Your search keyword '"Liu, Cong-Zhan"' showing total 119 results

1. Observation of GRB 221009A early afterglow in X/$\gamma$-ray energy band

Author

Zheng, Chao, Zhang, Yan-Qiu, Xiong, Shao-Lin, Li, Cheng-Kui, Gao, He, Xue, Wang-Chen, Liu, Jia-Cong, Wang, Chen-Wei, Tan, Wen-Jun, Peng, Wen-Xi, An, Zheng-Hua, Cai, Ce, Ge, Ming-Yu, Guo, Dong-Ya, Huang, Yue, Li, Bing, Li, Ti-Pei, Li, Xiao-Bo, Li, Xin-Qiao, Li, Xu-Fang, Liao, Jin-Yuan, Liu, Cong-Zhan, Lu, Fang-Jun, Ma, Xiang, Qiao, Rui, Song, Li-Ming, Wang, Jin, Wang, Ping, Wang, Xi-Lu, Wang, Yue, Wen, Xiang-Yang, Xiao, Shuo, Xu, Yan-Bing, Xu, Yu-Peng, Yao, Zhi-Guo, Yi, Qi-Bing, Yi, Shu-Xu, You, Yuan, Zhang, Fan, Zhang, Jin-Peng, Zhang, Peng, Zhang, Shu, Zhang, Shuang-Nan, Zhang, Yan-Ting, Zhang, Zhen, Zhao, Xiao-Yun, Zhao, Yi, and Zheng, Shi-Jie

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

The early afterglow of a Gamma-ray burst (GRB) can provide critical information on the jet and progenitor of the GRB. The extreme brightness of GRB 221009A allows us to probe its early afterglow in unprecedented detail. In this letter, we report comprehensive observation results of the early afterglow of GRB 221009A (from $T_0$+660 s to $T_0$+1860 s, where $T_0$ is the \textit{Insight}-HXMT/HE trigger time) in X/$\gamma$-ray energy band (from 20 keV to 20 MeV) by \textit{Insight}-HXMT/HE, GECAM-C and \textit{Fermi}/GBM. We find that the spectrum of the early afterglow in 20 keV-20 MeV could be well described by a cutoff power-law with an extra power-law which dominates the low and high energy bands respectively. The cutoff power-law $E_{\rm peak}$ is $\sim$ 30 keV and the power-law photon index is $\sim$ 1.8 throughout the early afterglow phase. By fitting the light curves in different energy bands, we find that a significant achromatic break (from keV to TeV) is required at $T_0$ + 1246$^{+27}_{-26}$ s (i.e. 1021 s since the afterglow starting time $T_{\rm AG}$=$T_0$+225 s), providing compelling evidence of a jet break. Interestingly, both the pre-break and post-break decay slopes vary with energy, and these two slopes become closer in the lower energy band, making the break less identifiable. Intriguingly, the spectrum of the early afterglow experienced a slight hardening before the break and a softening after the break. These results provide new insights into the understanding of this remarkable GRB., Comment: Accepted for publication in ApJ Letters on 19-Jan-2024, 11 pages, 7 figures and 2 tables

Published

2023

2. A spectral-timing study of the inner flow geometry in MAXI J1535--571 with $Insight$-HXMT and NICER

Author

Yu, Wei, Bu, Qing-Cui, Liu, He-Xin, Huang, Yue, Zhang, Liang, Yang, Zi-Xu, Qu, Jin-Lu, Zhang, Shu, Song, Li-Ming, Zhang, Shuang-Nan, Jia, Shu-Mei, Ma, Xiang, Tao, Lian, Ge, Ming-Yu, Liu, Qing-Zhong, Yan, Jing-Zhi, Cao, Xue-Lei, Chang, Zhi, Chen, Li, Chen, Yong, Chen, Yu-Peng, Ding, Guo-Qiang, Guan, Ju, Jin, Jing, Kong, Ling-Da, Li, Bing, Li, Cheng-Kui, Li, Ti-Pei, Li, Xiao-Bo, Liao, Jin-Yuan, Liu, Bai-Sheng, Liu, Cong-Zhan, Lu, Fang-Jun, Ma, Rui-Can, Nie, Jian-Yin, Ren, Xiao-Qin, Sai, Na, Tan, Ying, Tuo, You-Li, Wang, Ling-Jun, Wang, Peng-Ju, Wu, Bai-Yang, Xiao, Guang-Cheng, Yin, Qian-Qing, You, Yuan, Zhang, Juan, Zhang, Peng, Zhang, Wei, Zhao, Hai-Sheng, Zheng, Shi-Jie, and Zhou, Deng-Ke

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

We have performed a spectral-timing analysis on the black hole X-ray binary MAXI J1535--571 during its 2017 outburst, with the aim of exploring the evolution of the inner accretion flow geometry. X-ray reverberation lags are observed in the hard-intermediate state (HIMS) and soft-intermediate state (SIMS) of the outburst. During the HIMS, the characteristic frequency of the reverberation lags $\nu_0$ (the frequency at which the soft lag turns to zero in the lag-frequency spectra) increases when the spectrum softens. This reflects a reduction of the spatial distance between the corona and accretion disc, when assuming the measured time lags are associated with the light travel time. We also find a strong correlation between $\nu_0$ and type-C Quasi Periodic Oscillation (QPO) centroid frequency $\nu_{QPO}$, which can be well explained by the Lense-Thirring (L-T) precession model under a truncated disk geometry. Despite the degeneracy in the spectral modellings, our results suggest that the accretion disc is largely truncated in the low hard state (LHS), and moves inward as the spectrum softens. Combine the spectral modelling results with the $\nu_0$ - $\nu_{QPO}$ evolution, we are inclined to believe that this source probably have a truncated disk geometry in the hard state.

Published

2023

3. Discovery of the linear energy-dependence of the spectral lag of X-ray bursts from SGR J1935+2154

Author

Xiao, Shuo, Tuo, You-Li, Zhang, Shuang-Nan, Xiong, Shao-Lin, Lin, Lin, Zhang, Yan-Qiu, Wang, Yue, Xue, Wang-Chen, Cai, Ce, Gao, He, Li, Cheng-Kui, Li, Xiao-Bo, Zheng, Chao, Liu, Jia-Cong, Wang, Ping, Wang, Jin, Peng, Wen-Xi, Liu, Cong Zhan, Li, Xin-Qiao, Wen, Xiang-Yang, An, Zheng-Hua, Song, Li-Ming, Zheng, Shi-Jie, Zhang, Fan, Dong, Ai-Jun, Xie, Wei, Feng, Jian-Chao, Ma, Qing-Bo, Wang, De-Hua, Luo, Xi-Hong, Dang, Shi-Jun, Shang, Lun-Hua, Zhi, Qi-Jun, and Li, Ti-Pei

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

Spectral lag of the low-energy photons with respect to the high-energy ones is a common astrophysical phenomenon (such as Gamma-ray bursts and the Crab pulsar) and may serve as a key probe to the underlying radiation mechanism. However, spectral lag in keV range of the magnetar bursts has not been systematically studied yet. In this work, we perform a detailed spectral lag analysis with the Li-CCF method for SGR J1935+2154 bursts observed by {\it Insight}-HXMT, GECAM and Fermi/GBM from July 2014 to Jan 2022. We discover that the spectral lags of about 61\% (non-zero significance >1$\sigma$) bursts from SGR J1935+2154 are linearly dependent on the photon energy ($E$) with $t_{\rm lag}(E)=\alpha (E/{\rm keV})+C$, which may be explained by a linear change of the temperature of the blackbody-emitting plasma with time. The distribution of the slope ($\alpha$) approximately follows a Gaussian function with mean and standard deviation of 0.02 ms/keV (i.e. high-energy photons arrive earlier) and 0.02 ms/keV, respectively. We also find that the distribution can be well fitted with three Gaussians with mean values of $\sim$ -0.009, 0.013 and 0.039 ms/keV, which may correspond to different origins of the bursts. These spectral lag features may have important implications on the magnetar bursts., Comment: accepted for publication in MNRAS

