD901-999

Abstract

C44H56N10S2O6Ni, triclinic, P1̄ (no. 2), a = 9.3077(14) Å, b = 9.9624(14) Å, c = 14.0449(19) Å, α = 70.889(3)°, β = 75.532(2)°, γ = 87.544(3)°, V = 1190.5(3) Å3, Z = 1, Rgt(F) = 0.0528, wRref(F2) = 0.1279, T = 293 K.

Published

2020

11. Crystal structure of bis(2,3-diphenyltetrazolidine-5-thione-κ1S)-(nitrato-κ1O)-(nitrato-κ2O,O′)lead(II), C26H20N10O6S2Pb

Author

Li Zhuang-yu, Liu E, Liu Xiao-jing, and Jian Fang-fang

Subjects

1989442, Physics, QC1-999, Crystallography, QD901-999

Abstract

C26H20N10O6S2Pb, triclinic, P1̄ (no. 2), a = 9.3480(19) Å, b = 12.985(3) Å, c = 14.278(3) Å, α = 113.14(3)°, β = 92.05(3)°, γ = 102.75(3)°, V = 1539.8(7) Å3, Z = 2, Rgt(F) = 0.0336, wRref(F2) = 0.0874, T = 293.0 K.

Published

2020

12. Crystal structure of 2-((E)-(((E)-2-hydroxy-4-methylbenzylidene) hydrazineylidene)methyl)-4-methylphenol, C16H16N2O2

Author

Jin Ze-Sen, Liu Xiao-jing, Liu E., Jian Fang-fang, and Liang Tongling

Subjects

2125839, Physics, QC1-999, Crystallography, QD901-999

Abstract

C16H16N2O2, monoclinic, P21/c (no. 14), a = 8.6766(1) Å, b = 5.9039(1) Å, c = 13.3603(2) Å, β = 96.166(1)°, V = 680.432(17) Å3, Z = 2, Rgt(F) = 0.0395, wRref(F2) = 0.1195, T = 170 K.

Published

2022

13. Auger photoemission as a laser-like coherent cathode

Author

Zeng, Yushan, Zhang, Bin, Cao, Kecheng, Liu, Xiao-jing, and Pan, Yiming

Subjects

Quantum Physics, Condensed Matter - Materials Science, Physics - Accelerator Physics, Physics - Applied Physics, Physics - Optics

Abstract

In pursuit of quantum advancements across disciplines, a bright and coherent electron source is expected to be a cornerstone of diverse applications including electron microscopy, laser accelerators, and free electron lasers. Current cathodes, such as cold field and photoemission, can generate high-quality electron beams with different cathode materials, geometric configurations, and laser excitation profiles, but their maintenance of both quantum coherence and high beam brightness suffers from the space-charge repulsion of many electrons. Here, we propose a new mechanism to provide collective emission of coherent electrons based on Auger photoemission. Our approach leverages a photon-induced four-level Auger process that necessitates a combination of photoemission and Auger recombination. The Auger electrons, energized through a recycling process of photoelectrons, emit collectively into the vacuum as secondary electrons. We compare coherent and incoherent Auger photoemission, identifying that the working condition of the coherent photoemission requires population inversion, akin to the four-level laser system. Our work provides insights for experimental realization and nanofabrication of Auger photocathodes, addressing a critical need in advancing quantum technologies relating to correlated coherent sources., Comment: 12 pages, 2 figures

Published

2024

14. Desloratadine ameliorates paclitaxel-induced peripheral neuropathy and hypersensitivity reactions in mice

Author

Lu, Jian, Zhao, Xue-jian, Ruan, Yuan, Liu, Xiao-jing, Di, Xuan, Xu, Rui, Wang, Jia-ying, Qian, Min-yi, Jin, Hong-ming, Li, Wen-jun, and Shen, Xu

Published

2024

15. Crystal structure of (E)-amino(2-(4-(dimethylamino)benzylidene)hydrazineyl)methaniminium nitrate, C10H16N6O3

Author

Liu Xiao-Jing, Liu E., Jin Ze-Sen, Li Zhuang-Yu, Jian Fang-Fang, and Liang Tongling

Subjects

2076114, Physics, QC1-999, Crystallography, QD901-999

Abstract

C10H16N6O3, monoclinic, P21/c$P{2}_{1}/c$ (no. 14), a = 7.2312(1) Å, b = 17.7721(3) Å, c = 11.0146(2) Å, β = 104.557°, V = 1370.08(4) Å3, Z = 4, Rgt (F) = 0.0532, wRref (F2) = 0.1537, T = 170.0 K.

Published

2021

16. Crystal structure of (E)-(2-((1H-pyrrol-2-yl)methylene)hydrazineyl)(amino)methaniminium nitrate monohydrate, C6H12N6O4

Author

Jin Ze-Sen, Liu Xiao-jing, Li Zhuang-Yu, Liu E., Jian Fang-fang, and Liang Tongling

Subjects

2074192, Physics, QC1-999, Crystallography, QD901-999

Abstract

C6H12N6O4, monoclinic, P21/n (no. 14), a = 7.3652(3) Å, b = 16.8683(7) Å, c = 8.3779(3) Å, β = 101.525(4)°, V = 1019.87(7) Å3, Z = 4, Rgt(F) = 0.0349, wRref(F2) = 0.1018, T = 170 K.

Published

2021

17. Detector performance of the Gamma-ray Transient Monitor onboard DRO-A Satellite

Author

Feng, Pei-Yi, An, Zheng-Hua, Zhang, Da-Li, Wang, Chen-Wei, Zheng, Chao, Yang, Sheng, Xiong, Shao-Lin, Liu, Jia-Cong, Li, Xin-Qiao, Gong, Ke, Liu, Xiao-Jing, Gao, Min, Wen, Xiang-Yang, liu, Ya-Qing, Zhao, Xiao-Yun, Zhang, Fan, Sun, Xi-Lei, and Lu, Hong

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, High Energy Physics - Experiment, Nuclear Experiment, Physics - Instrumentation and Detectors

Abstract

Gamma-ray Transient Monitor (GTM) is an all-sky monitor onboard the Distant Retrograde Orbit-A (DRO-A) satellite with the scientific objective of detecting gamma-ray transients ranging from 20 keV to 1 MeV. GTM is equipped with 5 Gamma-ray Transient Probe (GTP) detector modules, utilizing the NaI(Tl) scintillator coupled with a SiPM array. To reduce the SiPM noise, GTP makes use of a dedicated dual-channel coincident readout design. In this work, we firstly studied the impact of different coincidence times on detection efficiency and ultimately selected the 500 ns time coincidence window for offline data processing. To test the performance of GTPs and validate the Monte Carlo simulated energy response, we conducted comprehensive ground calibration tests using Hard X-ray Calibration Facility (HXCF) and radioactive sources, including energy response, detection efficiency, spatial response, bias-voltage response, and temperature dependence. We extensively presented the ground calibration results, and validated the design and mass model of GTP detector. These work paved the road for the in-flight observation and science data analysis., Comment: 15 pages, 25 figures

