Your search keyword '"Jin, Y. J."' showing total 282 results

1. Wavelet analysis of low-frequency quasi-periodic oscillations in MAXI J1803$-$298 observed with Insight-HXMT and NICER

Author

Jin, Y. J., Chen, X., Zhu, H. F., Jiang, Z. J., Zhang, L., and Wang, W.

Subjects

Astrophysics - High Energy Astrophysical Phenomena, Astrophysics - Solar and Stellar Astrophysics

Abstract

With data observed by the Hard X-ray Modulation Telescope (\textit{Insight}-HXMT) and the Neutron star Interior Composition Explorer (\textit {NICER}), we study low-frequency quasi-periodic oscillations (LFQPOs) of the black hole candidate MAXI J1803$-$298 during the 2021 outburst. Based on hardness intensity diagram and difference of the QPOs properties, Type-C and Type-B QPOs are found in the low-hard state and soft intermediate state, respectively. After searching for and classifying QPOs in Fourier domains, we extract the QPO component and study it with wavelet analysis. The QPO and no-QPO time intervals are separated by the confidence level, so that the S-factor, which is defined as the ratio of the QPO time interval to the total length of good time interval, is calculated. We found S-factors decrease with QPOs frequency for Type-C QPOs but stay stable around zero for Type-B QPOs. The relation of S-factor of Type-C QPOs and photon energy, the correlation of S-factor and counts are also studied. Different correlation of S-factor and counts for different energy bands indicates different origins of QPOs in high energy and low energy bands, which may be due to a dual-corona scenario., Comment: 11 pages, 11 figures, 2 tables, MNRAS in press

Published

2024

2. Quasi-periodic oscillations in GX 339-4 during the 2021 Outburst observed with Insight-HXMT

Author

Jin, Y. J., Wang, W., Chen, X., Tian, P. F., Liu, Q., Zhang, P., Wu, H. J., and Sai, N.

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

A new outburst of GX 339$-$4 in 2021 was monitored by the Hard X-ray Modulation Telescope (\textit{Insight}-HXMT). By using the data of \textit{Insight}-HXMT from February to March 2021, we make the X-ray timing analysis of this new outburst. Based on the results of count rates, hardness-intensity diagram (HID) and power density spectrum (PDS), we confirm that the source exhibits spectral transitions from the low-hard state (LHS) to the hard-intermediate state (HIMS). During the transition from the LHS to the HIMS, Low-frequency Quasi-periodic oscillations (LFQPOs) are detected in the PDS. We found that these QPOs are all type-C QPOs with centroid frequencies evolving from $0.1 -0.6$ Hz in the LHS and in the $1 -3$ Hz frequency range in HIMS. The QPO features above 50 keV are reported for the first time in this black hole by \textit{Insight}-HXMT. The QPO rms stays stable with time but decreases with energy at higher energy above $\sim 10$ keV. We also find that the phase lag of the type-C QPO is close to zero in the early outburst stage, but becomes positive as the outburst evolves, with a hard lag of $\sim$ 0.6-1.2 rad in $50 -100 $ keV. The implications of the phase lag in high energy bands and possible physical mechanisms to explain those observations are also discussed., Comment: 15 pages, ApJ in press

Published

2023

3. Insight-HXMT observations of Swift J0243.6+6124: the evolution of RMS pulse fractions at super-Eddington luminosity

Author

Wang, P. J., Kong, L. D., Zhang, S., Chen, Y. P., Zhang, S. N., Qu, J. L., Ji, L., Tao, L., Ge, M. Y., Lu, F. J., Chen, L., Song, L. M., Li, T. P., Xu, Y. P., Cao, X. L., Chen, Y., Liu, C. Z., Bu, Q. C., Cai, C., Chang, Z., Chen, G., Chen, T. X., Chen, Y. B., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Gu, Y. D., Guan, J., Guo, C. C., Han, D. W., Huang, Y., Huo, J., Jia, S. M., Jiang, L. H., Jiang, W. C., Jin, J., Jin, Y. J., Li, B., Li, C. K., Li, G., Li, M. S., Li, W., Li, X., Li, X. B., Li, X. F., Li, Y. G., Li, Z. W., Liang, X. H., Liao, J. Y., Liu, B. S., Liu, G. Q., Liu, H. W., Liu, X. J., Liu, Y. N., Lu, B., Lu, X. F., Luo, Q., Luo, T., Ma, X., Meng, B., Nang, Y., Nie, J. Y., Ou, G., Sai, N., Shang, R. C., Song, X. Y., Sun, L., Tan, Y., Tuo, Y. L., Wang, C., Wang, G. F., Wang, J., Wang, L. J., Wang, W. S., Wang, Y. S., Wen, X. Y., Wu, B. Y., Wu, B. B., Wu, M., Xiao, G. C., Xiao, S., Xiong, S. L., Yang, J. W., Yang, S., Yang, Yan Ji, Yang, Yi Jung, Yi, Q. B., Yin, Q. Q., You, Y., Zhang, A. M., Zhang, C. M., Zhang, F., Zhang, H. M., Zhang, J., Zhang, T., Zhang, W. C., Zhang, W., Zhang, W. Z., Zhang, Y., Zhang, Y. F., Zhang, Y. J., Zhang, Zhao, Zhang, Zhi, Zhang, Z. L., Zhao, H. S., Zhao, X. F., Zheng, S. J., Zheng, Y. G., Zhou, D. K., Zhou, J. F., Zhu, Y. X., Zhu, Y., and Zhuang, R. L.

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

Based on Insight-HXMT data, we report on the pulse fraction evolution during the 2017-2018 outburst of the newly discovered first Galactic ultraluminous X-ray source (ULX) Swift J0243.6+6124. The pulse fractions of 19 observation pairs selected in the rising and fading phases with similar luminosity are investigated. The results show a general trend of the pulse fraction increasing with luminosity and energy at super-critical luminosity. However, the relative strength of the pulsation between each pair evolves strongly with luminosity. The pulse fraction in the rising phase is larger at luminosity below $7.71\times10^{38}$~erg~s$^{-1}$, but smaller at above. A transition luminosity is found to be energy independent. Such a phenomena is firstly confirmed by Insight-HXMT observations and we speculate it may have relation with the radiation pressure dominated accretion disk.

Published

2020

4. Two-dimensional Dirac Semimetals without Inversion Symmetry

Author

Jin, Y. J., Zheng, B. B., Xiao, X. L., Chen, Z. J., Xu, Y., and Xu, H.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Realizing stable two-dimensional (2D) Dirac points against spin-orbit coupling (SOC) has attracted much attention because it provides a platform to study the unique transport properties. In previous work, Young and Kane [Phys. Rev. Lett. \textbf{115}, 126803 (2015)] proposed stable 2D Dirac points with SOC, in which the Berry curvature and edge states vanish due to the coexistence of inversion and time-reversal symmetries. Herein, using the tight-binding model and k$\cdot$p effective Hamiltonian, we present that 2D Dirac points can survive in the presence of SOC without inversion symmetry. Such 2D Dirac semimetals possess nonzero Berry curvature near the crossing nodes, and two edge states are terminated at one pair of Dirac points. In addition, according to symmetry arguments and high-throughput first-principles calculations, we identify a family of ideal 2D Dirac semimetals, which has nonzero Berry curvature in the vicinity of Dirac points and visible edge states, thus facilitating the experimental observations. Our work shows that 2D Dirac points can emerge without inversion symmetry, which not only enriches the classification of 2D topological semimetals but also provides a promising avenue to observe exotic transport phenomena beyond graphene, e.g., nonlinear Hall effect., Comment: 5 pages, 4 figures

Published

2020

5. Insight-HXMT firm detection of the highest energy fundamental cyclotron resonance scattering feature in the spectrum of GRO J1008-57

Author

Ge, M. Y., Ji, L., Zhang, S. N., Santangelo, A., Liu, C. Z., Doroshenko, V., Staubert, R., Qu, J. L., Zhang, S., Lu, F. J., Song, L. M., Li, T. P., Tao, L., Xu, Y. P., Cao, X. L., Chen, Y., Bu, Q. C., Cai, C., Chang, Z., Chen, G., Chen, L., Chen, T. X., Chen, Y. B., Chen, Y. P., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Gu, Y. D., Guan, J., Guo, C. C., Han, D. W., Huang, Y., Huo, J., Jia, S. M., Jiang, L. H., Jiang, W. C., Jin, J., Jin, Y. J., Kong, L. D., Li, B., Li, C. K., Li, G., Li, M. S., Li, W., Li, X., Li, X. B., Li, X. F., Li, Y. G., Li, Z. W., Liang, X. H., Liao, J. Y., Liu, B. S., Liu, G. Q., Liu, H. W., Liu, X. J., Liu, Y. N., Lu, B., Lu, X. F., Luo, Q., Luo, T., Ma, X., Meng, B., Nang, Y., Nie, J. Y., Ou, G., Sai, N., Shang, R. C., Song, X. Y., Sun, L., Tan, Y., Tuo, Y. L., Wang, C., Wang, G. F., Wang, J., Wang, L. J., Wang, W. S., Wang, Y. D., Wang, Y. S., Wen, X. Y., Wu, B. B., Wu, B. Y., Wu, M., Xiao, G. C., Xiao, S., Xiong, S. L., Xu, H., Yang, J. W., Yang, S., Yang, Y. J., Yi, Q. B., Yin, Q. Q., You, Y., Zhang, A. M., Zhang, C. M., Zhang, F., Zhang, H. M., Zhang, J., Zhang, T., Zhang, W. C., Zhang, W., Zhang, W. Z., Zhang, Y., Zhang, Y. F., Zhang, Y. J., Zhang, Z., Zhang, Z. L., Zhao, H. S., Zhao, X. F., Zheng, S. J., Zheng, Y. G., Zhou, D. K., Zhou, J. F., Zhuang, R. L., Zhu, Y. X., and Zhu, Y.