Published

2023

4. Forecasts of CMB lensing reconstruction of AliCPT-1 from the foreground cleaned polarization data

Author

Han, Jiakang, Hu, Bin, Ghosh, Shamik, Li, Siyu, Dou, Jiazheng, Delabrouille, Jacques, Jin, Jing, Li, Hong, Liu, Yang, Remazeilles, Mathieu, Zhao, Wen, Zhang, Pengjie, Li, Zheng-Wei, Liu, Cong-Zhan, Zhang, Yong-jie, Kuo, Chao-Lin, and Zhang, Xinmin

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

Cosmic microwave background radiation (CMB) observations are unavoidably contaminated by emission from various extra-galactic foregrounds, which must be removed to obtain reliable measurements of the cosmological signal. In this paper, we demonstrate CMB lensing reconstruction in AliCPT-1 after foreground removal, combine the two bands of AliCPT-1 (90 and 150~GHz) with Planck HFI bands (100, 143, 217 and 353~GHz) and with the WMAP-K band (23~GHz). In order to balance contamination by instrumental noise and foreground residual bias, we adopt the Needlet Internal Linear Combination (NILC) method to clean the E-map and the constrained Internal Linear Combination (cILC) method to clean the B-map. The latter utilizes additional constraints on average frequency scaling of the dust and synchrotron to remove foregrounds at the expense of somewhat noisier maps. Assuming 4 modules observing 1 season from simulation data, the resulting effective residual noise in E- and B-map are roughly $15~\mu{\rm K}\cdot{\rm arcmin}$ and $25~\mu{\rm K}\cdot{\rm arcmin}$, respectively. As a result, the CMB lensing reconstruction signal-to-noise ratio (SNR) from polarization data is about SNR$\,\approx\,$4.5. This lensing reconstruction capability is comparable to that of other stage-III small aperture millimeter CMB telescopes., Comment: 12 pages, 6 figures

Published

2023

5. 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

6. Five-year in-orbit background of Insight-HXMT

Author

Liao, Jin-Yuan, Zhang, Shu, Zhang, Juan, Li, Gang, Chang, Zhi, Chen, Yu-Peng, Ge, Ming-Yu, Jin, Jing, Lu, Xue-Feng, You, Yuan, Cao, Xue-Lei, Chen, Yong, Huang, Yue, Jiang, Wei-Chun, Li, Xiao-Bo, Li, Xu-Fang, Li, Zheng-Wei, Liu, Cong-Zhan, Tan, Ying, Yang, Yan-Ji, Zhang, Yi-Fei, Zhao, Hai-Sheng, Lu, Fang-Jun, Xu, Yu-Peng, Qu, Jin-Lu, Song, Li-Ming, and Zhang, Shuang-Nan

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Purpose: We present the five-year in-orbit background evolution of Insight-HXMT since the launch, as well as the effects of the background model in data analysis. Methods: The backgrounds of the three main payloads, i.e., Low-Energy Telescope, Medium-Energy Telescope and High-Energy Telescope, are described, respectively. The evolution of the background over time is obtained by simply comparing the background in every year during the in-orbit operation of Insight-HXMT. Results: The major observational characteristics of the Insight-HXMT in-orbit background are presented, including the light curve, spectrum, geographical distribution, and long-term evolution. The systematic error in background estimation is investigated for every year. Conclusion: The observational characteristics of the five-year in-orbit background are consistent with our knowledge of the satellite design and the space environment, and the background model is still valid for the latest observations of Insight-HXMT., Comment: 22 pages, 25 figures, accepted for publication in RDTM

Published

2023

7. In-orbit performance of HE onboard Insight-HXMT in the first 5 years

Author

Li, Xu-Fang, Liu, Cong-Zhan, Zhang, Yi-Fei, Li, Xiao-Bo, Li, Zheng-Wei, Lu, Xue-Feng, Chang, Zhi, Ge, Ming-Yu, Zhang, Juan, Xu, Yu-Peng, Lu, Fang-Jun, Song, Li-Ming, and Zhang, Shuang-Nan

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

Purpose: The High-Energy X-ray telescope (HE), one of the three main payloads of the \textit{Insight}-HXMT mission, is composed of eighteen NaI(Tl)/CsI(Na) phoswich detectors, where NaI(Tl) serves as the primary detector covering 20--250\,keV, and CsI(Na) is used as an active shield detector to suppress the background of NaI(Tl) and also serves as an all-sky gamma-ray burst monitor covering 0.2--3\,MeV. In this paper, we review the in-orbit performance of HE in the first 5 years since \textit{Insight}-HXMT was launched on June 15, 2017. Methods: The major performances we concern include the gain and energy resolution of NaI(Tl) and CsI(Na) detectors, the performance of pulse-shape-discriminator (PSD) and system dead-time. In this work, we investigate these performances mainly using the data of blank-sky observations and the data when the telescope in earth occultation. Results: The overall performance of HE/NaI(Tl) is very stable in the first 5 years, whereas the gain of HE/CsI(Na) shows a continuously increasing trend and should be calibrated regularly. Conclusion: In general, HE is still in good health and well-calibrated status after five-year's operation. The in-orbit performance of HE has no significant deviation from expectation. HE is expected to be in operation healthily for another several years of extended mission life., Comment: 19 pages, 16 figures, Accepted by Insight-HXMT special issue on RDTM

Published

2023

8. Insight-HXMT discovery of the highest energy CRSF from the first Galactic ultra-luminous X-ray pulsar Swift J0243.6+6124

Author

Kong, Ling-Da, Zhang, Shu, Zhang, Shuang-Nan, Ji, Long, Doroshenko, Victor, Santangelo, Andrea, Chen, Yu-Peng, Lu, Fang-Jun, Ge, Ming-Yu, Wang, Peng-Ju, Tao, Lian, Qu, Jin-Lu, Li, Ti-Pei, Liu, Cong-Zhan, Liao, Jin-Yuan, Chang, Zhi, Peng, Jing-Qiang, and Shui, Qing-Cang

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

The detection of cyclotron resonance scattering features (CRSFs) is the only way to directly and reliably measure the magnetic field near the surface of a neutron star (NS). The broad energy coverage and large collection area of \emph{Insight}-HXMT in the hard X-ray band allowed us to detect the CRSF with the highest energy known to date, reaching about 146 keV during the 2017 outburst of the first galactic pulsing ultraluminous X-ray source (pULX) Swift J0243.6+6124. During this outburst, the CRSF was only prominent close to the peak luminosity $\sim 2\times10^{39}$ erg s$^{-1}$, the highest to date in any of the Galactic pulsars. The CRSF is most significant in the spin phase region corresponding to the main pulse of the pulse profile, and its centroid energy evolves with phase from 120 to 146 keV. We identify this feature as the fundamental CRSF, since no spectral feature exists at $60-70$ keV. This is the first unambiguous detection of an electron CRSF from an ULX. We also estimate a surface magnetic field $\sim1.6\times10^{13}$ G for Swift J0243.6+6124. Considering that the dipole magnetic field strengths, inferred from several independent estimates of magnetosphere radius, are at least an order of magnitude lower than our measurement, we argue that the detection of the highest energy CRSF reported here unambiguously proves the presence of multipole field components close to the surface of the neutron star. Such a scenario has previously been suggested for several pulsating ULXs, including Swift J0243.6+6124, and our result represents the first direct confirmation of this scenario., Comment: Accepted for publication in ApJL