Published

2024

18. Crystal structure of dichloro-bis-(1-butyl-1H-benzo[d]imidazole)-nickel(II), C22H28Cl2N4Ni

Author

Li Zhuang-yu, Liu Xiao-jing, Liu E., Jian Fang-fang, and Liang Tongling

Subjects

736513, Physics, QC1-999, Crystallography, QD901-999

Abstract

C22H28Cl2N4Ni, monoclinic, P21/c (no. 14), a = 9.7332(19) Å, b = 14.886(3) Å, c = 18.623(5) Å, β = 117.45(2)°, V = 2394.5(10) Å3, Z = 4, Rgt(F) = 0.0450, wRref(F2) = 0.1466, T = 293.0 K.

Published

2020

19. Crystal structure of diisobutyl 2,5-dihydroxycyclohexa-1,4-diene-1,4-dicarboxylate, C16H24O6

Author

Li Zhuang-Yu, Liu E., Liu Xiao-Jing, and Jian Fang-Fang

Subjects

1981073, Physics, QC1-999, Crystallography, QD901-999

Abstract

C16H24O6, triclinic, P1̄ (no. 2), a = 6.3410(13) Å, b = 7.3430(15) Å, c = 10.241(2) Å, α = 94.06(3)°, β = 103.89(3)°, γ = 113.13(3)°, V = 418.3(8) Å3, Z = 1, Rgt(F) = 0.0546, wRref(F2) = 0.1691, T = 295(3) K.

Published

2020

20. The Energy Response of LaBr3(Ce), LaBr3(Ce,Sr) and NaI(Tl) Crystals for GECAM

Author

Feng, Pei-Yi, Sun, Xi-Lei, An, Zheng-Hua, Deng, Yong, Wang, Cheng-Er, Jiang, Huang, Li, Jun-Jie, Zhang, Da-Li, Li, Xin-Qiao, Xiong, Shao-Lin, Zheng, Chao, Gong, Ke, Yang, Sheng, Liu, Xiao-Jing, Gao, Min, Wen, Xiang-Yang, Liu, Ya-Qing, Xu, Yan-Bing, Zhao, Xiao-Yun, Liu, Jia-Cong, Zhang, Fan, and Lu, Hong

Subjects

Physics - Instrumentation and Detectors, Astrophysics - Instrumentation and Methods for Astrophysics, High Energy Physics - Experiment, Nuclear Experiment

Abstract

The GECAM series of satellites utilize LaBr3(Ce), LaBr3(Ce,Sr), and NaI(Tl) crystals as sensitive materials for gamma-ray detectors (GRDs). To investigate the non-linearity in the detection of low-energy gamma rays and address errors in the E-C relationship calibration, comprehensive tests and comparative studies of the non-linearity of these three crystals were conducted using Compton electrons, radioactive sources, and mono-energetic X-rays. The non-linearity test results for Compton electrons and X-rays displayed substantial differences, with all three crystals showing higher non-linearity for X-rays and gamma-rays than for Compton electrons. Despite LaBr3(Ce) and LaBr3(Ce,Sr) crystals having higher absolute light yields, they exhibited a noticeable non-linear decrease in light yield, especially at energies below 400 keV. The NaI(Tl) crystal demonstrated excess light output in the 6~200 keV range, reaching a maximum excess of 9.2% at 30 keV in X-ray testing and up to 15.5% at 14 keV during Compton electron testing, indicating a significant advantage in the detection of low-energy gamma rays. Furthermore, this paper explores the underlying causes of the observed non-linearity in these crystals. This study not only elucidates the detector responses of GECAM, but also marks the inaugural comprehensive investigation into the non-linearity of domestically produced lanthanum bromide and sodium iodide crystals., Comment: 12pages, 16 figures

Published

2023

21. The evolutionary dynamics of genome sizes and repetitive elements in Ensifera (Insecta: Orthoptera)

Author

Yuan, Hao, Liu, Xiao-Jing, Liu, Xuan-Zeng, Zhao, Li-Na, Mao, Shao-Li, and Huang, Yuan

Published

2024

22. Assessment of subclinical LV myocardial dysfunction in T2DM patients with diabetic peripheral neuropathy: a cardiovascular magnetic resonance study

Author

Li, Xue-Ming, Shi, Ke, Jiang, Li, Wang, Jing, Yan, Wei-Feng, Gao, Yue, Shen, Meng-Ting, Shi, Rui, Zhang, Ge, Liu, Xiao-Jing, Guo, Ying-Kun, and Yang, Zhi-Gang

Published

2024

23. The worsening effect of paroxysmal atrial fibrillation on left ventricular function and deformation in type 2 diabetes mellitus patients: a 3.0 T cardiovascular magnetic resonance feature tracking study

Author

Li, Xue-Ming, Yan, Wei-Feng, Shi, Ke, Shi, Rui, Jiang, Li, Gao, Yue, Min, Chen-Yan, Liu, Xiao-Jing, Guo, Ying-Kun, and Yang, Zhi-Gang

Published

2024

24. Rebuilding the vibrational wavepacket in TRAS using attosecond X-ray pulses

Author

Wang, Chao, Gong, Maomao, Zhao, Xi, Nan, Quan Wei, Yu, Xin Yue, Cheng, Yongjun, Kimberg, Victor, Liu, Xiao-Jing, Vendrell, Oriol, Ueda, Kiyoshi, and Zhang, Song Bin

Published

2024

25. Calibration of the Timing Performance of GECAM-C

Author

Xiao, Shuo, Liu, Ya-Qing, Gong, Ke, An, Zheng-Hua, Xiong, Shao-Lin, Li, Xin-Qiao, Wen, Xiang-Yang, Peng, Wen-Xi, Zhang, Da-Li, Tuo, You-Li, Zheng, Shi-Jie, Song, Li-Ming, Wang, Ping, Zhao, Xiao-Yun, Huang, Yue, Ma, Xiang, Liu, Xiao-Jing, Qiao, Rui, Xu, Yan-Bing, Yang, Sheng, Zhang, Fan, Wang, Yue, Zhang, Yan-Qiu, Xue, Wang-Chen, Liu, Jia-Cong, Zheng, Chao, Wang, Chen-Wei, Tan, Wen-Jun, Cai, Ce, Yi, Qi-Bin, Zhang, Peng, Luo, Xi-Hong, Yang, Jiao-Jiao, Zhi, Qi-Jun, Dong, Ai-Jun, Dang, Shi-Jun, Shang, Lun-Hua, and Zhang, Shuang-Nan