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

We report on the observation of the accreting pulsar GRO J1008-57 performed by Insight-HXMT at the peak of the source's 2017 outburst. Pulsations are detected with a spin period of 93.283(1) s. The pulse profile shows double peaks at soft X-rays, and only one peak above 20 keV. The spectrum is well described by the phenomenological models of X-ray pulsars. A cyclotron resonant scattering feature is detected with very high statistical significance at a centroid energy of $E_{\rm cyc}=90.32_{-0.28}^{+0.32}$ keV, for the reference continuum and line models, HIGHECUT and GABS respectively. Detection is very robust with respect to different continuum models. The line energy is significantly higher than what suggested from previous observations, which provided very marginal evidence for the line. This establishes a new record for the centroid energy of a fundamental cyclotron resonant scattering feature observed in accreting pulsars. We also discuss the accretion regime of the source during the Insight-HXMT observation., Comment: 8 pages, 3 figures, accepted for publication in ApJL

Published

2020

6. HXMT Identification of a non-thermal X-ray burst from SGR J1935+2154 and with FRB 200428

Author

Li, C. K., Lin, L., Xiong, S. L., Ge, M. Y., Li, X. B., Li, T. P., Lu, F. J., Zhang, S. N., Tuo, Y. L., Nang, Y., Zhang, B., Xiao, S., Chen, Y., Song, L. M., Xu, Y. P., Liu, C. Z., Jia, S. M., Cao, X. L., Qu, J. L., Zhang, S., Gu, Y. D., Liao, J. Y., Zhao, X. F., Tan, Y., Nie, J. Y., Zhao, H. S., Zheng, S. J., Zheng, Y. G., Luo, Q., Cai, C., Li, B., Xue, W. C., Bu, Q. C., Chang, Z., Chen, G., Chen, T. X., Chen, Y. B., Chen, Y. P., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Guan, J., Guo, C. C., Han, D. W., Huang, Y., Huo, J., Jiang, L. H., Jiang, W. C., Jin, J., Jin, Y. J., Kong, L. D., Li, G., Li, M. S., Li, W., Li, X., Li, X. F., Li, Y. G., Li, Z. W., Liang, X. H., Liu, B. S., Liu, G. Q., Liu, H. W., Liu, X. J., Liu, Y. N., Lu, B., Lu, X. F., Luo, T., Ma, X., Meng, B., Ou, G., Sai, N., Shang, R. C., Song, X. Y., Sun, L., Tao, L., Wang, C., Wang, G. F., Wang, J., Wang, W. S., Wang, Y. S., Wen, X. Y., Wu, B. B., Wu, B. Y., Wu, M., Xiao, G. C., Xu, H., Yang, J. W., Yang, S., Yang, Y. J., Yang, Yi-Jung, Yi, Q. B., Yin, Q. Q., You, Y., Zhang, A. M., Zhang, C. M., Zhang, F., Zhang, H. M., Zhang, J., Zhang, T., Zhang, W., Zhang, W. C., Zhang, W. Z., Zhang, Y., Zhang, Yue, Zhang, Y. F., Zhang, Y. J., Zhang, Z., Zhang, Zhi, Zhang, Z. L., Zhou, D. K., Zhou, J. F., Zhu, Y., Zhu, Y. X., and Zhuang, R. L.

Subjects

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

Abstract

Fast radio bursts (FRBs) are short pulses observed in radio band from cosmological distances. One class of models invoke soft gamma-ray repeaters (SGRs), or magnetars, as the sources of FRBs. Some radio pulses have been observed from some magnetars, however, no FRB-like events had been detected in association any magnetar burst, including one giant flare. Recently, a pair of FRB-like bursts (FRB 200428 hereafter) separated by milliseconds (ms) were detected from the general direction of the Galactic magnetar SGR J1935+2154. Here we report the detection of a non-thermal X-ray burst in the 1-250 keV energy band with the Insight-HXMT satellite, which we identify as emitted from SGR J1935+2154. The burst showed two hard peaks with a separation of 34 ms, broadly consistent with that of the two bursts in FRB 200428. The delay time between the double radio and X-ray peaks is about 8.57 s, fully consistent with the dispersion delay of FRB 200428. We thus identify the non-thermal X-ray burst is associated with FRB 200428 whose high energy counterpart is the two hard peaks in X-ray. Our results suggest that the non-thermal X-ray burst and FRB 200428 share the same physical origin in an explosive event from SGR J1935+2154., Comment: 24 pages, 9 figures, 6 tables; initial submission to a journal on May 9th, 2020. Significant changes include updated localization and detailed spectral evolution of the X-ray burst, and better determination of the two narrow X-ray peaks corresponding to the two radio pulses. Conclusions are strengthened. Nature Astronomy online on Feb. 18, 2021

Published

2020

7. Insight-HXMT insight into switch of the accretion mode: the case of the X-ray pulsar 4U 1901+03

Author

Tuo, Y. L., Ji, L., Tsygankov, S. S., Mihara, T., Song, L. M., Ge, M. Y., Nabizadeh, A., Tao, L., Qu, J. L., Zhang, Y., Zhang, S., Zhang, S. N., Bu, Q. C., Chen, L., Xu, Y. P., Cao, X. L., Chen, Y., Liu, C. Z., Cai, C., Chang, Z., Chen, G., Chen, T. X., Chen, Y. B., Chen, Y. P., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Gu, Y. D., Guan, J., Guo, C. C., Han, D. W., Huang, Y., Huo, J., Jia, S. M., Jiang, L. H., Jiang, W. C., Jin, J., Jin, Y. J., Kong, L. D., Li, B., Li, C. K., Li, G., Li, M. S., Li, T. P., Li, W., Li, X., Li, X. B., Li, X. F., Li, Y. G., Li, Z. W., Liang, X. H., Liao, J. Y., Liu, B. S., Liu, G. Q., Liu, H. W., Liu, X. J., Liu, Y. N., Lu, B., Lu, F. J., Lu, X. F., Luo, Q., Luo, T., Ma, X., Meng, B., Nang, Y., Nie, J. Y., Ou, G., Sai, N., Shang, R. C., Song, X. Y., Sun, L., Tan, Y., Wang, C., Wang, G. F., Wang, J., Wang, W. S., Wang, Y. S., Wen, X. Y., Wu, B. Y., Wu, B. B., Wu, M., Xiao, G. C., Xiao, S., Xiong, S. L., Yang, J. W., Yang, S., Yang, Y. J., Yi, Q. B., Yin, Q. Q., You, Y., Zhang, A. M., Zhang, C. M., Zhang, F., Zhang, H. M., Zhang, J., Zhang, T., Zhang, W., Zhang, W. C., Zhang, W. Z., Zhang, Y. F., Zhang, Y. J., Zhang, Y. H., Zhang, Z., Zhang, Z. L., Zhao, H. S., Zhao, X. F., Zheng, S. J., Zheng, Y. G., Zhou, D. K., Zhou, J. F., Zhu, Y. X., Zhu, Y., and Zhuang, R. L.

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

We use the In data collected during the 2019 outburst from X-ray pulsar 4U 1901+03 to complement the orbital parameters reported by Fermi/GBM. Using the Insight-HXMT, we examine the correlation between the derivative of the intrinsic spin frequency and bolometric flux based on accretion torque models. It was found that the pulse profiles significantly evolve during the outburst. The existence of two types of the profile's pattern discovered in the Insight-HXMT data indicates that this source experienced transition between a super-critical and a sub-critical accretion regime during its 2019 outburst. Based on the evolution of the pulse profiles and the torque model, we derive the distance to 4U 1901+03 as 12.4+-0.2 kpc., Comment: 8 pages, 5 figures, accepted by JHEAP

Published

2020

8. The evolution of the broadband temporal features observed in the black-hole transient MAXI J1820+070 with Insight-HXMT

Author

Wang, Yanan, Ji, Long, Zhang, S. N., Méndez, Mariano, Qu, J. L., Maggi, Pierre, Ge, M. Y., Qiao, Erlin, Tao, L., Zhang, S., Altamirano, Diego, Zhang, L., Ma, X., Lu, F. J., Li, T. P., Huang, Y., Zheng, S. J., Chen, Y. P., Chang, Z., Tuo, Y. L., Gungor, C., Song, L. M., Xu, Y. P., Cao, X. L., Chen, Y., Liu, C. Z., Bu, Q. C., Cai, C., Chen, G., Chen, L., Chen, T. X., Chen, Y. B., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Gu, Y. D., Guan, J., Guo, C. C., Han, D. W., Huo, J., Jia, S. M., Jiang, L. H., Jiang, W. C., Jin, J., Jin, Y. J., Kong, L. D., Li, B., Li, C. K., Li, G., Li, M. S., Li, W., Li, X., Li, X. B., Li, X. F., Li, Y. G., Li, Z. W., Liang, X. H., Liao, J. Y., Liu, G. Q., Liu, H. W., Liu, X. J., Liu, Y. N., Lu, B., Lu, X. F., Luo, Q., Luo, T., Meng, B., Nang, Y., Nie, J. Y., Ou, G., Sai, N., Shang, R. C., Song, X. Y., Sun, L., Tan, Y., Wang, G. F., Wang, J., Wang, W. S., Wang, Y. D., Wang, Y. S., Wen, X. Y., Wu, B. B., Wu, B. Y., Wu, M., Xiao, G. C., Xiao, S., Xiong, S. L., Yang, J. W., Yang, S., Yang, Y. J., Yi, Q. B., Yin, Q. Q., You, Y., Zhang, A. M., Zhang, C. M., Zhang, F., Zhang, H. M., Zhang, J., Zhang, T., Zhang, W. C., Zhang, W., Zhang, W. Z., Zhang, Y., Zhang, Y. F., Zhang, Y. J., Zhang, Z., Zhang, Z. L., Zhao, H. S., Zhao, X. F., Zhou, D. K., Zhou, J. F., Zhuang, R. L., Zhu, Y. X., and Zhu, Y.

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

We study the evolution of the temporal properties of MAXI 1820+070 during the 2018 outburst in its hard state from MJD 58190 to 58289 with Insight-HXMT in a broad energy band 1-150 keV. We find different behaviors of the hardness ratio, the fractional rms and time lag before and after MJD 58257, suggesting a transition occurred at around this point. The observed time lags between the soft photons in the 1-5 keV band and the hard photons in higher energy bands, up to 150 keV, are frequency-dependent: the time lags in the low-frequency range, 2-10 mHz, are both soft and hard lags with a timescale of dozens of seconds but without a clear trend along the outburst; the time lags in the high-frequency range, 1-10 Hz, are only hard lags with a timescale of tens of milliseconds; first increase until around MJD 58257 and decrease after this date. The high-frequency time lags are significantly correlated to the photon index derived from the fit to the quasi-simultaneous NICER spectrum in the 1-10 keV band. This result is qualitatively consistent with a model in which the high-frequency time lags are produced by Comptonization in a jet., Comment: Accepted for publication in ApJ

Published

2020

9. Discovery of delayed spin-up behavior following two large glitches in the Crab pulsar, and the statistics of such processes

Author

Ge, M. Y., Zhang, S. N., Lu, F. J., Li, T. P., Yuan, J. P., Zheng, X. P., Huang, Y., Zheng, S. J., Chen, Y. P., Chang, Z., Tuo, Y. L., Cheng, Q., Güngör, C., Song, L. M., Xu, Y. P., Cao, X. L., Chen, Y., Liu, C. Z., Zhang, S., Qu, J. L., Bu, Q. C., Cai, C., Chen, G., Chen, L., Chen, M. Z., Chen, T. X., Chen, Y. B., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Gu, Y. D., Guan, J., Guo, C. C., Han, D. W., Hao, L. F., Huo, J., Jia, S. M., Jiang, L. H., Jiang, W. C., Jin, C. J., Jin, J., Jin, Y. J., Kong, L. D., Li, B., Li, D., Li, C. K., Li, G., Li, M. S., Li, W., Li, X., Li, X. B., Li, X. F., Li, Y. G., Li, Z. W., Li, Z. X., Liu, Z. Y., Liang, X. H., Liao, J. Y., Liu, G. Q., Liu, H. W., Liu, X. J., Liu, Y. N., Lu, B., Lu, X. F., Luo, Q., Luo, T., Ma, X., Meng, B., Nang, Y., Nie, J. Y., Ou, G., Sai, N., Shang, R. C., Song, X. Y., Sun, L., Tan, Y., Tao, L., Wang, C., Wang, G. F., Wang, J., Wang, J. B., Wang, M., Wang, N., Wang, W. S., Wang, Y. D., Wang, Y. S., Wen, X. Y., Wen, Z. G., Wu, B. B., Wu, B. Y., Wu, M., Xiao, G. C., Xiao, S., Xiong, S. L., Xu, Y. H., Yan, W. M., Yang, J. W., Yang, S., Yang, Y. J., Yi, Q. B., Yin, Q. Q., You, Y., Yue, Y. L., Zhang, A. M., Zhang, C. M., Zhang, D. P., Zhang, F., Zhang, H. M., Zhang, J., Zhang, T., Zhang, W. C., Zhang, W., Zhang, W. Z., Zhang, Y., Zhang, Y. F., Zhang, Y. J., Zhang, Z., Zhang, Z. L., Zhao, H. S., Zhao, X. F., Zheng, W., Zhou, D. K., Zhou, J. F., Zhou, X., Zhuang, R. L., Zhu, Y. X., and Zhu, Y.