Published

2022

9. The Peculiar Precursor of a Gamma-Ray Burst from a Binary Merger Involving a Magnetar

Author

Xiao, Shuo, Zhang, Yan-Qiu, Zhu, Zi-Pei, Xiong, Shao-Lin, Gao, He, Xu, Dong, Zhang, Shuang-Nan, Peng, Wen-Xi, Li, Xiao-Bo, Zhang, Peng, Lu, Fang-Jun, Lin, Lin, Liu, Liang-Duan, Zhang, Zhen, Ge, Ming-Yu, Tuo, You-Li, Xue, Wang-Chen, Fu, Shao-Yu, Liu, Xing, Liu, Jin-Zhong, Li, An, Wang, Tian-Cong, Zheng, Chao, Wang, Yue, Jiang, Shuai-Qing, Li, Jin-Da, Liu, Jia-Cong, Cao, Zhou-Jian, Luo, Xi-Hong, Yang, Jiao-Jiao, Yi, Shu-Xu, Wang, Xi-Lu, Cai, Ce, Yi, Qi-Bin, Zhao, Yi, Xie, Sheng-Lun, Li, Cheng-Kui, Luo, Qi, Song, Li-Ming, Zhang, Shu, Qu, Jin-Lu, Liu, Cong-Zhan, Li, Xu-Fang, Xu, Yu-Peng, and Li, Ti-Pei

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

The milestone discovery of GW 170817-GRB 170817A-AT 2017gfo has shown that gravitational wave (GW) could be produced during the merger of neutron star-neutron star/black hole and that in electromagnetic (EM) wave a gamma-ray burst (GRB) and a kilonova (KN) are generated in sequence after the merger. Observationally, however, EM property before the merger phase is still unclear. Here we report a peculiar precursor in a KN-associated long-duration GRB 211211A, providing evidence of the EM before the merger. This precursor lasts $\sim$ 0.2 s, and the waiting time between the precursor and the main burst is $\sim$ 1 s, comparable to that between GW 170817 and GRB 170817A. The spectrum of the precursor could be well fit with a non-thermal cutoff power-law model instead of a blackbody. Especially, a $\sim$22 Hz Quasi-Periodic Oscillation candidate ($\sim 3\sigma$) is detected in the precursor. These temporal and spectral properties indicate that this precursor is probably produced by a catastrophic flare accompanying with magnetoelastic or crustal oscillations of a magnetar in binary compact merger. The strong magnetic field of the magnetar can also account for the prolonged duration of GRB 211211A. However, it poses a challenge to reconcile the rather short lifetime of a magnetar with the rather long spiraling time of a binary neutron star system only by the GW radiation before merger., Comment: Published by ApJ. 13 pages, 11 figures

Published

2022

10. The First Insight-HXMT Gamma-Ray Burst Catalog: The First Four Years

Author

Song, Xin-Ying, Xiong, Shao-Lin, Zhang, Shuang-Nan, Li, Cheng-Kui, Li, Xiao-Bo, Huang, Yue, Guidorzi, Cristiano, Frontera, Filippo, Liu, Cong-Zhan, Li, Xu-Fang, Li, Gang, Liao, Jin-Yuan, Cai, Ce, Luo, Qi, Xiao, Shuo, Yi, Qi-Bin, Zheng, Yao-Guang, Zhou, Deng-Ke, Liu, Jia-Cong, Xue, Wang-Chen, Zhang, Yan-Qiu, Zheng, Chao, Chang, Zhi, Li, Zheng-Wei, Lu, Xue-Feng, Zhang, Ai-Mei, Zhang, Yi-Fei, Jin, Yong-Jie, Li, Ti-Pei, Lu, Fang-Jun, Song, Li-Ming, Wu, Mei, Xu, Yu-Peng, Ma, Xiang, Ge, Ming-Yu, Jia, Shu-Mei, Li, Bing, Nie, Jian-Yin, Wang, Ling-Jun, Zhang, Juan, Zheng, Shi-Jie, Yang, Xue-Juan, and Yang, Rong-Jia

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

The Hard X-ray Modulation Telescope (Insight-HXMT), is China's first X-ray astronomy satellite launched on June 15, 2017. The anti-coincidence CsI detectors of the High Energy X-ray telescope (HE) onboard Insight-HXMT could serve as an all-sky gamma-ray monitor in about 0.2-3 MeV. In its first four years of operation, Insight-HXMT has detected 322 Gamma-Ray Bursts (GRBs) by offline search pipeline including blind search and targeted search. For the GOLDEN sample of Insight-HXMT GRBs, joint analyses were performed with other GRB missions, including Fermi Gamma-ray Burst Monitor (Fermi/GBM), Swift Burst Alert Telescope (Swift/BAT) and Gravitational wave high-energy Electromagnetic Counterpart All-sky Monitor (GECAM). It shows that Insight-HXMT can provide better constraint on GRB spectrum at higher energy band. The properties of Insight-HXMT GRBs are reported in detail, including their trigger time, duration, spectral parameters, peak fluxes of different time scales and fluence. This catalog is an official product of the Insight-HXMT GRB team., Comment: 46 pages, 22 figures, accepted by APJS

Published

2022

11. 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

12. Long-term evolution of the X-ray flux of the Crab pulsar

Author

Zhao, Hai-Sheng, Ge, Ming-Yu, Li, Xiao-Bo, Yan, Lin-Li, Tuo, You-Li, Lu, Fang-Jun, Song, Li-Ming, Liu, Cong-Zhan, Zhang, Shu, and Zhang, Shuang-Nan

Published

2023

13. GRB 200415A: A Short Gamma-Ray Burst from a Magnetar Giant Flare?

Author

Yang, Jun, Chand, Vikas, Zhang, Bin-Bin, Yang, Yu-Han, Zou, Jin-Hang, Yang, Yi-Si, Zhao, Xiao-Hong, Shao, Lang, Xiong, Shao-Lin, Luo, Qi, Li, Xiao-Bo, Xiao, Shuo, Li, Cheng-Kui, Liu, Cong-Zhan, Joshi, Jagdish C., Sharma, Vidushi, Chakraborty, Manoneeta, Li, Ye, and Zhang, Bing

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

The giant flares of soft gamma-ray repeaters (SGRs) have long been proposed to contribute to at least a subsample of the observed short gamma-ray bursts (GRBs). In this paper, we perform a comprehensive analysis of the high-energy data of the recent bright short GRB 200415A, which was located close to the Sculptor galaxy. Our results suggest that a magnetar giant flare provides the most natural explanation for most observational properties of GRB 200415A, including its location, temporal and spectral features, energy, statistical correlations, and high-energy emissions. On the other hand, the compact star merger GRB model is found to have difficulty reproducing such an event in a nearby distance. Future detections and follow-up observations of similar events are essential to firmly establish the connection between SGR giant flares and a subsample of nearby short GRBs., Comment: ApJ published in August 2020 (Yang et al. 2020, ApJ, 899, 106)