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - High Energy Astrophysical Phenomena

Abstract

As a new member of the Gravitational wave high-energy Electromagnetic Counterpart All-sky Monitor (GECAM) after GECAM-A and GECAM-B, GECAM-C (originally called HEBS), which was launched on board the SATech-01 satellite on July 27, 2022, aims to monitor and localize X-ray and gamma-ray transients from $\sim$ 6 keV to 6 MeV. GECAM-C utilizes a similar design to GECAM but operates in a more complex orbital environment. In this work, we utilize the secondary particles simultaneously produced by the cosmic-ray events on orbit and recorded by multiple detectors, to calibrate the relative timing accuracy between all detectors of GECAM-C. We find the result is 0.1 $\mu \rm s$, which is the highest time resolution among all GRB detectors ever flown and very helpful in timing analyses such as minimum variable timescale and spectral lags, as well as in time delay localization. Besides, we calibrate the absolute time accuracy using the one-year Crab pulsar data observed by GECAM-C and Fermi/GBM, as well as GECAM-C and GECAM-B. The results are $2.02\pm 2.26\ \mu \rm s$ and $5.82\pm 3.59\ \mu \rm s$, respectively. Finally, we investigate the spectral lag between the different energy bands of Crab pulsar observed by GECAM and GBM, which is $\sim -0.2\ {\rm \mu s\ keV^{-1}}$., Comment: submitted

Published

2023

26. GECAM Observations of the Galactic Magnetar SGR J1935+2154 during the 2021 and 2022 Burst Active Episodes. I. Burst Catalog

Author

Xie, Sheng-Lun, Cai, Ce, Yu, Yun-Wei, Xiong, Shao-Lin, Lin, Lin, Zhao, Yi, Zhang, Shuang-Nan, Song, Li-Ming, Wang, Ping, Li, Xiao-Bo, Xue, Wang-Chen, Zhang, Peng, Zheng, Chao, Zhang, Yan-Qiu, Liu, Jia-Cong, Wang, Chen-Wei, Tan, Wen-Jun, Wang, Yue, Yu, Zheng-Hang, Feng, Pei-Yi, Zhang, Jin-Peng, Xiao, Shuo, Zhao, Hai-Sheng, Zhang, Wen-Long, Zhang, Yan-Ting, Huang, Yue, Zhao, Xiao-Yun, Ma, Xiang, Zheng, Shi-Jie, Li, Xin-Qiao, Wen, Xiang-Yang, Gong, Ke, An, Zheng-Hua, Zhang, Da-Li, Yang, Sheng, Liu, Xiao-Jing, and Zhang, Fan

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

Magnetar is a neutron star with an ultrahigh magnetic field ($\sim 10^{14}-10^{15}$ G) which usually manifests as soft gamma-ray repeater (SGR) or anomalous X-ray pulsar (AXP). SGR J1935+2154 is not only one of the most active magnetar detected so far, but also the unique confirmed source of fast radio burst (FRB). Gravitational wave high-energy Electromagnetic Counterpart All-sky Monitor (GECAM) are dedicated to monitor gamma-ray transients all over the sky, including SGR bursts. Here we report the GECAM observation of the burst activity of SGR J1935+2154 from January 2021 to December 2022, which results in a unique and valuable data set for this important magnetar. With a targeted search of GECAM data, 164 bursts from SGR J1935+2154 are detected by GECAM-B while 97 bursts by GECAM-C, including the X-ray burst associated with a fast radio burst (FRB 20221014). We find that both the burst duration and the waiting time between two successive bursts follow lognormal distributions. The period of burst activity is $134\pm20$ days, thus the burst activity could be generally divided into 4 active episodes over these two years. Interestingly, the hardness ratio of X-ray bursts tends to be softer and more concentrated over these two years, especially during the active episode with FRBs detected.