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

Glitches correspond to sudden jumps of rotation frequency ($\nu$) and its derivative ($\dot{\nu}$) of pulsars, the origin of which remains not well understood yet, partly because the jump processes of most glitches are not well time-resolved. There are three large glitches of the Crab pulsar, detected in 1989, 1996 and 2017, which were found to have delayed spin-up processes before the normal recovery processes. Here we report two additional glitches of the Crab pulsar occurred in 2004 and 2011 for which we discovered delayed spin up processes, and present refined parameters of the largest glitch occurred in 2017. The initial rising time of the glitch is determined as $<0.48$ hour. We also carried out a statistical study of these five glitches with observed spin-up processes. The two glitches occurred in 2004 and 2011 have delayed spin-up time scales ($\tau_{1}$) of $1.7\pm0.8$\,days and $1.6\pm0.4$\,days, respectively. We find that the $\Delta{\nu}$ vs. $|\Delta{\dot\nu}|$ relation of these five glitches is similar to those with no detected delayed spin-up process, indicating that they are similar to the others in nature except that they have larger amplitudes. For these five glitches, the amplitudes of the delayed spin-up process ($|\Delta{\nu}_{\rm d1}|$) and recovery process ($\Delta{\nu}_{\rm d2}$), their time scales ($\tau_{1}$, $\tau_{2}$), and permanent changes in spin frequency ($\Delta{\nu}_{\rm p}$) and total frequency step ($\Delta{\nu}_{\rm g}$) have positive correlations. From these correlations, we suggest that the delayed spin-up processes are common for all glitches, but are too short and thus difficult to be detected for most glitches., Comment: 25 pages, 8 figures

Published

2020

10. A search for prompt gamma-ray counterparts to fast radio bursts in the Insight-HXMT data

Author

Guidorzi, C., Marongiu, M., Martone, R., Nicastro, L., Xiong, S. L., Liao, J. Y., Li, G., Zhang, S. N., Amati, L., Frontera, F., Orlandini, M., Rosati, P., Virgilli, E., Zhang, S., Bu, Q. C., Cai, C., Cao, X. L., Chang, Z., Chen, G., Chen, L., Chen, T. X., Chen, Y. B., Chen, Y. P., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Ge, M. Y., Gu, Y. D., Guan, J., Guo, C. C., Han, D. W., Huang, Y., Huo, J., Jia, S. M., Jiang, L. H., Jiang, W. C., Jin, J., Jin, Y. J., Kong, L. D., Li, B., Li, C. K., Li, M. S., Li, T. P., Li, W., Li, X., Li, X. B., Li, X. F., Li, Y. G., Li, Z. W., Liang, X. H., Liu, B. S., Liu, C. Z., Liu, G. Q., Liu, H. W., Liu, X. J., Liu, Y. N., Lu, B., Lu, F. J., Lu, X. F., Luo, Q., Luo, T., Ma, R. C., Ma, X., Meng, B., Nang, Y., Nie, J. Y., Oui, G., Qu, J. L, Sai, N., Shang, R. C., Song, L. M., Song, X. Y., Sun, L., Tani, Y., Tao, L., Tuo, Y. L., Wang, C., Wang, G. F., Wang, J., Wang, W. S., Wang, Y. S., Wen, X. Y., Wu, B. Y., Wu, B. B., Wu, M., Xiao, G. C., Xiao, S., Xu, Y. P., Yang, J. W., Yang, S., Yang, Y. J., Yi, Q. B., Yin, Q. Q., You, Y., Zhang, A. M. Zhang C. M., Zhang, F., Zhang, H. M., Zhang, J., Zhang, T., Zhang, W. C., Zhang, W., Zhang, W. Z., Zhang, Y., Zhang, Y. F., Zhang, Y. J., Zhang, Z., Zhang, Z. L., Zhang, H. S., Zhang, X. F., Zheng, S. J., Zhou, D. K., Zhou, J. F., Zhu, Y. X., Zhu, Y., and Zhuang, R. L.

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

No robust detection of prompt electromagnetic counterparts to fast radio bursts (FRBs) has yet been obtained, in spite of several multi-wavelength searches carried out so far. Specifically, X/gamma-ray counterparts are predicted by some models. We planned on searching for prompt gamma-ray counterparts in the Insight-Hard X-ray Modulation Telescope (Insight-HXMT) data, taking advantage of the unique combination of large effective area in the keV-MeV energy range and of sub-ms time resolution. We selected 39 FRBs that were promptly visible from the High-Energy (HE) instrument aboard Insight-HXMT. After calculating the expected arrival times at the location of the spacecraft, we searched for a significant excess in both individual and cumulative time profiles over a wide range of time resolutions, from several seconds down to sub-ms scales. Using the dispersion measures in excess of the Galactic terms, we estimated the upper limits on the redshifts. No convincing signal was found and for each FRB we constrained the gamma-ray isotropic-equivalent luminosity and the released energy as a function of emission timescale. For the nearest FRB source, the periodic repeater FRB180916.J0158+65, we find $L_{\gamma,iso}<5.5\times 10^{47}$ erg/s over 1 s, whereas $L_{\gamma,iso}<10^{49}-10^{51}$ erg/s for the bulk of FRBs. The same values scale up by a factor of ~100 for a ms-long emission. Even on a timescale comparable with that of the radio pulse itself no keV-MeV emission is observed. A systematic association with either long or short GRBs is ruled out with high confidence, except for subluminous events, as is the case for core-collapse of massive stars (long) or binary neutron star mergers (short) viewed off axis. Only giant flares from extra-galactic magnetars at least ten times more energetic than Galactic siblings are ruled out for the nearest FRB., Comment: 15 pages, 3 figures, 6 tables, accepted by A&A

Published

2020

11. Insight-HXMT observations of 4U~1636-536: Corona cooling revealed with single short type-I X-ray burst

Author

Chen, Y. P., Zhang, S., Zhang, S. N., Ji, L., Kong, L. D., Cao, X. L., Chang, Z., Chen, G., Chen, L., Chen, T. X., Chen, Y., Chen, Y. B., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Ge, M. Y., Gu, Y. D., Guan, J., Guo, C. C., Han, D. W., Hu, W., Huang, Y., Huo, J., Jia, S. M., Jiang, L. H., Jiang, W. C., Jin, J., Jin, Y. J., Li, B., Li, C. K., Li, G., Li, M. S., Li, T. P., Li, W., Li, X., Li, X. B., Li, X. F., Li, Y. G., Li, Z. J., Li, Z. W., Liang, X. H., Liao, J. Y., Liu, C. Z., Liu, G. Q., Liu, H. W., Liu, S. Z., Liu, X. J., Liu, Y., Liu, Y. N., Lu, B., Lu, F. J., Lu, X. F., Luo, T., Ma, X., Meng, B., Nang, Y., Nie, J. Y., Ou, G., Qu, J. L., Sai, N., Song, L. M., Sun, L., Tan, Y., Tao, L., Tao, W. H., Tuo, Y. L., Wang, G. F., Wang, H. Y., Wang, J., Wang, W. S., Wang, Y. S., Wen, X. Y., Wu, B. B., Wu, M., Xiao, G. C., Xiong, S. L., Xu, H., Xu, Y. P., Yan, L. L., Yang, J. W., Yang, S., Yang, Y. J., Zhang, A. M., Zhang, C. L., Zhang, C. M., Zhang, F., hang, H. M., Zhang, J., Zhang, Q., Zhang, T., Zhang, W., Zhang, W. C., Zhang, W. Z., Zhang, Y., Zhang, Y. F., Zhang, Y. J., Zhang, Z., Zhang, Z. L., Zhao, H. S., Zhao, J. L., Zhao, X. F., Zheng, S. J., Zhu, Y., Zhu, Y. X., and Zou, C. L.

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

Corona cooling was detected previously from stacking a series of short type-I bursts occurred during the low/had state of atoll outburst. Type-I bursts are hence regarded as sharp probe to our better understanding on the basic property of the corona. The launch of the first Chinese X-ray satellite Insight-HXMT has large detection area at hard X-rays which provide almost unique chance to move further in this research field. We report the first detection of the corona cooling by Insight-HXMT from single short type-I burst showing up during {\bf flare} of 4U 1636-536. This type-I X-ray burst has a duration of $\sim$13 seconds and hard X-ray shortage is detected with significance 6.2~$\sigma$ in 40-70 keV. A cross-correlation analysis between the lightcurves of soft and hard X-ray band, shows that the corona shortage lag the burst emission by 1.6 $\pm$1.2~s. These results are consistent with those derived previously from stacking a large amount of bursts detected by RXTE/PCA within a series of {\bf flares} of 4U 1636-536. Moreover, the broad bandwidth of Insight-HXMT allows as well for the first time to infer the burst influence upon the continuum spectrum via performing the spectral fitting of the burst, which ends up with the finding that hard X-ray shortage appears at around 40 keV in the continuum spectrum. These results suggest that the evolution of the corona along with the outburst{\bf /flare} of NS XRB may be traced via looking into a series of embedded type-I bursts by using Insight-HXMT., Comment: published in 2018, ApJL,864, L30