Published

2020

14. 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

15. 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

16. Background Model for the High-Energy Telescope of Insight-HXMT

Author

Liao, Jin-Yuan, Zhang, Shu, Lu, Xue-Feng, Zhang, Juan, Li, Gang, Chang, Zhi, Chen, Yu-Peng, Ge, Ming-Yu, Guo, Cheng-Cheng, Huang, Rui, Jin, Jing, Li, Xiao-Bo, Li, Xu-Fang, Li, Zheng-Wei, Liu, Cong-Zhan, Lu, Fang-Jun, Nie, Jian-Yin, Song, Li-Ming, Wang, Si-Fan, You, Yuan, Zhang, Yi-Fei, Zhao, Hai-Sheng, and Zhang, Shuang-Nan

Subjects

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

Abstract

Accurate background estimation is essential for spectral and temporal analysis in astrophysics. In this work, we construct the in-orbit background model for the High-Energy Telescope (HE) of the Hard X-ray Modulation Telescope (dubbed as Insight-HXMT). Based on the two-year blank sky observations of Insight-HXMT/HE, we first investigate the basic properties of the background and find that both the background spectral shape and intensity have long-term evolution at different geographical sites. The entire earth globe is then divided into small grids, each with a typical area of 5x5 square degrees in geographical coordinate system. For each grid, an empirical function is used to describe the long-term evolution of each channel of the background spectrum; the intensity of the background can be variable and a modification factor is introduced to account for this variability by measuring the contemporary flux of the blind detector. For a given pointing observation, the background model is accomplished by integrating over the grids that are passed by the track of the satellite in each orbit. Such a background model is tested with both the blank sky observations and campaigns for observations of a series of celestial sources. The results show an average systematic error of 1.5% for the background energy spectrum (26-100 keV) under a typical exposure of 8 ks, and <3% for background light curve estimation (30-150 keV). Therefore, the background model introduced in this paper is included in the Insight-HXMT software as a standard part specialized for both spectral and temporal analyses., Comment: 27 pages, 16 figures, accepted by Journal of High Energy Astrophysics

Published

2020

17. Calibration of the Instrumental Response of Insight-HXMT/HE CsI Detectors for Gamma-Ray Monitoring

Author

Luo, Qi, Liao, Jin-Yuan, Li, Xu-Fang, Li, Gang, Zhang, Juan, Liu, Cong-Zhan, Li, Xiao-Bo, Zhu, Yue, Li, Cheng-Kui, Huang, Yue, Ge, Ming-Yu, Xu, Yu-Peng, Li, Zheng-Wei, Cai, Ce, Xiao, Shuo, Yi, Qi-Bin, Zhang, Yi-Fei, Xiong, Shao-Lin, Zhang, Shu, and Zhang, Shuang-Nan

Subjects

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

Abstract

The CsI detectors of the High Energy X-ray Telescope of the Hard X-ray Modulation Telescope (HXMT/CsI) can be used for gamma-ray all sky monitoring and searching for the electromagnetic counterpart of gravitational wave source. The instrumental responses are mainly obtained by Monte Carlo simulation with the Geant4 tool and the mass model of both the satellite and all the payloads, which is updated and tested with the Crab pulse emission in various incident directions. Both the Energy-Channel relationship and the energy resolution are calibrated in two working modes (Normal-Gain mode & Low-Gain Mode) with the different detection energy ranges. The simulative spectral analyses show that HXMT/CsI can constrain the spectral parameters much better in the high energy band than that in the low energy band. The joint spectral analyses are performed to ten bright GRBs observed simultaneously with HXMT/CsI and other instruments (Fermi/GBM, Swift/BAT, Konus-Wind), and the results show that the GRB flux given by HXMT/CsI is systematically higher by $7.0\pm8.8\%$ than those given by the other instruments. The HXMT/CsI-Fermi/GBM joint fittings also show that the high energy spectral parameter can be constrained much better as the HXMT/CsI data are used in the joint fittings., Comment: 22 pages, 17 figures, 4 tables, accepted by Journal of High Energy Astrophysics

Published

2020

18. Studies on the time response distribution of Insigh}-HXMT/LE

Author

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

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The Hard X-ray Modulation Telescope (HXMT) named Insight is China's first X-ray astronomical satellite. The Low Energy X-ray Telescope (LE) is one of its main payloads onboard. The detectors of LE adopt swept charge device CCD236 with L-shaped transfer electrodes. Charges in detection area are read out continuously along specific paths, which leads to a time response distribution of photons readout time. We designed a long exposure readout mode to measure the time response distribution. In this mode, CCD236 firstly performs exposure without readout, then all charges generated in preceding exposure phase are read out completely. Through analysis of the photons readout time in this mode, we obtained the probability distribution of photons readout time.

Published

2019

19. The GeV emission of PSR B1259-63 during its last three periastron passages observed by Fermi-LAT

Author

Chang, Zhi, Zhang, Shu, Chen, Yu-Peng, Ji, Long, Kong, Ling-Da, and Liu, Cong-Zhan

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

PSR B1259-63 is a $\gamma$-ray emitting high mass X-ray binary system, in which the compact object is a millisecond pulsar. The system has an orbital period of 1236.7 d and shows peculiar $\gamma$-ray flares when the neutron star moves out of the stellar disk of the companion star. The $\gamma$-ray flare events were firstly discovered by using Fermi-LAT around the 2010 periastron passage, which was repeated for the 2014 and 2017 periastron passages. We analyze the Fermi-LAT data for all the three periastron passages and found that in each flare the energy spectrum can be represented well by a simple power law. The $\gamma$-ray light curves show that in 2010 and 2014 after each periastron there are two main flares, but in 2017 there are four flares including one precursor about 10 d after the periastron passage. The first main flares in 2010 and 2014 are located at around 35 d after the periastron passage, and the main flare in 2014 is delayed by roughly 1.7 d with respect to that in 2010. In the 2017 flare, the source shows a precursor about 10 d after the periastron passage, but the following two flares become weaker and lag behind those in 2010 by roughly 5 d. The strongest flares in 2017 occurred 58 d and 70 d after the periastron passage. These results challenge the previous models., Comment: 8 pages, 3 figures, accepted for publication in RAA

Published

2018

20. Probing Primordial Gravitational Waves: Ali CMB Polarization Telescope

Author

Li, Hong, Li, Si-Yu, Liu, Yang, Li, Yong-Ping, Cai, Yifu, Li, Mingzhe, Zhao, Gong-Bo, Liu, Cong-Zhan, Li, Zheng-Wei, Xu, He, Wu, Di, Zhang, Yong-Jie, Fan, Zu-Hui, Yao, Yong-Qiang, Kuo, Chao-Lin, Lu, Fang-Jun, and Zhang, Xinmin

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, General Relativity and Quantum Cosmology, High Energy Physics - Experiment, High Energy Physics - Phenomenology

Abstract

In this paper, we will give a general introduction to the project of Ali CMB Polarization Telescope (AliCPT), which is a Sino-US joint project led by the Institute of High Energy Physics (IHEP) and has involved many different institutes in China. It is the first ground-based Cosmic Microwave Background (CMB) polarization experiment in China and an integral part of China's Gravitational Waves Program. The main scientific goal of AliCPT project is to probe the primordial gravitational waves (PGWs) originated from the very early Universe. The AliCPT project includes two stages. The first stage referred to as AliCPT-1, is to build a telescope in the Ali region of Tibet with an altitude of 5,250 meters. Once completed, it will be the worldwide highest ground-based CMB observatory and open a new window for probing PGWs in northern hemisphere. AliCPT-1 telescope is designed to have about 7,000 TES detectors at 90GHz and 150GHz. The second stage is to have a more sensitive telescope (AliCPT-2) with the number of detectors more than 20,000. Our simulations show that AliCPT will improve the current constraint on the tensor-to-scalar ratio $r$ by one order of magnitude with 3 years' observation. Besides the PGWs, the AliCPT will also enable a precise measurement on the CMB rotation angle and provide a precise test on the CPT symmetry. We show 3 years' observation will improve the current limit by two order of magnitude., Comment: 11 pages, 7 figures, 2 tables