Published

2023

27. Study on hydroforming of aluminum alloy thin-wall curved parts based on upper layer sheet and numerical simulation

Author

Liu, Xiao Jing, Zou, Zhao Long, Zhou, Ying Ying, and Li, Chao

Published

2024

28. Insight-HXMT and GECAM-C observations of the brightest-of-all-time GRB 221009A

Author

An, Zheng-Hua, Antier, S., Bi, Xing-Zi, Bu, Qing-Cui, Cai, Ce, Cao, Xue-Lei, Camisasca, Anna-Elisa, Chang, Zhi, Chen, Gang, Chen, Li, Chen, Tian-Xiang, Chen, Wen, Chen, Yi-Bao, Chen, Yong, Chen, Yu-Peng, Coughlin, Michael W., Cui, Wei-Wei, Dai, Zi-Gao, Hussenot-Desenonges, T., Du, Yan-Qi, Du, Yuan-Yuan, Du, Yun-Fei, Fan, Cheng-Cheng, Frontera, Filippo, Gao, He, Gao, Min, Ge, Ming-Yu, Gong, Ke, Gu, Yu-Dong, Guan, Ju, Guo, Dong-Ya, Guo, Zhi-Wei, Guidorzi, Cristiano, Han, Da-Wei, He, Jian-Jian, He, Jun-Wang, Hou, Dong-Jie, Huang, Yue, Huo, Jia, Ji, Zhen, Jia, Shu-Mei, Jiang, Wei-Chun, Kann, David Alexander, Klotz, A., Kong, Ling-Da, Lan, Lin, Li, An, Li, Bing, Li, Chao-Yang, Li, Cheng-Kui, Li, Gang, Li, Mao-Shun, Li, Ti-Pei, Li, Wei, Li, Xiao-Bo, Li, Xin-Qiao, Li, Xu-Fang, Li, Yan-Guo, Li, Zheng-Wei, Liang, Jing, Liang, Xiao-Hua, Liao, Jin-Yuan, Lin, Lin, Liu, Cong-Zhan, Liu, He-Xin, Liu, Hong-Wei, Liu, Jia-Cong, Liu, Xiao-Jing, Liu, Ya-Qing, Liu, Yu-Rong, Lu, Fang-Jun, Lu, Hong, Lu, Xue-Feng, Luo, Qi, Luo, Tao, Ma, Bin-Yuan, Ma, Fu-Li, Ma, Rui-Can, Ma, Xiang, Maccary, Romain, Mao, Ji-Rong, Meng, Bin, Nie, Jian-Yin, Orlandini, Mauro, Ou, Ge, Peng, Jing-Qiang, Peng, Wen-Xi, Qiao, Rui, Qu, Jin-Lu, Ren, Xiao-Qin, Shi, Jing-Yan, Shi, Qi, Song, Li-Ming, Song, Xin-Ying, Su, Ju, Sun, Gong-Xing, Sun, Liang, Sun, Xi-Lei, Tan, Wen-Jun, Tan, Ying, Tao, Lian, Tuo, You-Li, Turpin, Damien, Wang, Jin-Zhou, Wang, Chen, Wang, Chen-Wei, Wang, Hong-Jun, Wang, Hui, Wang, Jin, Wang, Ling-Jun, Wang, Peng-Ju, Wang, Ping, Wang, Wen-Shuai, Wang, Xiang-Yu, Wang, Xi-Lu, Wang, Yu-Sa, Wang, Yue, Wen, Xiang-Yang, Wu, Bo-Bing, Wu, Bai-Yang, Wu, Hong, Xiao, Sheng-Hui, Xiao, Shuo, Xiao, Yun-Xiang, Xie, Sheng-Lun, Xiong, Shao-Lin, Xiong, Sen-Lin, Xu, Dong, Xu, He, Xu, Yan-Jun, Xu, Yan-Bing, Xu, Ying-Chen, Xu, Yu-Peng, Xue, Wang-Chen, Yang, Sheng, Yang, Yan-Ji, Yang, Zi-Xu, Ye, Wen-Tao, Yi, Qi-Bin, Yi, Shu-Xu, Yin, Qian-Qing, You, Yuan, Yu, Yun-Wei, Yu, Wei, Yu, Wen-Hui, Zeng, Ming, Zhang, Bing, Zhang, Bin-Bin, Zhang, Da-Li, Zhang, Fan, Zhang, Hong-Mei, Zhang, Juan, Zhang, Liang, Zhang, Peng, Zhang, Shu, Zhang, Shuang-Nan, Zhang, Wan-Chang, Zhang, Xiao-Feng, Zhang, Xiao-Lu, Zhang, Yan-Qiu, Zhang, Yan-Ting, Zhang, Yi-Fei, Zhang, Yuan-Hang, Zhang, Zhen, Zhao, Guo-Ying, Zhao, Hai-Sheng, Zhao, Hong-Yu, Zhao, Qing-Xia, Zhao, Shu-Jie, Zhao, Xiao-Yun, Zhao, Xiao-Fan, Zhao, Yi, Zheng, Chao, Zheng, Shi-Jie, Zhou, Deng-Ke, Zhou, Xing, and Zhu, Xiao-Cheng

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

GRB 221009A is the brightest gamma-ray burst ever detected since the discovery of this kind of energetic explosions. However, an accurate measurement of the prompt emission properties of this burst is very challenging due to its exceptional brightness. With joint observations of \textit{Insight}-HXMT and GECAM-C, we made an unprecedentedly accurate measurement of the emission during the first $\sim$1800 s of GRB 221009A, including its precursor, main emission (ME, which dominates the burst in flux), flaring emission and early afterglow, in the hard X-ray to soft gamma-ray band from $\sim$ 10 keV to $\sim$ 6 MeV. Based on the GECAM-C unsaturated data of the ME, we measure a record-breaking isotropic equivalent energy ($E_{\rm iso}$) of $\bf \sim 1.5 \times 10^{55}$ erg, which is about eight times the total rest-mass energy of the Sun. The early afterglow data require a significant jet break between 650 s and 1100 s, most likely at $\sim950$ s from the afterglow starting time $T_{AG}$, which corresponds to a jet opening angle of $\sim {0.7^\circ} \ (\eta_\gamma n)^{1/8}$, where $n$ is the ambient medium density in units of $\rm cm^{-3}$ and $\eta_\gamma$ is the ratio between $\gamma$-ray energy and afterglow kinetic energy. The beaming-corrected total $\gamma$-ray energy $E_{\gamma}$ is $\sim 1.15 \times10^{51} \ (\eta_\gamma n)^{1/4}$ erg, which is typical for long GRBs. These results suggest that this GRB may have a special central engine, which could launch and collimate a very narrowly beamed jet with an ordinary energy budget, leading to exceptionally luminous gamma-ray radiation per unit solid angle. Alternatively, more GRBs might have such a narrow and bright beam, which are missed by an unfavorable viewing angle or have been detected without distance measurement., Comment: Submitted to National Science Review. This paper is under press embargo, contact the corresponding author for details

Published

2023

29. Cross calibration of gamma-ray detectors (GRD) of GECAM-C

Author

Zhang, Yan-Qiu, Xiong, Shao-Lin, Qiao, Rui, Guo, Dong-Ya, Peng, Wen-Xi, Li, Xin-Qiao, Xue, Wang-Chen, Zheng, Chao, Liu, Jia-Cong, Tan, Wen-Jun, Wang, Chen-Wei, Zhang, Peng, Wang, Ping, Cai, Ce, Xiao, Shuo, Huang, Yue, Feng, Pei-Yi, Li, Xiao-Bo, Song, Li-Ming, Yi, Qi-Bin, Zhao, Yi, Guo, Zhi-Wei, He, Jian-Jian, Li, Chao-Yang, Liu, Ya-Qing, Gong, Ke, Du, Yan-Qi, Liu, Xiao-Jing, Xie, Sheng-Lun, Zhao, Guo-Ying, Zhao, Xiao-Yun, Zhang, Xiao-Lu, Zhang, Zhen, Zheng, Shi-Jie, Wang, Jin, Wen, Xiang-Yang, An, Zheng-Hua, Zhang, Da-Li, Gao, Min, Sun, Xi-Lei, Liang, Xiao-Hua, Yang, Sheng, Wang, Jin-Zhou, Chen, Gang, and Zhang, Fan

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - High Energy Astrophysical Phenomena

Abstract

The gamma-ray detectors (GRDs) of GECAM-C onborad SATech-01 satellite is designed to monitor gamma-ray transients all over the sky from 6 keV to 6 MeV. The energy response matrix is the key to do spectral measurements of bursts, which is usually generated from GEANT4 simulation and partially verified by the ground calibration. In this work, energy response matrix of GECAM-C GRD is cross-calibrated with Fermi/GBM and Swift/BAT using a sample of Gamma-Ray Bursts (GRBs) and Soft Gamma-Ray Repeaters (SGRs). The calibration results show there is a good agreement between GECAM-C and other reasonably well calibrated instrument (i.e. Fermi/GBM and Swift/BAT). We also find that different GRD detectors of GECAM-C also show consistency with each other. All these results indicate that GECAM-C GRD can provide reliable spectral measurements., Comment: preliminary version, will be updated soon