Published

2019

12. The High Energy X-ray telescope (HE) onboard the Insight-HXMT astronomy satellite

Author

Liu, C. Z., Zhang, Y. F., Li, X. F., Lu, X. F., Chang, Z., Li, Z. W., Zhang, A. Z., Jin, Y. J., Yu, H. M., Zhang, Z., Fu, M. X., Chen, Y. B., Ji, J. F., Xu, Y. P., Deng, J. K., Shang, R. C., Liu, G. Q., Lu, F. J., Zhang, S. N., Dong, Y. W., Li, T. P., Wu, M., Li, Y. G., Wang, H. Y., Wu, B. B., Zhang, Y. J., Xiong, S. L., Liu, Y., Zhang, S., Liu, H. W., Yang, Y. R., and Zhang, F.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The Insight-Hard X-ray Modulation Telescope (Insight-HXMT) is a broad band X-ray and gamma-ray (1-3000 keV) astronomy satellite. The High Energy X-ray telescope (HE) is one of its three main telescopes. The main detector plane of HE is composed of 18 NaI(Tl)/CsI(Na) phoswich detectors, where NaI(Tl) serves as primary detector to measure ~ 20-250 keV photons incident from the field of view (FOV) defined by the collimators, and CsI(Na) is used as an active shield detector to NaI(Tl) by pulse shape discrimination. CsI(Na) is also used as an omnidirectional gamma-ray monitor. The HE collimators have a diverse FOV: 1.1{\deg}x 5.7{\deg} (15 units), 5.7{\deg}x 5.7{\deg} (2 units) and blocked (1 unit), thus the combined FOV of HE is about 5.7{\deg}x 5.7{\deg}. Each HE detector has a diameter of 190 mm, resulting in the total geometrical area of about 5100 cm_2. The energy resolution is ~15% at 60 keV. The timing accuracy is better than 10 {\mu}s and dead-time for each detector is less than 10 {\mu}s. HE is devoted to observe the spectra and temporal variability of X-ray sources in the 20-250 keV band either by pointing observations for known sources or scanning observations to unveil new sources, and to monitor the gamma-ray sky in 0.2-3 MeV. This paper presents the design and performance of the HE instruments. Results of the on-ground calibration experiments are also reported., Comment: Accepted by SCIENCE CHINA Physics, Mechanics & Astronomy

Published

2019

13. Timing analysis of 2S 1417-624 observed with NICER and Insight-HXMT

Author

Ji, L., Doroshenko, V., Santangelo, A., Gungor, C., Zhang, S., Ducci, L., Zhang, S. -N., Ge, M. -Y., Qu, L. J., Chen, Y. P., Bu, Q. C., Cao, X. L., Chang, Z., Chen, G., Chen, L., Chen, T. X., Chen, Y., Chen, Y. B., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Gu, Y. D., Guan, J., Guo, C. C., Han, D. W., Hu, W., Huang, Y., Huo, J., Jia, S. M., Jiang, L. H., Jiang, W. C., Jin, J., Jin, Y. J., Kong, L. D., Li, B., Li, C. K., Li, G., Li, M. S., Li, T. P., Li, W., Li, X., Li, X. B., Li, X. F., Li, Y. G., Li, Z. J., Li, Z. W., Liang, X. H., Liao, J. Y., Liu, C. Z., Liu, G. Q., Liu, H. W., Liu, S. Z., Liu, X. J., Liu, Y., Liu, Y. N., Lu, B., Lu, F. J., Lu, X. F., Luo, T., Ma, X., Meng, B., Nang, Y., Nie, J. Y., Ou, G., Sai, N., Song, L. M., Song, X. Y., Sun, L., Tan, Y., Tao, L., Tuo, Y. L., Wang, G. F., Wang, J., Wang, W. S., Wang, Y. S., Wen, X. Y., Wu, B. B., Wu, M., Xiao, G. C., Xiong, S. L., Xu, H., Xu, Y. P., Yang, Y. R., Yang, J. W., Yang, S., Yang, Y. J., Zhang, A. M., Zhang, C. L., Zhang, C. M., Zhang, F., Zhang, H. M., Zhang, J., Zhang, Q., Zhang, T., Zhang, W., Zhang, W. C., Zhang, W. Z., Zhang, Y., Zhang, Y. F., Zhang, Y. J., Zhang, Z., Zhang, Z. L., Zhao, H. S., Zhao, J. L., Zhao, X. F., Zheng, S. J., Zhu, Y., Zhu, Y. X., and Zou, C. L.

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

We present a study of timing properties of the accreting pulsar 2S 1417-624 observed during its 2018 outburst, based on Swift/BAT, Fermi/GBM, Insight-HXMT and NICER observations. We report a dramatic change of the pulse profiles with luminosity. The morphology of the profile in the range 0.2-10.0keV switches from double to triple peaks at $\sim2.5$ $\rm \times 10^{37}{\it D}_{10}^2\ erg\ s^{-1}$ and from triple to quadruple peaks at $\sim7$ $\rm \times 10^{37}{\it D}_{10}^2\ erg\ s^{-1}$. The profile at high energies (25-100keV) shows significant evolutions as well. We explain this phenomenon according to existing theoretical models. We argue that the first change is related to the transition from the sub to the super-critical accretion regime, while the second to the transition of the accretion disc from the gas-dominated to the radiation pressure-dominated state. Considering the spin-up as well due to the accretion torque, this interpretation allows to estimate the magnetic field self-consistently at $\sim7\times 10^{12}$G., Comment: 7 pages, 4 figures, 1 tables, accepted for publication in MNRAS

Published

2019

14. Hot disk of the Swift J0243.6+6124 revealed by Insight-HXMT

Author

Doroshenko, V., Zhang, S. N., Santangelo, A., Ji, L., Tsygankov, S., Mushtukov, A., Qu, L. J., Zhang, S., Ge, M. Y., Chen, Y. P., Bu, Q. C., Cao, X. L., Chang, Z., Chen, G., Chen, L., Chen, T. X., Chen, Y., Chen, Y. B., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Gu, Y. D., Guan, Guo, C. C., Han, D. W., Hu, W., Huang, Y., Huo, J., Jia, S. M., Jiang, L. H., Jiang, W. C., Jin, J., Jin, Y. J., Kong, L. D., Li, B., Li, C. K., Li, G., Li, M. S., Li, T. P., Li, W., Li, X., Li, X. B., Li, X. F., Li, Y. G., Li, Z. J., Li, Z. W., Liang, X. H., Liao, J. Y., Liu, C. Z., Liu, G. Q., Liu, H. W., Liu, S. Z., Liu, X. J., Liu, Y., Liu, Y. N., Lu, B., Lu, F. J., Lu, X. F., Luo, T., Ma, X., Meng, B., Nang, Y., Nie, J. Y., Ou, G., Sai, N., Song, L. M., Song, X. Y., Sun, L., Tan, Y., Tao, L., Tuo, Y. L., Wang, G. F., Wang, J., Wang, W. S., Wang, Y. S., Wen, X. Y., Wu, B. B., Wu, M., Xiao, G. C., Xiong, S. L., Xu, H., Xu, Y. P., Yang, Y. R., Yang, J. W., Yang, S., Yang, Y. J., Zhang, A. M., Zhang, C. L., Zhang, C. M., Zhang, F., Zhang, H. M., Zhang, J., Zhang, Q., Zhang, T., Zhang, W., Zhang, W. C., Zhang, W. Z., Zhang, Y., Zhang, Y. F., Zhang, Y. J., Zhang, Z., Zhang, Z. L., Zhao, H. S., Zhao, J. L., Zhao, X. F., Zheng, S. J., Zhu, Y., Zhu, Y. X., and Zou, C. L.

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

We report on analysis of observations of the bright transient X-ray pulsar \src obtained during its 2017-2018 giant outburst with Insight-HXMT, \emph{NuSTAR}, and \textit{Swift} observatories. We focus on the discovery of a sharp state transition of the timing and spectral properties of the source at super-Eddington accretion rates, which we associate with the transition of the accretion disk to a radiation pressure dominated (RPD) state, the first ever directly observed for magnetized neutron star. This transition occurs at slightly higher luminosity compared to already reported transition of the source from sub- to super-critical accretion regime associate with onset of an accretion column. We argue that this scenario can only be realized for comparatively weakly magnetized neutron star, not dissimilar to other ultra-luminous X-ray pulsars (ULPs), which accrete at similar rates. Further evidence for this conclusion is provided by the non-detection of the transition to the propeller state in quiescence which strongly implies compact magnetosphere and thus rules out magnetar-like fields., Comment: Submitted to MNRAS

Published

2019

15. In-orbit demonstration of X-ray pulsar navigation with the Insight-HXMT satellite

Author

Zheng, S. J., Zhang, S. N., Lu, F. J., Wang, W. B., Gao, Y., Li, T. P., Song, L. M., Ge, M. Y., Han, D. W., Chen, Y., Xu, Y. P., Cao, X. L., Liu, C. Z., Zhang, S., Qu, J. L., Chang, Z., Chen, G., Chen, L., Chen, T. X., Chen, Y. B., Chen, Y. P., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Gu, Y. D., Guan, J., Gungor, C., Guo, C. C., Hu, W., Huang, Y., Huo, J., Ji, J. F., Jia, S. M., Jiang, L. H., Jiang, W. C., Jin, J., Jin, Y. J., Li, B., Li, C. K., Li, G., Li, M. S., Li, W., Li, X., Li, X. B., Li, X. F., Li, Y. G., Li, Z. J., Li, Z. W., Liang, X. H., Liao, J. Y., Liu, G. Q., Liu, H. W., Liu, S. Z., Liu, X. J., Liu, Y., Liu, Y. N., Lu, B., Lu, X. F., Luo, T., Ma, X., Meng, B., Nang, Y., Nie, J. Y., Ou, G, Sai, N., Shang, R. C., Sun, L., Tan, Y., Tao, L., Tao, W., Tuo, Y. L., Wang, G. F., Wang, J., Wang, W. S., Wang, Y. S., Wen, X. Y., Wu, B. B., Wu, M., Xiao, G. C., Xiong, S. L., Xu, H., Yan, L. L., Yang, J. W., Yang, S., Yang, Y. J., Zhang, A. M., Zhang, C. L., Zhang, C. M., Zhang, F., Zhang, H. M., Zhang, J., Zhang, Q., Zhang, T., Zhang, W., Zhang, W. C., Zhang, W. Z., Zhang, Y., Zhang, Y. F., Zhang, Y. J., Zhang, Z., Zhang, Z. L., Zhao, H. S., Zhao, J. L., Zhao, X. F., Zhu, Y., Zhu, Y. X., and Zou, C. L.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

In this work, we report the in-orbit demonstration of X-ray pulsar navigation with Insight-Hard X-ray Modulation Telescope (Insight-HXMT), which was launched on Jun. 15th, 2017. The new pulsar navigation method 'Significance Enhancement of Pulse-profile with Orbit-dynamics' (SEPO) is adopted to determine the orbit with observations of only one pulsar. In this test, the Crab pulsar is chosen and observed by Insight-HXMT from Aug. 31th to Sept. 5th in 2017. Using the 5-day-long observation data, the orbit of Insight-HXMT is determined successfully with the three telescopes onboard - High Energy X-ray Telescope (HE), Medium Energy X-ray Telescope (ME) and Low Energy X-ray Telescope (LE) - respectively. Combining all the data, the position and velocity of the Insight-HXMT are pinpointed to within 10 km (3 sigma) and 10 m/s (3 sigma), respectively., Comment: Accepted by the Astrophysical Journal Supplement