Published

2017

21. Temporal and spectral characteristics of persistent emission and special bursts of Magnetar SGR J1935+2154 based on Insight-HXMT

Author

Lu, Xuefeng, primary, Song, Liming, additional, Ge, Mingyu, additional, Zhang, Shuangnan, additional, Qu, Jin-Lu, additional, Cai, Ce, additional, Liu, Cong-Zhan, additional, Li, Chengkui, additional, Fu, Yucong, additional, and Xu, Yingchen, additional

Published

2024

22. A study of raining influence on the environmental radiation background spectra with HXMT/HE

Author

Li, Xu-Fang, Liu, Cong-Zhan, Zhang, Yi-Fei, Li, Zheng-Wei, Lu, Xue-Feng, Zhao, Jian-Ling, Zou, Chang-Lin, Xu, Yu-Peng, and Lu, Fang-Jun

Subjects

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

Abstract

Full functional and performance tests were performed many times before the Hard X-ray Modulation Telescope (HXMT) launch. During one of the tests, the count rate curves of the 18 High Energy Detectors (HED) have been found increased consistently within an interval of time. A further study on the correlation between the count rate and rainfall was carried out,and the increased net spectrum was also analyzed. The analysis results indicate that the short-lived 222Rn decay products (214Pb and 214Bi) in rainwater were responsible for the transient changes of the background radiation spectra in HEDs. The results show that the HXMT/HEDs have a good detection sensitivity on X/gamma rays, and the detector calibration results are effective., Comment: 6 pages,6 figures (2subplot in fig.2), submitted to Chinese Physics C

Published

2016

23. Study on temperature coefficient of CdTe detector used for X-rays detection

Author

Guo, Si-Ming, Wu, Jin-Jie, Zhang, Jian, Li, Xu-Fang, Liu, Cong-Zhan, Zhang, Shuai, Li, Cheng-Ze, Huo, Bin-Bin, and Liao, Zhen-Yu

Subjects

Physics - Instrumentation and Detectors

Abstract

The temperature of the working environment is a key factor in determining the properties of semiconductor detectors, and it affects the absolute accuracy and stability of the standard detector. In order to determine the temperature coefficient of CdTe detector used for X-rays detection, a precise temperature control system was designed. In this experiment, detectors and radiographic source were set inside the thermostat with temperature of 0-40 Celsius degree, so that the temperature can be regulated for the test of the temperature coefficient of CdTe detector. Studies had shown that, with the increase of the temperature, the energy resolution and detection efficiency of the CdTe detector would deteriorate, and under 10 Celsius degree the detectors have better performance with the 8 keV X-rays., Comment: 8 pages, 7 figures

Published

2016

24. Confirming the spin parameter of the black hole in Cygnus X-1 using the Insight-HXMT

Author

Zhao, Xue-Shan, Dong, Yan-Ting, Gou, Li-Jun, Feng, Ye, Jia, Nan, Li, Yu-Feng, Liao, Zhen-Xuan, Liu, Ji-Ren, Zheng, Xue-Ying, Zhang, Shuang-Nan, Qu, Jin-Lu, Song, Li-Ming, Zhang, Shu, Bu, Qing-Cui, Cai, Ce, Cao, Xue-Lei, Chang, Zhi, Chen, Gang, Chen, Li, Chen, Tian-Xiang, Chen, Yi-Bao, Chen, Yong, 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, Huang, Yue, Huo, Jia, 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, He-Xin, Liu, Hong-Wei, Liu, Xiao-Jing, Liu, Yi-Nong, Lu, Bo, Lu, Fang-Jun, Lu, Xue-Feng, Luo, Qi, Luo, Tao, Ma, Xiang, Meng, Bin, Nang, Yi, Nie, Jian-Yin, Ou, Ge, Sai, Na, Shang, Ren-Cheng, Song, Xin-Ying, Sun, Liang, Tan, Ying, Tao, Lian, Tuo, You-Li, Wang, Chen, Wang, Guo-Feng, Wang, Juan, Wang, Wen-Shuai, Wang, Yu-Sa, Wen, Xiang-Yang, Wu, Bai-Yang, Wu, Bo-Bing, Wu, Mei, Xiao, Guang-Cheng, Xiao, Shuo, Xiong, Shao-Lin, Xu, Yu-Peng, Yang, Jia-Wei, Yang, Sheng, Yang, Yan-Ji, Yang, Yi-Rong, 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, Yue-Zhu, and Zhuang, Ren-Lin

Published

2020

25. Observation of GRB 221009A Early Afterglow in X-Ray/Gamma-Ray Energy Bands

Author

Zheng, Chao, primary, Zhang, Yan-Qiu, additional, Xiong, Shao-Lin, additional, Li, Cheng-Kui, additional, Gao, He, additional, Xue, Wang-Chen, additional, Liu, Jia-Cong, additional, Wang, Chen-Wei, additional, Tan, Wen-Jun, additional, Peng, Wen-Xi, additional, An, Zheng-Hua, additional, Cai, Ce, additional, Ge, Ming-Yu, additional, Guo, Dong-Ya, additional, Huang, Yue, additional, Li, Bing, additional, Li, Ti-Pei, additional, Li, Xiao-Bo, additional, Li, Xin-Qiao, additional, Li, Xu-Fang, additional, Liao, Jin-Yuan, additional, Liu, Cong-Zhan, additional, Lu, Fang-Jun, additional, Ma, Xiang, additional, Qiao, Rui, additional, Song, Li-Ming, additional, Wang, Jin, additional, Wang, Ping, additional, Wang, Xi-Lu, additional, Wang, Yue, additional, Wen, Xiang-Yang, additional, Xiao, Shuo, additional, Xu, Yan-Bing, additional, Xu, Yu-Peng, additional, Yao, Zhi-Guo, additional, Yi, Qi-Bing, additional, Yi, Shu-Xu, additional, You, Yuan, additional, Zhang, Fan, additional, Zhang, Jin-Peng, additional, Zhang, Peng, additional, Zhang, Shu, additional, Zhang, Shuang-Nan, additional, Zhang, Yan-Ting, additional, Zhang, Zhen, additional, Zhao, Xiao-Yun, additional, Zhao, Yi, additional, and Zheng, Shi-Jie, additional

Published

2024

26. 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

Published

2021

27. Design and implementation of the NaI (Tl)CsI (Na) detectors output signal generator

Author

Zhou, Xu, Liu, Cong-Zhan, Zhao, Jian-Ling, Zhang, Fei, Zhang, Yi-Fei, Li, Zheng-Wei, Zhang, Shuo, Li, Xu-Fang, Lu, Xue-Feng, Xu, Zhen-Ling, and Lu, Fang-Jun

Subjects

High Energy Physics - Experiment, Physics - Instrumentation and Detectors

Abstract

We designed and implemented a signal generator that can simulate the output of the NaI (Tl)CsI (Na) detectors pre amplifier onboard the Hard X ray Modulation Telescope (HXMT). Using the development of FPGA (Field Programmable Gate Array) with VHDL language and adding random constituent, we have finally produced the double exponential random pulse signal generator. The statistical distribution of signal amplitude is programmable. The occurrence time intervals of adjacent signals content negative exponential distribution statistically., Comment: 5 pages, 11 figures