Published

2023

30. Ground calibration of Gamma-Ray Detectors of GECAM-C

Author

Zheng, Chao, An, Zheng-Hua, Peng, Wen-Xi, Zhang, Da-Li, Xiong, Shao-Lin, Qiao, Rui., Zhang, Yan-Qiu, Xue, Wang-Chen, Liu, Jia-Cong, Feng, Pei-Yi, Cai, Ce., Gao, Min, Gong, Ke, Guo, Dong-Ya, Hou, Dong-Jie, Li, Gang, Li, Xin-Qiao, Li, Yan-Guo, Li, Mao-Shun, Liang, Xiao-Hua, Liu, Ya-Qing, Liu, Xiao-Jing, Song, Li-Ming, Sun, Xi-Lei, Tan, Wen-Jun, Wang, Chen-Wei, Wang, Hui, Wang, Jin-Zhou, Wen, Xiang-Yang, Xiao, Shuo, Xu, Yan-Bing, Yang, Sheng, Yi, Qi-Bing, Zhang, Fan, Zhang, Peng, Zhang, Zhen, Zhao, Yi, and Zhou, Xing

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Physics - Instrumentation and Detectors

Abstract

As a new member of GECAM mission, GECAM-C (also named High Energy Burst Searcher, HEBS) was launched onboard the SATech-01 satellite on July 27th, 2022, which is capable to monitor gamma-ray transients from $\sim$ 6 keV to 6 MeV. As the main detector, there are 12 gamma-ray detectors (GRDs) equipped for GECAM-C. In order to verify the GECAM-C GRD detector performance and to validate the Monte Carlo simulations of detector response, comprehensive on-ground calibration experiments have been performed using X-ray beam and radioactive sources, including Energy-Channel relation, energy resolution, detection efficiency, SiPM voltage-gain relation and the non-uniformity of positional response. In this paper, the detailed calibration campaigns and data analysis results for GECAM-C GRDs are presented, demonstrating the excellent performance of GECAM-C GRD detectors., Comment: third version

Published

2023

31. GECAM Localization of High Energy Transients and the Systematic Error

Author

Zhao, Yi, Xue, Wang-Chen, Xiong, Shao-Lin, Wang, Yuan-Hao, Liu, Jia-Cong, Liuo, Qi, Zhang, Yan-Qiu, Sun, Jian-Chao, Zhao, Xiao-Yun, Cai, Ce, Xiao, Shuo, Huang, Yue, Li, Xiao-Bo, Zhang, Zhen, Liao, Jin-Yuan, Yang, Sheng, Qiao, Rui, Guo, Dong-Ya, Zheng, Chao, Yi, Qi-Bin, Xie, Sheng-Lun, Guo, Zhi-Wei, Li, Chao-Yang, Wang, Chen-Wei, Tan, Wen-Jun, Wang, Yue, Peng, Wen-Xi, Zheng, Shi-Jie, He, Jian-Jian, Wang, Ping, Wang, Jin, Ma, Xiang, Song, Xin-Ying, Zhang, Hong-Mei, Li, Bing, Zhang, Peng, Wu, Hong, Du, Yan-Qi, Liang, Jing, Zhao, Guo-Ying, Li, Xin-Qiao, Wen, Xiang-Yang, An, Zheng-Hua, Sun, Xi-Lei, Xu, Yan-Bing, Zhang, Fan, Zhang, Da-Li, Gong, Ke, Liu, Ya-Qing, Liang, Xiao-Hua, Liu, Xiao-Jing, Gao, Min, Wang, Jin-Zhou, Song, Li-Ming, Chen, Gang, Zhang, Ke-Ke, Han, Xing-Bo, Wu, Hai-Yan, Hu, Tai, Geng, Hao, Lu, Fang-Jun, Zhang, Shu, Zhang, Shuang-Nan, Lu, Gao-Peng, Zeng, Ming, and Yu, Heng

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - High Energy Astrophysical Phenomena

Abstract

Gravitational wave high-energy Electromagnetic Counterpart All-sky Monitor (GECAM) is a pair of microsatellites (i.e. GECAM-A and GECAM-B) dedicated to monitoring gamma-ray transients including gravitational waves high-energy electromagnetic counterparts, Gamma-ray Bursts, Soft Gamma-ray Repeaters, Solar Flares and Terrestrial Gamma-ray Flashes. Since launch in December 2020, GECAM-B has detected hundreds of astronomical and terrestrial events. For these bursts, localization is the key for burst identification and classification as well as follow-up observations in multi-wavelength. Here, we propose a Bayesian localization method with Poisson data with Gaussian background profile likelihood to localize GECAM bursts based on the burst counts distribution in detectors with different orientations. We demonstrate that this method can work well for all kinds of bursts, especially for extremely short ones. In addition, we propose a new method to estimate the systematic error of localization based on a confidence level test, which can overcome some problems of the existing method in literature. We validate this method by Monte Carlo simulations, and then apply it to a burst sample with accurate location and find that the mean value of the systematic error of GECAM-B localization is $\sim 2.5^{\circ}$. By considering this systematic error, we can obtain a reliable localization probability map for GECAM bursts. Our methods can be applied to other gamma-ray monitors., Comment: The paper has been accepted by Astrophysical Journal Supplement Series

Published

2022

32. High-resolution neutronics model for 238Pu production in high-flux reactors

Author

Pan, Qing-Quan, Zhao, Qing-Fei, Wang, Lian-Jie, Xia, Bang-Yang, Cai, Yun, Xiong, Jin-Biao, and Liu, Xiao-Jing

Published

2024

33. An efficient parallel algorithm of variational nodal method for heterogeneous neutron transport problems

Author

Yin, Han, Liu, Xiao-Jing, and Zhang, Teng-Fei

Published

2024

34. Reducing the risk of unfavourable fractures in Le Fort III osteotomy via a navigation-guided technique

Author

Wang, Yu-ting, Liu, Yue, Ye, Guo-hua, Xu, Tao, Zhang, Yi, and Liu, Xiao-jing

Published

2024

35. Clinical analysis of Le Fort III distraction for obstructive sleep apnea in pediatric patients with syndromic craniosynostosis

Author

Liu, Yue, Xu, Tao, Zhang, Yi, and Liu, Xiao-jing

Published

2024

36. A cytoplasm-applicative aggregation-induced fluorescent probe for detecting hydrogen sulfide and imaging study

Author

Guo, Meng-Ya, Liu, Xiao-Jing, Zhang, Xiao, Yang, Yu-Shun, Sun, Wen-Xue, Xu, Chen, and Zhu, Hai-Liang