Published

2019

16. Ideal Intersecting Nodal Ring Phonons in a Body-Centered Cubic C$_{8}$

Author

Jin, Y. J., Chen, Z. J., Xia, B. W., Zhao, Y. J., Wang, R., and Xu, H.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Carbon, a basic versatile element in our universe, exhibits rich varieties of allotropic phases, most of which possess promising nontrivial topological fermions. In this work, we identify a distinct topological phonon phase in a realistic carbon allotrope with a body-centered cubic structure, termed bcc-C$_{8}$. We show by symmetry arguments and effective model analysis that there are three intersecting phonon nodal rings perpendicular to each other in different planes. The intersecting phonon nodal rings are protected by time-reversal and inversion symmetries, which quantize the corresponding Berry phase into integer multiples of $\pi$. Unlike the electron systems, the phonon nodal rings in bcc-C$_{8}$ are guaranteed to remain gapless due to the lack of spin-orbital coupling. The nearly flat drumhead surface states projected on semi-infinite (001) and (110) surfaces of bcc-C$_{8}$ are clearly visible. Our findings not only discover promising nodal ring phonons in a carbon allotrope, but also provide emergent avenues for exploring topological phonons beyond fermionic electrons in carbon-allotropic structures with attractive features., Comment: 5 pages, 4 figures

Published

2018

17. Insight-HXMT observations of the New Black Hole Candidate MAXI J1535-571: timing analysis

Author

Huang, Y., Qu, J. L., Zhang, S. N., Bu, Q. C., Chen, Y. P., Tao, L., Zhang, S., Lu, F. J., Li, T. P., Song, L. M., Xu, Y. P., Cao, X. L., Chen, Y., Liu, C. Z., Chang, H. -K., Yu, W. f., Weng, S. S., Hou, X., Kong, A. K. H., Xie, F. G., Zhang, G. B., ZHOU, J. F., Chang, Z., Chen, G., Chen, L., Chen, T. X., Chen, Y. B., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Ge, M. Y., Gu, Y. D., Guan, J., Gungor, C., Guo, C. C., Han, D. W., Hu, W., Huo, J., Ji, J. F., Jia, S. M., Jiang, L. H., Jiang, W. C., Jin, J., Jin, Y. J., Li, B., Li, C. K., Li, G., Li, M. S., Li, W., Li, X., Li, X. B., Li, X. F., Li, Y. G., Li, Z. J., Li, Z. W., Liang, X. H., Liao, J. Y., Liu, G. Q., Liu, H. W., Liu, S. Z., Liu, X. J., Liu, Y., Liu, Y. N., Lu, B., Lu, X. F., Luo, T., Ma, X., Meng, B., Nang, Y., Nie, J. Y., Ou, G, Sai, N., Shang, R. C., Sun, L., Tan, Y., Tao, W., Tuo, Y. L., Wang, G. F., Wang, H. Y., Wang, J., Wang, W. S., Wang, Y. S., Wen, X. Y., Wu, B. B., Wu, M., Xiao, G. C., Xiong, S. L., Xu, H., Yan, L. L., Yang, J. W., Yang, S., Yang, Y. J., Zhang, A. M., Zhang, C. L., Zhang, C. M., Zhang, F., Zhang, H. M., Zhang, J., Zhang, Q., Zhang, T., Zhang, W., Zhang, W. C., Zhang, W. Z., Zhang, Y., Zhang, Y. F., Zhang, Y. J., Zhang, Z., Zhang, Z. L., Zhao, H. S., Zhao, J. L., Zhao, X. F., Zheng, S. J., Zhu, Y., Zhu, Y. X., and Zou, C. L.

Subjects

Astrophysics - High Energy Astrophysical Phenomena

Abstract

We present the X-ray timing results of the new black hole candidate (BHC) MAXI J1535-571 during its 2017 outburst from Hard X-ray Modulation Telescope (\emph{Insight}-HXMT) observations taken from 2017 September 6 to 23. Following the definitions given by \citet{Belloni2010}, we find that the source exhibits state transitions from Low/Hard state (LHS) to Hard Intermediate state (HIMS) and eventually to Soft Intermediate state (SIMS). Quasi-periodic oscillations (QPOs) are found in the intermediate states, which suggest different types of QPOs. With the large effective area of \emph{Insight}-HXMT at high energies, we are able to present the energy dependence of the QPO amplitude and centroid frequency up to 100 keV which is rarely explored by previous satellites. We also find that the phase lag at the type-C QPOs centroid frequency is negative (soft lags) and strongly correlated with the centroid frequency. By assuming a geometrical origin of type-C QPOs, the source is consistent with being a high inclination system., Comment: 12 pages, 11 figures, Sumbitted to ApJ

Published

2018

18. Three-Dimensional Quantum Anomalous Hall Effect in Ferromagnetic Insulators

Author

Jin, Y. J., Wang, R., Xia, B. W., Zheng, B. B., and Xu, H.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

The quantum anomalous Hall effect (QAHE) hosts the dissipationless chiral edge states associated with the nonzero Chern number, providing potentially significant applications in future spintronics. The QAHE usually occurs in a two-dimensional (2D) system with time-reversal symmetry breaking. In this work, we propose that the QAHE can exist in three-dimensional (3D) ferromagnetic insulators. By imposing inversion symmetry, we develop the topological constraints dictating the appearance of 3D QAHE based on the parity analysis at the time-reversal invariant points in reciprocal space. Moreover, using first-principles calculations, we identify that 3D QAHE can be realized in a family of intrinsic ferromagnetic insulating oxides, including layered and non-layered compounds that share a centrosymmetric structure with space group $R\bar{3}m$ (No. 166). The Hall conductivity is quantized to be $-\frac{3e^2}{hc}$ with the lattice constant $c$ along $c$-axis. The chiral surface sheet states are clearly visible and uniquely distributed on the surfaces that are parallel to the magnetic moment. Our findings open a promising pathway to realize the QAHE in 3D ferromagnetic insulators., Comment: 5 pages, 4 figures

Published

2018

19. Room-Temperature Ferromagnetic Topological Phase in CrO$_{2}$: From Tripe Fermions to Weyl Fermions

Author

Wang, R., Jin, Y. J., Duan, L., Zhao, J. Z., Xu, H., and Jin, C. Q.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

Ferromagnetic topological semimetals due to their band topology co-existing with intrinsic magnetization exerted important influences on early study of topological fermions. However, they have not been observed in experiments up to now. In this work, we propose that rutile CrO$_{2}$, a widely used half-metallic ferromagnetic material in magnetic recording taps, exhibits unexpected ferromagnetic topological features. Using first-principles calculations and symmetry analysis, we reveal that rutile CrO$_2$ hosts the triple nodal points in the absence of spin orbital coupling (SOC). By taking into account of SOC, each triple nodal point splits into two Weyl points, which are located on the magnetic axis with four-fold rotational symmetry. Notably, the Fermi arcs and accompanying quasiparticle interference patterns are clearly visible, which facilitate experimental observations. In addition, we find that another experimentally synthesized CrO$_{2}$ in CaCl$_2$ structure, also hosts the topologically nontrivial ferromagnetic phase. Our findings substantially advance the experimental realization of ferromagnetic topological semimetals. More importantly, room-temperature time-reversal-breaking Weyl fermions in CrO$_{2}$ may result in promising applications related to the topological phenomena in industry., Comment: 5 pages, 4 figures

Published

2017

20. Ferromagnetic Type-II Weyl Semimetal in Pyrite Chromium Dioxide

Author

Wang, R., Jin, Y. J., Zhao, J. Z., Chen, Z. J., Zhao, Y. J., and Xu, H.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

Magnetic topological materials have recently drawn significant importance and interest, due to their topologically nontrivial electronic structure within spontaneous magnetic moments and band inversion. Based on first-principles calculations, we propose that chromium dioxide, in its ferromagnetic pyrite structure, can realize one pair of type-II Weyl points between the $N$th and $(N+1)$th bands, where $N$ is the total number of valence electrons per unit cell. Other Weyl points between the $(N-1)$th and $N$th bands also appear close to the Fermi level due to the complex topological electronic band structure. The symmetry analysis elucidates that the Weyl points arise from a triply-degenerate point splitting due to the mirror reflection symmetry broken in the presence of spin-orbital coupling, which is equivalent to an applied magnetic field along the direction of magnetization. The Weyl points located on the magnetic axis are protected by the three-fold rotational symmetry. The corresponding Fermi arcs projected on both (001) and (110) surfaces are calculated as well and observed clearly. This finding opens a wide range of possible experimental realizations of type-II Weyl fermions in a system with time-reversal breaking., Comment: 8 pages, 5 figures

Published

2017

21. Topological Weyl and Node-Line Semimetals in Ferromagnetic Vanadium-Phosphorous-Oxide $\beta$-V$_2$OPO$_4$ Compound

Author

Jin, Y. J., Wang, R., Zhao, J. Z., Chen, Z. J., Zhao, Y. J., and Xu, H.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We propose that the topological semimetal features can co-exist with ferromagnetic ground state in vanadium-phosphorous-oxide $\beta$-V$_2$OPO$_4$ compound from first-principles calculations. In this magnetic system with inversion symmetry, the direction of magnetization is able to manipulate the symmetric protected band structures from a node-line type to a Weyl one in the presence of spin-orbital-coupling. The node-line semimetal phase is protected by the mirror symmetry with the reflection-invariant plane perpendicular to magnetic order. Within mirror symmetry breaking due to the magnetization along other directions, the gapless node-line loop will degenerate to only one pair of Weyl points protected by the rotational symmetry along the magnetic axis, which are largely separated in momentum space. Such Weyl semimetal phase provides a nice candidate with the minimum number of Weyl points in a condensed matter system. The results of surface band calculations confirm the non-trivial topology of this proposed compound. This findings provide a realistic candidate for the investigation of topological semimetals with time-reversal symmetry breaking, particularly towards the realization of quantum anomalous Hall effect in Weyl semimetals., Comment: 5 pages, 4 figures

Published

2017

22. Strongly Ideal Robust Weyl Semimetals in Cubic Symmetry with Spatial-Inversion Breaking

Author

Wang, R., Zhao, J. Z., Jin, Y. J., Xu, W. P., Gan, L. -Y., Wu, X. Z., Xu, H., and Tong, S. Y.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We show that compounds in a family that possess time-reversal symmetry and share a non-centrosymmetric cubic structure with the space group F-43m (No. 216) host robust ideal Weyl semi-metal fermions with desirable topologically protected features. The candidates in this family are compounds with different chemical formulas AB2, ABC, ABC2, and ABCD and their Fermi levels are predominantly populated by nontrivial Weyl fermions. Symmetry of the system requires that the Weyl nodes with opposite chirality are well separated in momentum space. Adjacent Weyl points have the same chirality, thus these Weyl nodes would not annihilate each other with respect to lattice perturbations. As Fermi arcs and surface states connect Weyl nodes with opposite chirality, the large separation of the latter in momentum space guarantees the appearance of very long arcs and surface states. This work demonstrates the use of system symmetry by first-principles calculations as a powerful recipe for discovering new Weyl semi-metals with attractive features whose protected fermions may be candidates of many applications., Comment: 15 pages, 4 figures

Published

2017

23. Ferromagnetic Dirac-Nodal Semimetal Phase of Stretched Chromium Dioxide

Author

Wang, R., Zhao, J. Z., Jin, Y. J., Du, Y. P., Zhao, Y. X., Xu, H., and Tong, S. Y.