Published

2013

28. X-Ray Variability Coherence in the Time Domain

Author

Che, Xiao, Liu, Cong-Zhan, and Li, Ti-Pei

Subjects

Astrophysics

Abstract

A technique for calculation of variability coherence at different timescales performed directly in the time domain is introduced. Simulations are made to compare the coherence spectrum derived by the time domain technique with the coherence function by Fourier analysis. The results indicate that in comparison with the Fourier analysis the time domain technique is more powerful for revealing signal coherence in noisy data. We apply the time domain technique to the real data of the black hole binaries Cygnus X-1 and GX 339-4 and compare the results with their Fourier coherence spectra., Comment: To be published in ApJ, 15 pages, 6 figures

Published

2007

29. A Spectral-timing Study of the Inner Flow Geometry in MAXI J1535-571 with Insight-HXMT and NICER

Author

Yu, Wei, primary, Bu, Qing-Cui, additional, Liu, He-Xin, additional, Huang, Yue, additional, Zhang, Liang, additional, Yang, Zi-Xu, additional, Qu, Jin-Lu, additional, Zhang, Shu, additional, Song, Li-Ming, additional, Zhang, Shuang-Nan, additional, Jia, Shu-Mei, additional, Ma, Xiang, additional, Tao, Lian, additional, Ge, Ming-Yu, additional, Liu, Qing-Zhong, additional, Yan, Jing-Zhi, additional, Cao, Xue-Lei, additional, Chang, Zhi, additional, Chen, Li, additional, Chen, Yong, additional, Chen, Yu-Peng, additional, Ding, Guo-Qiang, additional, Guan, Ju, additional, Jin, Jing, additional, Kong, Ling-Da, additional, Li, Bing, additional, Li, Cheng-Kui, additional, Li, Ti-Pei, additional, Li, Xiao-Bo, additional, Liao, Jin-Yuan, additional, Liu, Bai-Sheng, additional, Liu, Cong-Zhan, additional, Lu, Fang-Jun, additional, Ma, Rui-Can, additional, Nie, Jian-Yin, additional, Ren, Xiao-Qin, additional, Sai, Na, additional, Tan, Ying, additional, Tuo, You-Li, additional, Wang, Ling-Jun, additional, Wang, Peng-Ju, additional, Wu, Bai-Yang, additional, Xiao, Guang-Cheng, additional, Yin, Qian-Qing, additional, You, Yuan, additional, Zhang, Juan, additional, Zhang, Peng, additional, Zhang, Wei, additional, Zhao, Hai-Sheng, additional, Zheng, Shi-Jie, additional, and Zhou, Deng-Ke, additional

Published

2023

30. Detecting Primordial Gravitational Waves: a forecast study on optimizing frequency distribution of next generation ground-based CMB telescope

Author

Wu, Deliang, Li, Hong, Ni, Shulei, Li, Zheng-Wei, and Liu, Cong-Zhan

Published

2020

31. Forecasts of CMB lensing reconstruction of AliCPT-1 from the foreground cleaned polarization data

Author

Han, Jiakang, primary, Hu, Bin, additional, Ghosh, Shamik, additional, Li, Siyu, additional, Dou, Jiazheng, additional, Delabrouille, Jacques, additional, Jin, Jing, additional, Li, Hong, additional, Liu, Yang, additional, Remazeilles, Mathieu, additional, Zhao, Wen, additional, Zhang, Pengjie, additional, Li, Zheng-Wei, additional, Liu, Cong-Zhan, additional, Zhang, Yong-jie, additional, Kuo, Chao-Lin, additional, and Zhang, Xinmin, additional

Published

2023

32. Discovery of the linear energy dependence of the spectral lag of X-ray bursts from SGR J1935+2154

Author

Xiao, Shuo, primary, Tuo, You-Li, additional, Zhang, Shuang-Nan, additional, Xiong, Shao-Lin, additional, Lin, Lin, additional, Zhang, Yan-Qiu, additional, Wang, Yue, additional, Xue, Wang-Chen, additional, Cai, Ce, additional, Gao, He, additional, Li, Cheng-Kui, additional, Li, Xiao-Bo, additional, Zheng, Chao, additional, Liu, Jia-Cong, additional, Wang, Ping, additional, Wang, Jin, additional, Peng, Wen-Xi, additional, Liu, Cong-Zhan, additional, Li, Xin-Qiao, additional, Wen, Xiang-Yang, additional, An, Zheng-Hua, additional, Song, Li-Ming, additional, Zheng, Shi-Jie, additional, Zhang, Fan, additional, Dong, Ai-Jun, additional, Xie, Wei, additional, Feng, Jian-Chao, additional, Ma, Qing-Bo, additional, Wang, De-Hua, additional, Luo, Xi-Hong, additional, Dang, Shi-Jun, additional, Shang, Lun-Hua, additional, Zhi, Qi-Jun, additional, and Li, Ti-Pei, additional

Published

2023

33. In-orbit performance of HE onboard Insight-HXMT in the first 5 years

Author

Li, Xu-Fang, primary, Liu, Cong-Zhan, additional, Zhang, Yi-Fei, additional, Li, Xiao-Bo, additional, Li, Zheng-Wei, additional, Lu, Xue-Feng, additional, Chang, Zhi, additional, Ge, Ming-Yu, additional, Zhang, Juan, additional, Xu, Yu-Peng, additional, Lu, Fang-Jun, additional, Song, Li-Ming, additional, and Zhang, Shuang-Nan, additional

Published

2023

34. Five-year in-orbit background of Insight-HXMT

Author

Liao, Jin-Yuan, primary, Zhang, Shu, additional, Zhang, Juan, additional, Li, Gang, additional, Chang, Zhi, additional, Chen, Yu-Peng, additional, Ge, Ming-Yu, additional, Jin, Jing, additional, Lu, Xue-Feng, additional, You, Yuan, additional, Cao, Xue-Lei, additional, Chen, Yong, additional, Huang, Yue, additional, Jiang, Wei-Chun, additional, Li, Xiao-Bo, additional, Li, Xu-Fang, additional, Li, Zheng-Wei, additional, Liu, Cong-Zhan, additional, Tan, Ying, additional, Yang, Yan-Ji, additional, Zhang, Yi-Fei, additional, Zhao, Hai-Sheng, additional, Lu, Fang-Jun, additional, Xu, Yu-Peng, additional, Qu, Jin-Lu, additional, Song, Li-Ming, additional, and Zhang, Shuang-Nan, additional

Published

2023

35. Burst phase distribution of SGR J1935+2154 based on Insight-HXMT

Author

Lu, Xuefeng, primary, Song, Liming, additional, Ge, Mingyu, additional, Tuo, Youli, additional, Zhang, Shuangnan, additional, Qu, Jin-Lu, additional, Cai, Ce, additional, Xie, Sheng-Lun, additional, Liu, Cong-Zhan, additional, Li, Chengkui, additional, Fu, Yucong, additional, xu, yingchen, additional, and li, tianming, additional

Published

2023

36. Insight-HXMT Discovery of the Highest-energy CRSF from the First Galactic Ultraluminous X-Ray Pulsar Swift J0243.6+6124

Author

Kong, Ling-Da, primary, Zhang, Shu, additional, Zhang, Shuang-Nan, additional, Ji, Long, additional, Doroshenko, Victor, additional, Santangelo, Andrea, additional, Chen, Yu-Peng, additional, Lu, Fang-Jun, additional, Ge, Ming-Yu, additional, Wang, Peng-Ju, additional, Tao, Lian, additional, Qu, Jin-Lu, additional, Li, Ti-Pei, additional, Liu, Cong-Zhan, additional, Liao, Jin-Yuan, additional, Chang, Zhi, additional, Peng, Jing-Qiang, additional, and Shui, Qing-Cang, additional