Published

2024

37. Reaction mechanism for NH3-SCR of NOx over CrMn1.5O4 catalyst

Author

Yuan, Zheng-nan, Guo, Rui-tang, Liu, Xiao-jing, Xu, Yi-feng, Liu, Lu, and Pan, Wei-guo

Published

2024

38. Core-shell structured Cu2O@NiAl-LDH/CQDs photocatalysts for efficient photocatalytic reduction of CO2 to C2 products

Author

Guo, Sheng-hui, Guo, Rui-tang, Zhang, Zhen-rui, Yu, Ling-qi, Yan, Ji-song, Liu, Hao, Pan, Wei-guo, and Liu, Xiao-jing

Published

2025

39. The In-Flight Realtime Trigger and Localization Software of GECAM

Author

Zhao, Xiao-Yun, Xiong, Shao-Lin, Wen, Xiang-Yang, Li, Xin-Qiao, Cai, Ce, Xiao, Shuo, Luo, Qi, Peng, Wen-Xi, Guo, Dong-Ya, An, Zheng-Hua, Gong, Ke, Liao, Jin-Yuan, Zhang, Yan-Qiu, Huang, Yue, Li, Lu, Wen, Xing, Zhang, Fei, Duan, Jing, Wang, Chen-Wei, Shi, Dong-Li, Zhang, Peng, Yi, Qi-Bin, Li, Chao-Yang, Xu, Yan-Bing, Liang, Xiao-Hua, Liu, Ya-Qing, Zhang, Da-Li, Sun, Xi-Lei, Zhang, Fan, Chen, Gang, Wang, Huan-Yu, Yang, Sheng, Liu, Xiao-Jing, Gao, Min, Li, Mao-Shun, Wang, Jin-Zhou, Zhou, Xing, Zhao, Yi, Xue, Wang-Chen, Zheng, Chao, Liu, Jia-Cong, Han, Xing-Bo, Qi, Jin-Ling, Huang, Jia, Zhang, Ke-Ke, Chen, Can, Yang, Xiong-Tao, Hou, Dong-Jie, Wang, Yu-Sa, Qiao, Rui, Ma, Xiang, Li, Xiao-Bo, Wang, Ping, Song, Xin-Ying, Song, Li-Ming, Zheng, Shi-Jie, Li, Bing, Zhang, Hong-Mei, Zhu, Yue, Chen, Wei, He, Jian-Jian, Zhang, Zhen, Hou, Jin, Wang, Hong-Jun, Hao, Yan-Chao, Wang, Xiang-Yu, Yang, Zong-Yuan, Wen, Zhi-Long, Chang, Zhi, Du, Yuan-Yuan, Gao, Rui, Lan, Xiao-Fei, Li, Yan-Guo, Li, Gang, Li, Xu-Fang, Lu, Fang-Jun, Lu, Hong, Meng, Bin, Shi, Feng, Wang, Hui, Wang, Hui-Zhen, Xu, Yu-Peng, Yang, Jia-Wei, Yang, Xue-Juan, Zhang, Shuang-Nan, Zhang, Chao-Yue, Zhang, Cheng-Mo, Tang, Zhi-Cheng, and Cheng, Cheng

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Realtime trigger and localization of bursts are the key functions of GECAM, which is an all-sky gamma-ray monitor launched in Dec 10, 2020. We developed a multifunctional trigger and localization software operating on the CPU of the GECAM electronic box (EBOX). This onboard software has the following features: high trigger efficiency for real celestial bursts with a suppression of false triggers caused by charged particle bursts and background fluctuation, dedicated localization algorithm optimized for short and long bursts respetively, short time latency of the trigger information which is downlinked throught the BeiDou satellite navigation System (BDS). This paper presents the detailed design and deveopment of this trigger and localization software system of GECAM, including the main functions, general design, workflow and algorithms, as well as the verification and demonstration of this software, including the on-ground trigger tests with simulated gamma-ray bursts made by a dedicated X-ray tube and the in-flight performance to real gamma-ray bursts and magnetar bursts., Comment: Draft, comments welcome

Published

2021

40. The energy response of LaBr33(Ce), LaBr33(Ce,Sr), and NaI(Tl) crystals for GECAM

Author

Feng, Pei-Yi, Sun, Xi-Lei, An, Zheng-Hua, Deng, Yong, Wang, Cheng-Er, Jiang, Huang, Li, Jun-Jie, Zhang, Da-Li, Li, Xin-Qiao, Xiong, Shao-Lin, Zheng, Chao, Gong, Ke, Yang, Sheng, Liu, Xiao-Jing, Gao, Min, Wen, Xiang-Yang, liu, Ya-Qing, Xu, Yan-Bing, Zhao, Xiao-Yun, Liu, Jia-Cong, Zhang, Fan, and Lu, Hong

Published

2024

41. Insight-HXMT on-orbit thermal control status and thermal deformation impact analysis

Author

Zhang, Ai-Mei, Zhang, Yi-Fan, Liao, Jin-Yuan, Xu, Yu-Peng, Wang, Yu-Sa, Luo, Wen-Bo, Zhou, Yu-Peng, Qian, Zhi-Ying, Li, Xiao-Bo, Lu, Fang-Jun, Zhang, Shuang-Nan, Song, Li-Ming, Liu, Cong-Zhan, Zhang, Fan, Nie, Jian-Yin, Wang, Juan, Yang, Sheng, Zhang, Tong, Liu, Xiao-Jing, Wang, Rui-Jie, Li, Xu-Fang, Zhang, Yi-Fei, Li, Zheng-Wei, Lu, Xue-Feng, Xu, He, and Wu, Di

Published

2023

42. Synergistic multifactor influence and management of commercial vanadium-based catalyst lifetimes

Author

Xu, Yi-feng, Liu, Xiao-jing, Guo, Rui-tang, Wu, Tong, Ding, Hong-lei, Ye, Dong, and Pan, Wei-guo

Published

2024

43. Unexpected offsetting effect of Na and HCl deactivation over CeO2-MoO3 catalyst for NO reduction

Author

You, Yi-hao, Ye, Dong, Guo, Rui-tang, Liu, Xiao-jing, Wu, Tong, and Pan, Wei-guo

Published

2024

44. A structural optimized fluorescent probe for monitoring hydrogen sulfide in cells and zebrafish

Author

Guo, Meng-Ya, Li, Yun-Zhang, Liu, Xiao-Jing, Wang, Bao-Zhong, Yang, Yu-Shun, and Zhu, Hai-Liang