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We show by first-principles calculations that the Dirac nodal-line semimetal phase can co-exist with the ferromagnetic order at room temperature in chromium dioxide, a widely used material in magnetic tape applications, under small tensile hydrostatic strains. An ideally flat Dirac nodal ring close to the Fermi energy is placed in the reflection-invariant boundary of the Brillouin zone perpendicular to the magnetic order, and is topologically protected by the unitary mirror symmetry of the magnetic group $D_{4h}(C_{4h})$, which quantizes the corresponding Berry phase into integer multiples of $\pi$. The symmetry-dependent topological stability is demonstrated through showing that only the topologically protected nodal ring can persistently exist under small anisotropic stains preservingthe symmetry $D_{4h}(C_{4h})$, while the other seeming band touching points are generically gapped. Our work provides a practical platform for the investigation of novel physics and potential applications of the Dirac nodal-line and drumhead fermions, in particular those related to ferromagnetic properties, Comment: 5 pages, 5 figures

Published

2017

24. Pressure-induced Topological Node-Line Semimetals in Alkaline-Earth Hexaborides XB6 (X=Ca, Sr, Ba)

Author

Gan, L. -Y., Wang, R., Jin, Y. J., Ling, D. B., Zhao, J. Z., Xu, W. P., Liu, J. F., and Xu, H.

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Based on first-principles calculations, we reported that external pressure can induce topological phase transition in alkaline-earth hexaborides, XB6 (X=Ca, Sr, Ba). It was revealed that XB6 is transformed from trivial semiconductors to topological node-line semimetals under moderate pressures when spin-orbit coupling (SOC) is ignored. The band inversion between B px (pz) and py orbitals at X point is responsible for the formation of node-line semimetals. Three node-line rings around X point are protected by the combination of the time-reversal and spatial inversion symmetries, and the drumhead surface bands are obtained in the interiors of the projected node-line rings. When SOC is included, tiny gaps (< 4.8 meV) open at the crossing lines, and the XB6 becomes strong topological insulators with Z2 indices (1;111). As the SOC-induced gap opening is negligible, our findings thus suggest ideal real systems for experimental exploration of the fundamental physics of topological node-line semimetals.

Published

2016

25. Highly Efficient and Catalyst-Free Synthesis of Benzimidazoles in Aqueous Media

Author

Zhou, L.-H., Jin, Y.-J., Ma, L.-F., Huang, W.-H., and Wu, Y.

Published

2021

26. HXMT identification of a non-thermal X-ray burst from SGR J1935+2154 and with FRB 200428

Author

Li, C. K., Lin, L., Xiong, S. L., Ge, M. Y., Li, X. B., Li, T. P., Lu, F. J., Zhang, S. N., Tuo, Y. L., Nang, Y., Zhang, B., Xiao, S., Chen, Y., Song, L. M., Xu, Y. P., Liu, C. Z., Jia, S. M., Cao, X. L., Qu, J. L., Zhang, S., Gu, Y. D., Liao, J. Y., Zhao, X. F., Tan, Y., Nie, J. Y., Zhao, H. S., Zheng, S. J., Zheng, Y. G., Luo, Q., Cai, C., Li, B., Xue, W. C., Bu, Q. C., Chang, Z., Chen, G., Chen, L., Chen, T. X., Chen, Y. B., Chen, Y. P., Cui, W., Cui, W. W., Deng, J. K., Dong, Y. W., Du, Y. Y., Fu, M. X., Gao, G. H., Gao, H., Gao, M., Gu, Y. D., Guan, J., Guo, C. C., Han, D. W., Huang, Y., Huo, J., Jiang, L. H., Jiang, W. C., Jin, J., Jin, Y. J., Kong, L. D., Li, G., Li, M. S., Li, W., Li, X., Li, X. F., Li, Y. G., Li, Z. W., Liang, X. H., Liu, B. S., Liu, G. Q., Liu, H. W., Liu, X. J., Liu, Y. N., Lu, B., Lu, X. F., Luo, T., Ma, X., Meng, B., Ou, G., Sai, N., Shang, R. C., Song, X. Y., Sun, L., Tao, L., Wang, C., Wang, G. F., Wang, J., Wang, W. S., Wang, Y. S., Wen, X. Y., Wu, B. B., Wu, B. Y., Wu, M., Xiao, G. C., Xu, H., Yang, J. W., Yang, S., Yang, Y. J., Yang, Yi-Jung, Yi, Q. B., Yin, Q. Q., You, Y., Zhang, A. M., Zhang, C. M., Zhang, F., Zhang, H. M., Zhang, J., Zhang, T., Zhang, W., Zhang, W. C., Zhang, W. Z., Zhang, Y., Zhang, Yue, Zhang, Y. F., Zhang, Y. J., Zhang, Z., Zhang, Zhi, Zhang, Z. L., Zhou, D. K., Zhou, J. F., Zhu, Y., Zhu, Y. X., and Zhuang, R. L.

Published

2021

27. Primary dendrite growth within binary Fe71Ge29 eutectic alloy under duplex levitation states.

Author

Hou, N. S., Geng, D. L., Jin, Y. J., Yan, P. X., and Wei, B.

Subjects

DENDRITIC crystals, LEVITATION, EUTECTIC alloys, ACOUSTIC streaming, MAGNETIC suspension

Abstract

The primary β-Fe3Ge2 dendrite growth kinetics within liquid Fe71Ge29 eutectic alloy was studied by both acoustic levitation and electrostatic levitation techniques, with maximum experimental undercoolings of 130 and 143 K, respectively. At small undercoolings, (α1 + β-Fe3Ge2) eutectic growth proceeded and then transformed to lamellar (ε-Fe3Ge + β-Fe3Ge2) microstructure by peritectoid reaction. Once liquid undercooling reached 56 K, β primary phase started to nucleate preferentially and its maximum growth velocity attained 13.5 mm/s at 143 K undercooling. By acoustic levitation processing, β dendrites were distributed inside the alloy droplet. Under electrostatic levitation state, β dendrites were distributed both at the periphery and within the interior of alloy droplet, and their volume fraction was significantly higher than that under acoustic levitation. Numerical simulation results indicated that a duplex flow was induced by alloy droplet shape oscillation and acoustic streaming. The flow exhibited maximum intensity near the alloy surface, which inhibited the achievement of larger undercoolings during acoustic levitation. [ABSTRACT FROM AUTHOR]

Published

2024

28. Quasi-periodic Oscillations in GX 339−4 during the 2021 Outburst Observed with Insight-HXMT

Author

Jin, Y. J., primary, Wang, W., additional, Chen, X., additional, Tian, P. F., additional, Liu, Q., additional, Zhang, P., additional, Wu, H. J., additional, and Sai, N., additional

Published

2023

29. ZnO Nanoparticle Modification by Polyethylenimine for Biomolecule Conjugation

Author

Shiryaev, M. A., Jin, Y. J., Bong, H. Ch., and Baranov, A.

Published

2017

30. Cyclic Mobility of Sand and Its Simulation in Boundary Value Problems

Author

Zhang, F., Ye, Bin, Jin, Y. J., Nakai, T., Wu, Wei, editor, Borja, Ronaldo I., editor, Wan, Richard, editor, Alsaleh, Mustafa, editor, and Labuz, Joe, editor

Published

2011

31. Spin photovoltaic effect in antiferromagnetic materials: Mechanisms, symmetry constraints, and recent progress.

Author

Xiao, Rui-Chun, Jin, Y. J., and Jiang, Hua

Subjects

PHOTOVOLTAIC effect, SYMMETRY, SPINTRONICS, ANTIFERROMAGNETIC materials

Abstract

Antiferromagnetic (AFM) materials possess unique properties, such as rapid dynamic response, resistance to external magnetic disturbances, and the absence of a stray field. AFM materials are important members in the field of spintronics, and generating the spin current in AFM materials is one of the vital topics for AFM spintronics. The spin photovoltaic effect (SPVE) is the spin counterpart of the bulk photovoltaic effect (BPVE), where the photocurrent is spin-polarized. This effect can generate spin current in a contactless and ultra-fast way. Recently, SPVE has garnered significant interest due to its potential application in AFM spintronics and rich physical content. In this perspective, the mechanism of SPVE, including the relationship between SPVE and BPVE, and symmetry constraints are reviewed. We also provide an overview of recent progress on SPVE in AFM materials. This perspective also offers a viewpoint on this exciting area of research. [ABSTRACT FROM AUTHOR]

Published

2023

32. In situ SEM observation of microscale strain fields around a crack tip in polycrystalline molybdenum

Author

Li, J. J., Li, W. C., Jin, Y. J., Wang, L. F., Zhao, C. W., Xing, Y. M., Lang, F. C., Yan, L., and Yang, S. T.

Published

2016

33. Switching characteristics of TaO x -based one diode-one resistor for crossbar memory application

Author

Jin, Y. J., Xu, Z., Yoon, S. F., Chia, C. K., Wang, S. J., and Chi, D. Z.

Published

2016

34. Hybrid nodal-ring phonons with hourglass dispersion in AgAlO2

Author

Chen, Z. J., primary, Xie, Z. J., additional, Jin, Y. J., additional, Liu, G., additional, and Xu, H., additional

Published

2022

35. Type-II quadratic and cubic Weyl fermions

Author

Jin, Y. J., primary, Xu, Y., additional, Chen, Z. J., additional, and Xu, H., additional

Published

2022

36. Electromagnetically induced transparency and theoretical slow light in semiconductor multiple quantum wells

Author

Yan, W., Wang, T., Li, X. M., and Jin, Y. J.

Published

2012

37. Three-Dimensional Dirac Phonons with Inversion Symmetry

Author

Chen, Z. J., primary, Wang, R., additional, Xia, B. W., additional, Zheng, B. B., additional, Jin, Y. J., additional, Zhao, Yu-Jun, additional, and Xu, H., additional

Published

2021

38. Tunable double Weyl phonons driven by chiral point group symmetry

Author

Jin, Y. J., primary, Chen, Z. J., additional, Xiao, X. L., additional, and Xu, H., additional

Published

2021

39. PAC1 is a direct transcription target of E2F-1 in apoptotic signaling

Author

Wu, J, Jin, Y J, Calaf, G M, Huang, W-L, and Yin, Y

Published

2007

40. Synergistic Effects of A1896, T1653 and T1762/A1764 Mutations in Genotype C2 Hepatitis B Virus on Development of Hepatocellular Carcinoma

Author

Lyu, H., Lee, D., Chung, Y.-H., Kim, J. A., Lee, J.-H., Jin, Y.-J., Park, W., Mathews, P., Jaffee, E., Zheng, L., Yu, E., and Lee, Y. J.