Published

2022

37. The quasi-periodically oscillating precursor of a long gamma-ray burst from a binary neutron star merger

Author

Xiao, Shuo, Zhang, Yan-Qiu, Zhu, Zi-Pei, Xiong, Shao-Lin, Gao, He, Xu, Dong, Zhang, Shuang-Nan, Peng, Wen-Xi, Li, Xiao-Bo, Zhang, Peng, Lu, Fang-Jun, Lin, Lin, Liu, Liang-Duan, Zhang, Zhen, Ge, Ming-Yu, Tuo, You-Li, Xue, Wang-Chen, Fu, Shao-Yu, Liu, Xing, Li, An, Wang, Tian-Cong, Zheng, Chao, Wang, Yue, Jiang, Shuai-Qing, Li, Jin-Da, Liu, Jia-Cong, Cao, Zhou-Jian, Cai, Ce, Yi, Qi-Bin, Zhao, Yi, Xie, Sheng-Lun, Li, Cheng-Kui, Luo, Qi, Liao, Jin-Yuan, Song, Li-Ming, Zhang, Shu, Qu, Jin-Lu, Liu, Cong-Zhan, Li, Xu-Fang, Xu, Yu-Peng, Li, Ti-Pei, Xiao, Shuo, Zhang, Yan-Qiu, Zhu, Zi-Pei, Xiong, Shao-Lin, Gao, He, Xu, Dong, Zhang, Shuang-Nan, Peng, Wen-Xi, Li, Xiao-Bo, Zhang, Peng, Lu, Fang-Jun, Lin, Lin, Liu, Liang-Duan, Zhang, Zhen, Ge, Ming-Yu, Tuo, You-Li, Xue, Wang-Chen, Fu, Shao-Yu, Liu, Xing, Li, An, Wang, Tian-Cong, Zheng, Chao, Wang, Yue, Jiang, Shuai-Qing, Li, Jin-Da, Liu, Jia-Cong, Cao, Zhou-Jian, Cai, Ce, Yi, Qi-Bin, Zhao, Yi, Xie, Sheng-Lun, Li, Cheng-Kui, Luo, Qi, Liao, Jin-Yuan, Song, Li-Ming, Zhang, Shu, Qu, Jin-Lu, Liu, Cong-Zhan, Li, Xu-Fang, Xu, Yu-Peng, and Li, Ti-Pei

Abstract

The milestone of GW 170817-GRB 170817A-AT 2017gfo has shown that gravitational wave (GW) is produced during the merger of neutron star-neutron star/black hole and that in electromagnetic (EM) wave a gamma-ray burst (GRB) and a kilonovae (KN) are generated in sequence after the merger. Observationally, however, EM property during a merger is still unclear. Here we report a peculiar precursor in a KN-associated long GRB 211211A. The duration of the precursor is $\sim$ 0.2 s, and the waiting time between the precursor and the main emission (ME) of the burst is $\sim$ 1 s, which is about the same as the time interval between GW 170817 and GRB 170817A. Quasi-Periodic Oscillations (QPO) with frequency $\sim$22 Hz (at $>5\sigma$ significance) are found throughout the precursor, the first detection of periodic signals from any {\it bona fide} GRBs. This indicates most likely that a magnetar participated in the merger, and the precursor might be produced due to a catastrophic flare accompanying with torsional or crustal oscillations of the magnetar. The strong seed magnetic field of $\sim 10^{14-15}$ G at the surface of the magnetar may also account for the prolonged duration of GRB 211211A. However, it is a challenge to reconcile the rather short lifetime of a magnetar \cite{kaspi2017magnetars} with the rather long spiraling time of a binary neutron star system only by gravitational wave radiation before merger., Comment: 37 pages, 14 figures

Published

2022

38. The First Insight-HXMT Gamma-Ray Burst Catalog: The First Four Years

Author

Song, Xin-Ying, primary, Xiong, Shao-Lin, additional, Zhang, Shuang-Nan, additional, Li, Cheng-Kui, additional, Li, Xiao-Bo, additional, Huang, Yue, additional, Guidorzi, Cristiano, additional, Frontera, Filippo, additional, Liu, Cong-Zhan, additional, Li, Xu-Fang, additional, Li, Gang, additional, Liao, Jin-Yuan, additional, Cai, Ce, additional, Luo, Qi, additional, Xiao, Shuo, additional, Yi, Qi-Bin, additional, Zheng, Yao-Guang, additional, Zhou, Deng-Ke, additional, Liu, Jia-Cong, additional, Xue, Wang-Chen, additional, Zhang, Yan-Qiu, additional, Zheng, Chao, additional, Chang, Zhi, additional, Li, Zheng-Wei, additional, Lu, Xue-Feng, additional, Zhang, Ai-Mei, additional, Zhang, Yi-Fei, additional, Jin, Yong-Jie, additional, Li, Ti-Pei, additional, Lu, Fang-Jun, additional, Song, Li-Ming, additional, Wu, Mei, additional, Xu, Yu-Peng, additional, Ma, Xiang, additional, Ge, Ming-Yu, additional, Jia, Shu-Mei, additional, Li, Bing, additional, Nie, Jian-Yin, additional, Wang, Ling-Jun, additional, Zhang, Juan, additional, Zheng, Shi-Jie, additional, Yang, Xue-Juan, additional, and Yang, Rong-Jia, additional

Published

2022

39. Development of a 70–110 GHz silicon corrugated horn for cosmic microwave background experiment

Author

Feng, Zhao, primary, Li, Jia‐Ning, additional, Li, Zheng‐Wei, additional, Xu, Yu‐Peng, additional, Liu, Cong‐Zhan, additional, Fan, Jin, additional, Shu, Shi‐Bo, additional, Gao, Guan‐Hua, additional, Zhang, Yi‐Fei, additional, Lu, Xue‐Feng, additional, Li, Xu‐Fang, additional, Lu, Fang‐Jun, additional, Zhang, Ai‐Mei, additional, Gu, Yu‐Dong, additional, Xu, Yu, additional, Xu, He, additional, Wu, Di, additional, and Wang, Ying, additional

Published

2021

40. A Parametric Model to Reproduce the Background of the Insight-HXMT/HE Blind Detector

Author

You, Yuan, primary, Liao, Jin-Yuan, additional, Zhang, Shuang-Nan, additional, Zhang, Shu, additional, Lu, Xue-Feng, additional, Zhang, Juan, additional, Li, Gang, additional, Chang, Zhi, additional, Chen, Yu-Peng, additional, Ge, Ming-Yu, additional, Guo, Cheng-Cheng, additional, Huang, Rui, additional, Huang, Yue, additional, Jin, Jing, additional, Li, Xiao-Bo, additional, Li, Xu-Fang, additional, Li, Zheng-Wei, additional, Liu, Cong-Zhan, additional, Lu, Fang-Jun, additional, Nie, Jian-Yin, additional, Song, Li-Ming, additional, Wang, Si-Fan, additional, Zhang, Yi-Fei, additional, and Zhao, Hai-Sheng, additional