Published

2024

45. Ground calibration of Gamma-Ray Detectors of GECAM-C

Author

Zheng, Chao, An, Zheng-Hua, Peng, Wen-Xi, Zhang, Da-Li, Xiong, Shao-Lin, Qiao, Rui, Zhang, Yan-Qiu, Xue, Wang-Chen, Liu, Jia-Cong, Feng, Pei-Yi, Cai, Ce, Gao, Min, Gong, Ke, Guo, Dong-Ya, Hou, Dong-Jie, Li, Gang, Li, Xin-Qiao, Li, Yan-Guo, Li, Mao-Shun, Liang, Xiao-Hua, Liu, Ya-Qing, Liu, Xiao-Jing, Song, Li-Ming, Sun, Xi-Lei, Tan, Wen-Jun, Wang, Chen-Wei, Wang, Hui, Wang, Jin-Zhou, Wen, Xiang-Yang, Xiao, Shuo, Xu, Yan-Bing, Yang, Sheng, Yi, Qi-Bing, Zhang, Fan, Zhang, Peng, Zhang, Zhen, Zhao, Yi, and Zhou, Xing

Published

2024

46. Timing analysis of the black hole candidate EXO 1846-031 with Insight-HXMT monitoring

Author

Liu, He-Xin, Huang, Yue, Xiao, Guang-Cheng, Bu, Qing-Cui, Qu, Jin-Lu, Zhang, Shu, Zhang, Shuang-Nan, Jia, Shu-Mei, Lu, Fang-Jun, Ma, Xiang, Tao, Lian, Zhang, Wei, Chen, Li, Song, Li-Ming, Li, Ti-Pei, Xu, Yu-Peng, Cao, Xue-Lei, Chen, Yong, Liu, Cong-Zhan, Cai, Ce, Chang, Zhi, Chen, Gang, Chen, Tian-Xiang, Chen, Yi-Bao, Chen, Yu-Peng, Cui, Wei, Cui, Wei-Wei, Deng, Jing-Kang, Dong, Yong-Wei, Du, Yuan-Yuan, Fu, Min-Xue, Gao, Guan-Hua, Gao, He, Gao, Min, Ge, Ming-Yu, Gu, Yu-Dong, Guan, Ju, Guo, Cheng-Cheng, Han, Da-Wei, Huo, Jia, Jiang, Lu-Hua, Jiang, Wei-Chun, Jin, Jing, Jin, Yong-Jie, Kong, Ling-Da, Li, Bing, Li, Cheng-Kui, Li, Gang, Li, Mao-Shun, Li, Wei, Li, Xian, Li, Xiao-Bo, Li, Xu-Fang, Li, Yang-Guo, Li, Zheng-Wei, Liang, Xiao-Hua, Liao, Jing-Yuan, Liu, Bai-Sheng, Liu, Guo-Qing, Liu, Hong-Wei, Liu, Xiao-Jing, Liu, Yi-Nong, Lu, Bo, Lu, Xue-Feng, Luo, Qi, Luo, Tao, Meng, Bin, Nang, Yi, Nie, Jian-Yin, Ou, Ge, Sai, Na, Shang, Ren-Cheng, Song, Xin-Ying, Sun, Liang, Tan, Ying, Tuo, You-Li, Wang, Chen, Wang, Guo-Feng, Wang, Juan, Wang, Ling-Jun, Wang, Weng-Shuai, Wang, Yu-Sa., Wen, Xiang-Yang, Wu, Bai-Yang, Wu, Bo-Bing, Wu, Mei, Xiao, Shuo, Xiong, Shao-Lin, Xu, He, Yang, Jia-Wei, Yang, Sheng, Yang, Yan-Ji, Yang, Yi-Jung, Yi, Qi-Bin, Yin, Qian-Qing, You, Yuan, Zhang, Ai-Mei, Zhang, Cheng-Mo, Zhang, Fan, Zhang, Hong-Mei, Zhang, Juan, Zhang, Tong, Zhang, Wan-Chang, Zhang, Wen-Zhao, Yi-Zhang, Zhang, Yi-Fei, Zhang, Yong-Jie, Zhang, Yuan-Hang, Zhang, Yue, Zhang, Zhao, Zhang, Zhi, Zhang, Zi-Liang, Zhao, Hai-Sheng, Zhao, Xiao-Fan, Zheng, Shi-Jie, Zheng, Yao-Guang, Zhou, Deng-Ke, Zhou, Jian-Feng, Zhu, Yu-Xuan, Zhuang, Ren-Lin, and Zhu, Yue

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

We present the observational results from a detailed timing analysis of the black hole candidate EXO 1846-031 during its outburst in 2019 with the observations of Insight-HXMT, NICER and MAXI. This outburst can be classfied roughly into four different states. Type-C quasi-periodic oscillations (QPOs) observed by NICER (about 0.1-6Hz) and Insight-HXMT (about 0.7-8Hz) are also reported in this work. Meanwhile, we study various physical quantities related to QPO frequency.The QPO rms-frequency relationship in three energy band 1-10 keV indicates that there is a turning pointing in frequency around 2 Hz,which is similar to that of GRS 1915+105. A possible hypothesis for the relationship above may be related to the inclination of the source, which may require a high inclination to explain it. The relationships between QPO frequency and QPO rms,hardness,total fractional rms and count rate have also been found in other transient sources, which can indicate that the origin of type-C QPOs is non-thermal.