Published

2013

41. Improvement in Hematopoiesis after Iron Chelation Therapy with Deferasirox in Patients with Aplastic Anemia

Author

Lee, Sung-Eun S.-E., Yahng, Seung-Ah S.-A., Cho, Byung-Sik B.-S., Eom, Ki-Sung K.-S., Kim, Yoo-Jin Y.-J., Lee, Seok S., Min, Chang-Ki C.-K., Kim, Hee-Je H.-J., Cho, Seok-Goo S.-G., Kim, Dong-Wook D.-W., Min, Woo-Sung W.-S., Park, Chong-Won C.-W., and Lee, Jong Wook J.W.

Published

2013

42. Vitamin B12-Responsive Pancytopenia Mimicking Myelodysplastic Syndrome

Author

Kim, Myungshin M., Lee, Sung-Eun S.-E., Park, Joonhong J., Lim, Jihyang J., Cho, Byung-Sik B.-S., Kim, Yoo-Jin Y.-J., Kim, Hee-Je H.-J., Lee, Seok S., Min, Chang-Ki C.-K., Kim, Yonggoo Y., and Cho, Seok-Goo S.-G.

Published

2011

43. Two Complete Spectral Transitions of Swift J0243.6+6124 Observed by Insight-HXMT

Author

Kong, L. D., primary, Zhang, S., additional, Chen, Y. P., additional, Zhang, S. N., additional, Ji, L., additional, Doroshenko, V., additional, Wang, P. J., additional, Tao, L., additional, Ge, M. Y., additional, Liu, C. Z., additional, Song, L. M., additional, Lu, F. J., additional, Qu, J. L., additional, Li, T. P., additional, Xu, Y. P., additional, Cao, X. L., additional, Chen, Y., additional, Bu, Q. C., additional, Cai, C., additional, Chang, Z., additional, Chen, G., additional, Chen, L., additional, Chen, T. X., additional, Chen, Y. B., additional, Cui, W., additional, Cui, W. W., additional, Deng, J. K., additional, Dong, Y. W., additional, Du, Y. Y., additional, Fu, M. X., additional, Gao, G. H., additional, Gao, H., additional, Gao, M., additional, Gu, Y. D., additional, Guan, J., additional, Guo, C. C., additional, Han, D. W., additional, Huang, Y., additional, Huo, J., additional, Jia, S. M., additional, Jiang, L. H., additional, Jiang, W. C., additional, Jin, J., additional, Jin, Y. J., additional, Li, B., additional, Li, C. K., additional, Li, G., additional, Li, M. S., additional, Li, W., additional, Li, X., additional, Li, X. B., additional, Li, X. F., additional, Li, Y. G., additional, Li, Z. W., additional, Liang, X. H., additional, Liao, J. Y., additional, Liu, B. S., additional, Liu, G. Q., additional, Liu, H. W., additional, Liu, X. J., additional, Liu, Y. N., additional, Lu, B., additional, Lu, X. F., additional, Luo, Q., additional, Luo, T., additional, Ma, X., additional, Meng, B., additional, Nang, Y., additional, Nie, J. Y., additional, Ou, G., additional, Sai, N., additional, Shang, R. C., additional, Song, X. Y., additional, Sun, L., additional, Tan, Y., additional, Tuo, Y. L., additional, Wang, C., additional, Wang, G. F., additional, Wang, J., additional, Wang, L. J., additional, Wang, W. S., additional, Wang, Y. S., additional, Wen, X. Y., additional, Wu, B. B., additional, Wu, B. Y., additional, Wu, M., additional, Xiao, G. C., additional, Xiao, S., additional, Xiong, S. L., additional, Xu, H., additional, Yang, J. W., additional, Yang, S., additional, Yang, Y. J., additional, Yi, Q. B., additional, Yin, Q. Q., additional, You, Y., additional, Zhang, A. M., additional, Zhang, C. M., additional, Zhang, F., additional, Zhang, H. M., additional, Zhang, J., additional, Zhang, T., additional, Zhang, W. C., additional, Zhang, W., additional, Zhang, W. Z., additional, Zhang, Y., additional, Zhang, Y. F., additional, Zhang, Y. J., additional, Zhang, Z., additional, Zhang, Z. L., additional, Zhao, H. S., additional, Zhao, X. F., additional, Zheng, S. J., additional, Zheng, Y. G., additional, Zhou, D. K., additional, Zhou, J. F., additional, Zhu, Y. X., additional, and Zhuang, R. L., additional

Published

2020

44. Two-Dimensional Dirac Semimetals without Inversion Symmetry

Author

Jin, Y. J., primary, Zheng, B. B., additional, Xiao, X. L., additional, Chen, Z. J., additional, Xu, Y., additional, and Xu, H., additional

Published

2020

45. Insight-HXMT observations of Swift J0243.6+6124: the evolution of RMS pulse fractions at super-Eddington luminosity

Author

Wang, P J, primary, Kong, L D, additional, Zhang, S, additional, Chen, Y P, additional, Zhang, S N, additional, Qu, J L, additional, Ji, L, additional, Tao, L, additional, Ge, M Y, additional, Lu, F J, additional, Chen, L, additional, Song, L M, additional, Li, T P, additional, Xu, Y P, additional, Cao, X L, additional, Chen, Y, additional, Liu, C Z, additional, Bu, Q C, additional, Cai, C, additional, Chang, Z, additional, Chen, G, additional, Chen, T X, additional, Chen, Y B, additional, Cui, W, additional, Cui, W W, additional, Deng, J K, additional, Dong, Y W, additional, Du, Y Y, additional, Fu, M X, additional, Gao, G H, additional, Gao, H, additional, Gao, M, additional, Gu, Y D, additional, Guan, J, additional, Guo, C C, additional, Han, D W, additional, Huang, Y, additional, Huo, J, additional, Jia, S M, additional, Jiang, L H, additional, Jiang, W C, additional, Jin, J, additional, Jin, Y J, additional, Li, B, additional, Li, C K, additional, Li, G, additional, Li, M S, additional, Li, W, additional, Li, X, additional, Li, X B, additional, Li, X F, additional, Li, Y G, additional, Li, Z W, additional, Liang, X H, additional, Liao, J Y, additional, Liu, B S, additional, Liu, G Q, additional, Liu, H W, additional, Liu, X J, additional, Liu, Y N, additional, Lu, B, additional, Lu, X F, additional, Luo, Q, additional, Luo, T, additional, Ma, X, additional, Meng, B, additional, Nang, Y, additional, Nie, J Y, additional, Ou, G, additional, Sai, N, additional, Shang, R C, additional, Song, X Y, additional, Sun, L, additional, Tan, Y, additional, Tuo, Y L, additional, Wang, C, additional, Wang, G F, additional, Wang, J, additional, Wang, L J, additional, Wang, W S, additional, Wang, Y S, additional, Wen, X Y, additional, Wu, B Y, additional, Wu, B B, additional, Wu, M, additional, Xiao, G C, additional, Xiao, S, additional, Xiong, S L, additional, Yang, J W, additional, Yang, S, additional, Yang, Yan Ji, additional, Yang, Yi Jung, additional, Yi, Q B, additional, Yin, Q Q, additional, You, Y, additional, Zhang, A M, additional, Zhang, C M, additional, Zhang, F, additional, Zhang, H M, additional, Zhang, J, additional, Zhang, T, additional, Zhang, W C, additional, Zhang, W, additional, Zhang, W Z, additional, Zhang, Y, additional, Zhang, Y F, additional, Zhang, Y J, additional, Zhang, Zhao, additional, Zhang, Zhi, additional, Zhang, Z L, additional, Zhao, H S, additional, Zhao, X F, additional, Zheng, S J, additional, Zheng, Y G, additional, Zhou, D K, additional, Zhou, J F, additional, Zhu, Y X, additional, Zhu, Y, additional, and Zhuang, R L, additional

Published

2020

46. Insight-HXMT Firm Detection of the Highest-energy Fundamental Cyclotron Resonance Scattering Feature in the Spectrum of GRO J1008-57

Author

Ge, M. Y., primary, Ji, L., additional, Zhang, S. N., additional, Santangelo, A., additional, Liu, C. Z., additional, Doroshenko, V., additional, Staubert, R., additional, Qu, J. L., additional, Zhang, S., additional, Lu, F. J., additional, Song, L. M., additional, Li, T. P., additional, Tao, L., additional, Xu, Y. P., additional, Cao, X. L., additional, Chen, Y., additional, Bu, Q. C., additional, Cai, C., additional, Chang, Z., additional, Chen, G., additional, Chen, L., additional, Chen, T. X., additional, Chen, Y. B., additional, Chen, Y. P., additional, Cui, W., additional, Cui, W. W., additional, Deng, J. K., additional, Dong, Y. W., additional, Du, Y. Y., additional, Fu, M. X., additional, Gao, G. H., additional, Gao, H., additional, Gao, M., additional, Gu, Y. D., additional, Guan, J., additional, Guo, C. C., additional, Han, D. W., additional, Huang, Y., additional, Huo, J., additional, Jia, S. M., additional, Jiang, L. H., additional, Jiang, W. C., additional, Jin, J., additional, Jin, Y. J., additional, Kong, L. D., additional, Li, B., additional, Li, C. K., additional, Li, G., additional, Li, M. S., additional, Li, W., additional, Li, X., additional, Li, X. B., additional, Li, X. F., additional, Li, Y. G., additional, Li, Z. W., additional, Liang, X. H., additional, Liao, J. Y., additional, Liu, B. S., additional, Liu, G. Q., additional, Liu, H. W., additional, Liu, X. J., additional, Liu, Y. N., additional, Lu, B., additional, Lu, X. F., additional, Luo, Q., additional, Luo, T., additional, Ma, X., additional, Meng, B., additional, Nang, Y., additional, Nie, J. Y., additional, Ou, G., additional, Sai, N., additional, Shang, R. C., additional, Song, X. Y., additional, Sun, L., additional, Tan, Y., additional, Tuo, Y. L., additional, Wang, C., additional, Wang, G. F., additional, Wang, J., additional, Wang, L. J., additional, Wang, W. S., additional, Wang, Y. D., additional, Wang, Y. S., additional, Wen, X. Y., additional, Wu, B. B., additional, Wu, B. Y., additional, Wu, M., additional, Xiao, G. C., additional, Xiao, S., additional, Xiong, S. L., additional, Xu, H., additional, Yang, J. W., additional, Yang, S., additional, Yang, Y. J., additional, Yi, Q. B., additional, Yin, Q. Q., additional, You, Y., additional, Zhang, A. M., additional, Zhang, C. M., additional, Zhang, F., additional, Zhang, H. M., additional, Zhang, J., additional, Zhang, T., additional, Zhang, W. C., additional, Zhang, W., additional, Zhang, W. Z., additional, Zhang, Y., additional, Zhang, Y. F., additional, Zhang, Y. J., additional, Zhang, Z., additional, Zhang, Z. L., additional, Zhao, H. S., additional, Zhao, X. F., additional, Zheng, S. J., additional, Zheng, Y. G., additional, Zhou, D. K., additional, Zhou, J. F., additional, Zhuang, R. L., additional, Zhu, Y. X., additional, and Zhu, Y., additional