Published

2021

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

Author

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

Published

2021

42. Development of a 70–110 GHz silicon corrugated horn for cosmic microwave background experiment.

Author

Feng, Zhao, Li, Jia‐Ning, Li, Zheng‐Wei, Xu, Yu‐Peng, Liu, Cong‐Zhan, Fan, Jin, Shu, Shi‐Bo, Gao, Guan‐Hua, Zhang, Yi‐Fei, Lu, Xue‐Feng, Li, Xu‐Fang, Lu, Fang‐Jun, Zhang, Ai‐Mei, Gu, Yu‐Dong, Xu, Yu, Xu, He, Wu, Di, and Wang, Ying

Subjects

COSMIC background radiation, RECEIVING antennas, ANTENNA arrays, MICROWAVE generation, SEMICONDUCTOR manufacturing, MILLIMETER waves

Abstract

Next generation cosmic microwave background (CMB) polarization telescope will use large arrays of receiver with nearly 100 000 transition edge sensor (TES) detectors and receiving antennas. Such large TES and antenna array is a big challenge for the fabrication of TES and antennas. A 35‐layers silicon‐platelet corrugated horn for 70–110 GHz is designed and fabricated based on the micro electro mechanical system (MEMS) technology. Compared with the traditional corrugated horn, the last layer of the 35‐layers silicon‐platelet is designed with no corrugation to increase the beam symmetry. A parametric HFSS model of the horn was established to evaluate the performance of the horn and effect of fabrication process. The measured S11 and cross‐polarization of the fabricated prototype horn are both below −20 dB while the sidelobe at 70 and 90 GHz is below −20 dB. The beam symmetry of the horn is good in 70–110 GHz band. The measured gain is greater than 15 dBi. These results show that the performance of the designed horn meets the requirement of CMB experiment. [ABSTRACT FROM AUTHOR]

Published

2022

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

Author

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

Published

2020

44. GRB 200415A: A Short Gamma-Ray Burst from a Magnetar Giant Flare?

Author

Yang, Jun, primary, Chand, Vikas, additional, Zhang, Bin-Bin, additional, Yang, Yu-Han, additional, Zou, Jin-Hang, additional, Yang, Yi-Si, additional, Zhao, Xiao-Hong, additional, Shao, Lang, additional, Xiong, Shao-Lin, additional, Luo, Qi, additional, Li, Xiao-Bo, additional, Xiao, Shuo, additional, Li, Cheng-Kui, additional, Liu, Cong-Zhan, additional, Joshi, Jagdish C., additional, Sharma, Vidushi, additional, Chakraborty, Manoneeta, additional, Li, Ye, additional, and Zhang, Bing, additional

Published

2020

45. Calibration of the instrumental response of Insight-HXMT/HE CsI detectors for gamma-ray monitoring

Author

Luo, Qi, primary, Liao, Jin-Yuan, additional, Li, Xu-Fang, additional, Li, Gang, additional, Zhang, Juan, additional, Liu, Cong-Zhan, additional, Li, Xiao-Bo, additional, Zhu, Yue, additional, Li, Cheng-Kui, additional, Huang, Yue, additional, Ge, Ming-Yu, additional, Xu, Yu-Peng, additional, Li, Zheng-Wei, additional, Cai, Ce, additional, Xiao, Shuo, additional, Yi, Qi-Bin, additional, Zhang, Yi-Fei, additional, Xiong, Shao-Lin, additional, Zhang, Shu, additional, and Zhang, Shuang-Nan, additional

Published

2020

46. Background model for the high-energy telescope of Insight-HXMT

Author

Liao, Jin-Yuan, primary, Zhang, Shu, additional, Lu, Xue-Feng, additional, Zhang, Juan, additional, Li, Gang, additional, Chang, Zhi, additional, Chen, Yu-Peng, additional, Ge, Ming-Yu, additional, Guo, Cheng-Cheng, additional, Huang, Rui, additional, Jin, Jing, additional, Li, Xiao-Bo, additional, Li, Xu-Fang, additional, Li, Zheng-Wei, additional, Liu, Cong-Zhan, additional, Lu, Fang-Jun, additional, Nie, Jian-Yin, additional, Song, Li-Ming, additional, Wang, Si-Fan, additional, You, Yuan, additional, Zhang, Yi-Fei, additional, Zhao, Hai-Sheng, additional, and Zhang, Shuang-Nan, additional

Published

2020

47. The GeV emission of PSR B1259–63 during its last three periastron passages observed by Fermi-LAT

Author

Chang, Zhi, primary, Zhang, Shu, additional, Chen, Yu-Peng, additional, Ji, Long, additional, Kong, Ling-Da, additional, and Liu, Cong-Zhan, additional

Published

2018

48. Probing primordial gravitational waves: Ali CMB Polarization Telescope

Author

Li, Hong, primary, Li, Si-Yu, additional, Liu, Yang, additional, Li, Yong-Ping, additional, Cai, Yifu, additional, Li, Mingzhe, additional, Zhao, Gong-Bo, additional, Liu, Cong-Zhan, additional, Li, Zheng-Wei, additional, Xu, He, additional, Wu, Di, additional, Zhang, Yong-Jie, additional, Fan, Zu-Hui, additional, Yao, Yong-Qiang, additional, Kuo, Chao-Lin, additional, Lu, Fang-Jun, additional, and Zhang, Xinmin, additional

Published

2018

49. Probing primordial gravitational waves: Ali CMB Polarization Telescope.

Author

Li, Hong, Li, Si-Yu, Liu, Yang, Li, Yong-Ping, Cai, Yifu, Li, Mingzhe, Zhao, Gong-Bo, Liu, Cong-Zhan, Li, Zheng-Wei, Xu, He, Wu, Di, Zhang, Yong-Jie, Fan, Zu-Hui, Yao, Yong-Qiang, Kuo, Chao-Lin, Lu, Fang-Jun, and Zhang, Xinmin

Subjects

PALEOCLIMATOLOGY, GRAVITATIONAL waves, COSMIC background radiation

Abstract

In this paper, we will give a general introduction to the Ali CMB Polarization Telescope (AliCPT) project, which is a Sino–US joint project led by the Institute of High Energy Physics and involves many different institutes in China. It is the first ground-based Cosmic Microwave Background (CMB) polarization experiment in China and an integral part of China's Gravitational-wave Program. The main scientific goal of the AliCPT project is to probe the primordial gravitational waves (PGWs) originating from the very early Universe. The AliCPT project includes two stages. The first stage, referred to as AliCPT-1, is to build a telescope in the Ali region of Tibet at an altitude of 5250 meters. Once completed, it will be the highest ground-based CMB observatory in the world and will open a new window for probing PGWs in the northern hemisphere. The AliCPT-1 telescope is designed to have about 7000 transition-edge sensor detectors at 95 GHz and 150 GHz. The second stage is to have a more sensitive telescope (AliCPT-2) with more than 20 000 detectors. Our simulations show that AliCPT will improve the current constraint on the tensor-to-scalar ratio r by one order of magnitude with three years' observation. Besides the PGWs, AliCPT will also enable a precise measurement of the CMB rotation angle and provide a precise test of the CPT symmetry. We show that three years' observation will improve the current limit by two orders of magnitude. [ABSTRACT FROM AUTHOR]

Published

2019

50. Design and implementation of the NaI(Tl)/CsI(Na) detectors output signal generator

Author

Zhou, Xu, primary, Liu, Cong-Zhan, additional, Zhao, Jian-Ling, additional, Zhang, Fei, additional, Zhang, Yi-Fei, additional, Li, Zheng-Wei, additional, Zhang, Shuo, additional, Li, Xu-Fang, additional, Lu, Xue-Feng, additional, Xu, Zhen-Ling, additional, and Lu, Fang-Jun, additional

Published

2014