Published

2020

47. Discovery of oscillations above 200 keV in a black hole X-ray binary with Insight-HXMT

Author

Ma, Xiang, Tao, Lian, Zhang, Shuang-Nan, Zhang, Liang, Bu, Qing-Cui, Ge, Ming-Yu, Chen, Yu-Peng, Qu, Jin-Lu, Zhang, Shu, Lu, Fang-Jun, Song, Li-Ming, Yang, Yi-Jung, Yuan, Feng, Cai, Ce, Cao, Xue-Lei, Chang, Zhi, Chen, Gang, Chen, Li, Chen, Tian-Xiang, Chen, Yi-Bao, Chen, Yong, Cui, Wei, Cui, Wei-Wei, Deng, Jing-Kang, Dong, Yong-Wei, Du, Yuan-Yuan, Fu, Min-Xue, Gao, Guan-Hua, Gao, He, Gao, Min, Gu, Yu-Dong, Guan, Ju, Guo, Cheng-Cheng, Han, Da-Wei, Huang, Yue, Huo, Jia, Ji, Long, Jia, Shu-Mei, Jiang, Lu-Hua, Jiang, Wei-Chun, Jin, Jing, Jin, Yong-Jie, Kong, Ling-Da, Li, Bing, Li, Cheng-Kui, Li, Gang, Li, Mao-Shun, Li, Ti-Pei, Li, Wei, Li, Xian, Li, Xiao-Bo, Li, Xu-Fang, Li, Yan-Guo, Li, Zheng-Wei, Liang, Xiao-Hua, Liao, Jin-Yuan, Liu, Bai-Sheng, Liu, Cong-Zhan, Liu, Guo-Qing, Liu, Hong-Wei, Liu, Xiao-Jing, Liu, Yi-Nong, Lu, Bo, Lu, Xue-Feng, Luo, Qi, Luo, Tao, Meng, Bin, Nang, Yi, Nie, Jian-Yin, Ou, Ge, Sai, Na, Shang, Ren-Cheng, Song, Xin-Ying, Sun, Liang, Tan, Ying, Tuo, Yuo-Li, Wang, Chen, Wang, Guo-Feng, Wang, Juan, Wang, Ling-Jun, Wang, Wen-Shuai, Wang, Yu-Sa, Wen, Xiang-Yang, Wu, Bai-Yang, Wu, Bo-Bing, Wu, Mei, Xiao, Guang-Cheng, Xiao, Shuo, Xie, Fu-Guo, Xiong, Shao-Lin, Xu, He, Xu, Yu-Peng, Yang, Jia-Wei, Yang, Sheng, Yang, Yan-Ji, Yi, Qi-Bin, Yin, Qian-Qing, You, Yuan, Zhang, Ai-Mei, Zhang, Cheng-Mo, Zhang, Fan, Zhang, Hong-Mei, Zhang, Juan, Zhang, Tong, Zhang, Wan-Chang, Zhang, Wei, Zhang, Wen-Zhao, Zhang, Yi, Zhang, Yi-Fei, Zhang, Yong-Jie, Zhang, Yue, Zhang, Zhao, Zhang, Zhi, Zhang, Zi-Liang, Zhao, Hai-Sheng, Zhao, Xiao-Fan, Zheng, Shi-Jie, Zhou, Deng-Ke, Zhou, Jian-Feng, Zhu, Yu-Xuan, Zhu, Yue, and Zhuang, Ren-Lin

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

Low-frequency quasi-periodic oscillations (LFQPOs) are commonly found in black hole X-ray binaries, and their origin is still under debate. The properties of LFQPOs at high energies (above 30 keV) are closely related to the nature of the accretion flow in the innermost regions, and thus play a crucial role in critically testing various theoretical models. The Hard X-ray Modulation Telescope (Insight-HXMT) is capable of detecting emissions above 30 keV, and is therefore an ideal instrument to do so. Here we report the discovery of LFQPOs above 200 keV in the new black hole MAXI J1820+070 in the X-ray hard state, which allows us to understand the behaviours of LFQPOs at hundreds of kiloelectronvolts. The phase lag of the LFQPO is constant around zero below 30 keV, and becomes a soft lag (that is, the high-energy photons arrive first) above 30 keV. The soft lag gradually increases with energy and reaches ~0.9s in the 150-200 keV band. The detection at energies above 200 keV, the large soft lag and the energy-related behaviors of the LFQPO pose a great challenge for most currently existing models, but suggest that the LFQPO probably originates from the precession of a small-scale jet., Comment: 36 pages, 12 figures, 3 tables; published in Nature Astronomy

Published

2020

48. The Background Model of the Medium Energy X-ray telescope of Insight-HXMT

Author

Guo, Cheng-Cheng, Liao, Jin-Yuan, Zhang, Shu, Zhang, Juan, Tan, Ying, Song, Li-Ming, Lu, Fang-Jun, Cao, Xue-Lei, Chang, Zhi, Chen, Yu-Peng, Du, Yuan-Yuan, Ge, Ming-Yu, Gu, Yu-Dong, Jiang, Wei-Chun, Li, Gang, Li, Xian, Li, Xiao-Bo, Liu, Shao-Zhen, Liu, Xiao-Jing, Lu, Xue-Feng, Luo, Tao, Meng, Bin, Sun, Liang, Yang, Jia-Wei, Yang, Sheng, You, Yuan, Zhang, Wan-Chang, Zhao, Hai-Sheng, and Zhang, Shuang-Nan

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - High Energy Astrophysical Phenomena

Abstract

The Medium Energy X-ray Telescope (ME) is one of the main payloads of the Hard X-ray Modulation Telescope (dubbed as Insight-HXMT). The background of Insight-HXMT/ME is mainly caused by the environmental charged particles and the background intensity is modulated remarkably by the geomagnetic field, as well as the geographical location. At the same geographical location, the background spectral shape is stable but the intensity varies with the level of the environmental charged particles. In this paper, we develop a model to estimate the ME background based on the ME database that is established with the two-year blank sky observations of the high Galactic latitude. In this model, the entire geographical area covered by Insight-HXMT is divided into grids of $5^{\circ}\times5^{\circ}$ in geographical coordinate system. For each grid, the background spectral shape can be obtained from the background database and the intensity can be corrected by the contemporary count rate of the blind FOV detectors. Thus the background spectrum can be obtained by accumulating the background of all the grids passed by Insight-HXMT during the effective observational time. The model test with the blank sky observations shows that the systematic error of the background estimation in $8.9-44.0$ keV is $\sim1.3\%$ for a pointing observation with an average exposure $\sim5.5$ ks. We also find that the systematic error is anti-correlated with the exposure, which indicates the systematic error is partly contributed by the statistical error of count rate measured by the blind FOV detectors., Comment: to be published in Journal of High Energy Astrophysics

Published

2020

49. Subclinical left ventricular deformation and microvascular dysfunction in T2DM patients with and without peripheral neuropathy: assessed by 3.0 T cardiac magnetic resonance imaging

Author

Li, Xue-Ming, Shi, Rui, Shen, Meng-Ting, Yan, Wei-Feng, Jiang, Li, Min, Chen-Yan, Liu, Xiao-Jing, Guo, Ying-Kun, and Yang, Zhi-Gang

Published

2023

50. METTL3 facilitates immunosurveillance by inhibiting YTHDF2-mediated NLRC5 mRNA degradation in endometrial cancer

Author

Zhan, Lei, Zhang, Jing, Zhang, Jun-Hui, Liu, Xiao-Jing, Guo, Bao, Chen, Jia-Hua, Tang, Zhen-Hai, Wang, Wen-Yan, Wang, Qing-Yuan, Wei, Bing, and Cao, Yun-Xia

Published

2023