Published

2020

47. Weyl fermions in ferromagnetic high-temperature phase of K2Cr8O16

Author

Zhao, J Z, primary, Jin, Y J, additional, Wang, R, additional, Xia, B W, additional, and Xu, H, additional

Published

2020

48. Discovery of Delayed Spin-up Behavior Following Two Large Glitches in the Crab Pulsar, and the Statistics of Such Processes

Author

Ge, M. Y., primary, Zhang, S. N., additional, Lu, F. J., additional, Li, T. P., additional, Yuan, J. P., additional, Zheng, X. P., additional, Huang, Y., additional, Zheng, S. J., additional, Chen, Y. P., additional, Chang, Z., additional, Tuo, Y. L., additional, Cheng, Q., additional, Güngör, C., additional, Song, L. M., additional, Xu, Y. P., additional, Cao, X. L., additional, Chen, Y., additional, Liu, C. Z., additional, Zhang, S., additional, Qu, J. L., additional, Bu, Q. C., additional, Cai, C., additional, Chen, G., additional, Chen, L., additional, Chen, M. Z., additional, Chen, T. X., additional, Chen, Y. B., additional, Cui, W., additional, Cui, W. W., additional, Deng, J. K., additional, Dong, Y. W., additional, Du, Y. Y., additional, Fu, M. X., additional, Gao, G. H., additional, Gao, H., additional, Gao, M., additional, Gu, Y. D., additional, Guan, J., additional, Guo, C. C., additional, Han, D. W., additional, Hao, L. F., additional, Huo, J., additional, Jia, S. M., additional, Jiang, L. H., additional, Jiang, W. C., additional, Jin, C. J., additional, Jin, J., additional, Jin, Y. J., additional, Kong, L. D., additional, Li, B., additional, Li, D., additional, Li, C. K., additional, Li, G., additional, Li, M. S., additional, Li, W., additional, Li, X., additional, Li, X. B., additional, Li, X. F., additional, Li, Y. G., additional, Li, Z. W., additional, Li, Z. X., additional, Liu, Z. Y., additional, Liang, X. H., additional, Liao, J. Y., additional, Liu, G. Q., additional, Liu, H. W., additional, Liu, X. J., additional, Liu, Y. N., additional, Lu, B., additional, Lu, X. F., additional, Luo, Q., additional, Luo, T., additional, Ma, X., additional, Meng, B., additional, Nang, Y., additional, Nie, J. Y., additional, Ou, G., additional, Sai, N., additional, Shang, R. C., additional, Song, X. Y., additional, Sun, L., additional, Tan, Y., additional, Tao, L., additional, Wang, C., additional, Wang, G. F., additional, Wang, J., additional, Wang, J. B., additional, Wang, M., additional, Wang, N., additional, Wang, W. S., additional, Wang, Y. D., additional, Wang, Y. S., additional, Wen, X. Y., additional, Wen, Z. G., additional, Wu, B. B., additional, Wu, B. Y., additional, Wu, M., additional, Xiao, G. C., additional, Xiao, S., additional, Xiong, S. L., additional, Xu, Y. H., additional, Yan, W. M., additional, Yang, J. W., additional, Yang, S., additional, Yang, Y. J., additional, Yi, Q. B., additional, Yin, Q. Q., additional, You, Y., additional, Yue, Y. L., additional, Zhang, A. M., additional, Zhang, C. M., additional, Zhang, D. P., additional, Zhang, F., additional, Zhang, H. M., additional, Zhang, J., additional, Zhang, T., additional, Zhang, W. C., additional, Zhang, W., additional, Zhang, W. Z., additional, Zhang, Y., additional, Zhang, Y. F., additional, Zhang, Y. J., additional, Zhang, Z., additional, Zhang, Z. L., additional, Zhao, H. S., additional, Zhao, X. F., additional, Zheng, W., additional, Zhou, D. K., additional, Zhou, J. F., additional, Zhou, X., additional, Zhuang, R. L., additional, Zhu, Y. X., additional, and Zhu, Y., additional

Published

2020

49. The Evolution of the Broadband Temporal Features Observed in the Black-hole Transient MAXI J1820+070 with Insight-HXMT

Author

Wang, Yanan, primary, Ji, Long, additional, Zhang, S. N., additional, Méndez, Mariano, additional, Qu, J. L., additional, Maggi, Pierre, additional, Ge, M. Y., additional, Qiao, Erlin, additional, Tao, L., additional, Zhang, S., additional, Altamirano, Diego, additional, Zhang, L., additional, Ma, X., additional, Lu, F. J., additional, Li, T. P., additional, Huang, Y., additional, Zheng, S. J., additional, Chen, Y. P., additional, Chang, Z., additional, Tuo, Y. L., additional, Güngör, C., additional, Song, L. M., additional, Xu, Y. P., additional, Cao, X. L., additional, Chen, Y., additional, Liu, C. Z., additional, Bu, Q. C., additional, Cai, C., additional, Chen, G., additional, Chen, L., additional, Chen, T. X., additional, Chen, Y. B., additional, Cui, W., additional, Cui, W. W., additional, Deng, J. K., additional, Dong, Y. W., additional, Du, Y. Y., additional, Fu, M. X., additional, Gao, G. H., additional, Gao, H., additional, Gao, M., additional, Gu, Y. D., additional, Guan, J., additional, Guo, C. C., additional, Han, D. W., additional, Huo, J., additional, Jia, S. M., additional, Jiang, L. H., additional, Jiang, W. C., additional, Jin, J., additional, Jin, Y. J., additional, Kong, L. D., additional, Li, B., additional, Li, C. K., additional, Li, G., additional, Li, M. S., additional, Li, W., additional, Li, X., additional, Li, X. B., additional, Li, X. F., additional, Li, Y. G., additional, Li, Z. W., additional, Liang, X. H., additional, Liao, J. Y., additional, Liu, G. Q., additional, Liu, H. W., additional, Liu, X. J., additional, Liu, Y. N., additional, Lu, B., additional, Lu, X. F., additional, Luo, Q., additional, Luo, T., additional, Meng, B., additional, Nang, Y., additional, Nie, J. Y., additional, Ou, G., additional, Sai, N., additional, Shang, R. C., additional, Song, X. Y., additional, Sun, L., additional, Tan, Y., additional, Wang, G. F., additional, Wang, J., additional, Wang, W. S., additional, Wang, Y. D., additional, Wang, Y. S., additional, Wen, X. Y., additional, Wu, B. B., additional, Wu, B. Y., additional, Wu, M., additional, Xiao, G. C., additional, Xiao, S., additional, Xiong, S. L., additional, Yang, J. W., additional, Yang, S., additional, Yang, Y. J., additional, Yi, Q. B., additional, Yin, Q. Q., additional, You, Y., additional, Zhang, A. M., additional, Zhang, C. M., additional, Zhang, F., additional, Zhang, H. M., additional, Zhang, J., additional, Zhang, T., additional, Zhang, W. C., additional, Zhang, W., additional, Zhang, W. Z., additional, Zhang, Y., additional, Zhang, Y. F., additional, Zhang, Y. J., additional, Zhang, Z., additional, Zhang, Z. L., additional, Zhao, H. S., additional, Zhao, X. F., additional, Zhou, D. K., additional, Zhou, J. F., additional, Zhuang, R. L., additional, Zhu, Y. X., additional, Zhu, Y., additional, and Wang, Lingjun, additional

Published

2020

50. A search for promptγ-ray counterparts to fast radio bursts in the Insight-HXMT data

Author

Guidorzi, C., primary, Marongiu, M., additional, Martone, R., additional, Nicastro, L., additional, Xiong, S. L., additional, Liao, J. Y., additional, Li, G., additional, Zhang, S. N., additional, Amati, L., additional, Frontera, F., additional, Orlandini, M., additional, Rosati, P., additional, Virgilli, E., additional, Zhang, S., additional, Bu, Q. C., additional, Cai, C., additional, Cao, X. L., additional, Chang, Z., additional, Chen, G., additional, Chen, L., additional, Chen, T. X., additional, Chen, Y. B., additional, Chen, Y. P., additional, Cui, W., additional, Cui, W. W., additional, Deng, J. K., additional, Dong, Y. W., additional, Du, Y. Y., additional, Fu, M. X., additional, Gao, G. H., additional, Gao, H., additional, Gao, M., additional, Ge, M. Y., additional, Gu, Y. D., additional, Guan, J., additional, Guo, C. C., additional, Han, D. W., additional, Huang, Y., additional, Huo, J., additional, Jia, S. M., additional, Jiang, L. H., additional, Jiang, W. C., additional, Jin, J., additional, Jin, Y. J., additional, Kong, L. D., additional, Li, B., additional, Li, C. K., additional, Li, M. S., additional, Li, T. P., additional, Li, W., additional, Li, X., additional, Li, X. B., additional, Li, X. F., additional, Li, Y. G., additional, Li, Z. W., additional, Liang, X. H., additional, Liu, B. S., additional, Liu, C. Z., additional, Liu, G. Q., additional, Liu, H. W., additional, Liu, X. J., additional, Liu, Y. N., additional, Lu, B., additional, Lu, F. J., additional, Lu, X. F., additional, Luo, Q., additional, Luo, T., additional, Ma, R. C., additional, Ma, X., additional, Meng, B., additional, Nang, Y., additional, Nie, J. Y., additional, Ou, G., additional, Qu, J. L., additional, Sai, N., additional, Shang, R. C., additional, Song, L. M., additional, Song, X. Y., additional, Sun, L., additional, Tan, Y., additional, Tao, L., additional, Tuo, Y. L., additional, Wang, C., additional, Wang, G. F., additional, Wang, J., additional, Wang, W. S., additional, Wang, Y. S., additional, Wen, X. Y., additional, Wu, B. Y., additional, Wu, B. B., additional, Wu, M., additional, Xiao, G. C., additional, Xiao, S., additional, Xu, Y. P., additional, Yang, J. W., additional, Yang, S., additional, Yang, Y. J., additional, Yi, Q. B., additional, Yin, Q. Q., additional, You, Y., additional, Zhang, A. M., additional, Zhang, C. M., additional, Zhang, F., additional, Zhang, H. M., additional, Zhang, J., additional, Zhang, T., additional, Zhang, W. C., additional, Zhang, W., additional, Zhang, W. Z., additional, Zhang, Y., additional, Zhang, Y. F., additional, Zhang, Y. J., additional, Zhang, Z., additional, Zhang, Z. L., additional, Zhang, H. S., additional, Zhang, X. F., additional, Zheng, S. J., additional, Zhou, D. K., additional, Zhou, J. F., additional, Zhu, Y. X., additional, Zhu, Y., additional, and Zhuang, R. L., additional

Published

2020