Your search keyword '"ZHAO, Zijian"' showing total 6 results

1. Ground calibration result of the Lobster Eye Imager for Astronomy

Author

Cheng, Huaqing, Ling, Zhixing, Zhang, Chen, Sun, Xiaojin, Sun, Shengli, Liu, Yuan, Dai, Yanfeng, Jia, Zhenqing, Pan, Haiwu, Wang, Wenxin, Zhao, Donghua, Chen, Yifan, Cheng, Zhiwei, Fu, Wei, Han, Yixiao, Li, Junfei, Li, Zhengda, Ma, Xiaohao, Xue, Yulong, Yan, Ailiang, Zhang, Qiang, Wang, Yusa, Yang, Xiongtao, Zhao, Zijian, and Yuan, Weimin

Published

2024

2. The 100-m X-ray test facility at IHEP

Author

Wang, Yusa, Zhao, Zijian, Hou, Dongjie, Yang, Xiongtao, Chen, Can, Li, Xinqiao, Zhu, Yuxuan, Zhao, Xiaofan, Ma, Jia, Xu, He, Chen, Yupeng, Wang, Guofeng, Lu, Fangjun, Zhang, Shuangnan, Zhang, Shu, Chen, Yong, and Xu, Yupeng

Published

2023

3. Design and testing of the Optics for FXT onboard EP satellite.

Author

Yang, Yanji, Wang, Yusa, Han, Dawei, Wang, Juan, Cui, Weiwei, Zhu, Yuxuan, Cong, Min, Ma, Jia, Zhao, Zijian, Hou, Dongjie, Yang, Xiongtao, Chen, Can, Lu, Bing, Lv, He, Sun, Wenxin, Zhang, Jiawei, Yu, Ke, Wang, Shaohuai, Liu, Dongxu, and Zhang, Qian

Subjects

PARTICLE physics, OPTICS, FOCAL planes, FOCAL length, X-ray telescopes, MIRRORS

Abstract

The Einstein Probe (EP) mission is a science mission designed for the time domain astronomy, which is approved by the Chinese Academy of Sciences (CAS) in 2017 and is to be launched in 2023 with a duration time of more than 3 years. The Follow-up X-ray Telescope (FXT) is an important payload onboard EP, which employs the Wolter I focusing mirror as the X-ray collection unit and the PNCCD as the focal plane detector. The Phase C study has been finished in 2021. During the Phase C, the structural and thermal model (STM) of the mirror assembly of FXT, provided by the European Space Agency (ESA), a mirror assembly developed by the Institute of High Energy Physics (IHEP), a qualification model (QM) PNCCD and other components, are integrated and tested in IHEP. All optical performances meet the goal requirement of EP, such as the field of view of 60 arcmins, the angular resolution of less than 30 arcsec HEW on-axis, and the focal length of ab. 1600 mm. After that, the FXT is assembled, integrated, and tested on the EP satellite platform. Furthermore, these performances are not changed after the mechanical and thermal tests on the spacecraft platform. [ABSTRACT FROM AUTHOR]

Published

2023

4. X-ray optics test and calibration of the Einstein Probe Follow-up telescope.

Author

Friedrich, Peter, Stieglitz, Veronika, Burwitz, Vadim, Eder, Josef, Dennerl, Konrad, Hartner, Gisela, Langmeier, Andreas, Müller, Thomas, Rukdee, Surangkhana, Schmidt, Thomas, Chen, Yong, Wang, YuSa, Hou, DongJie, Zhao, ZiJian, Zhao, XiaoFan, Xu, JingJing, Cui, WeiWei, Keermann, Arnoud, Kuulkers, Erik, and Santovincenzo, Andrea

Subjects

*PARTICLE physics, *X-ray telescopes, *VIBRATION tests, *TELESCOPES, *THOMSON scattering, *CALIBRATION, *X-ray optics, *NEUTRINO detectors

Abstract

The Follow-up X-ray telescope (FXT) is one of the instruments on board the Einstein Probe (EP) satellite of the Chinese Academy of Sciences (CAS) which was launched in January 2024. The EP mission is dedicated to the study of time-domain high-energy astrophysics, utilising a lobster-eye-based wide-field telescope, complemented by an eROSITA-like optics for follow-up observations. Max Planck Institute for Extraterrestrial Physics (MPE) has provided hardware and conducted measurement campaigns at its test facilities as part of a European contribution to Einstein Probe by ESA, and in addition the eROSITA flight spare mirror assembly as the second FXT module. Three FXT mirror assemblies – structural-thermal, qualification and flight models – have been manufactured. All components underwent acceptance testing using X-rays, followed by the installation of X-ray baffles for stray-light rejection. Subsequently, they underwent environmental tests and X-ray performance evaluations. The final tests of the qualification model, serving as a flight spare, and the flight model included an X-ray calibration at various photon energies ranging from about 0.3 keV to 8 keV. All tests were performed at MPE's test facilities: the laboratory for vibration and thermal-vacuum testing, and the PANTER X-ray facility. Reported are the setups and the results of the respective test sequences, focusing on the qualification and flight mirror assemblies. After delivery to China, all mirror assemblies were subjected to complementary measurements in the X-ray test facility of the Institute for High Energy Physics (IHEP) of CAS. • Design of the Follow-up X-ray telescope (FXT) on Einstein Probe. • FXT model philosophy and test matrix. • FXT X-ray test and calibration results. [ABSTRACT FROM AUTHOR]

Published

2024

5. Optical design and simulation of Einstein Probe satellite follow-up x-ray telescope.

Author

Zhu, Yuxuan, Lu, Jingbin, Yang, Yangji, Cong, Min, Sheng, Lizhi, Qiang, Pengfei, Cui, Weiwei, Zhang, Ziliang, Wang, Yusa, Han, Dawei, Li, Wei, Wang, Juan, Huo, Jia, Li, Maoshun, Zhao, Xiaofan, Yu, Nian, Song, Zeyu, Ma, Jia, Lv, Zhonghua, and Zhao, Zijian

Subjects

MONTE Carlo method, X-ray telescopes, OPTICAL mirrors

Abstract

The Follow-up X-ray Telescope (FXT), a key payload onboard the Einstein Probe sallite (EP), is equipped with a Wolter-I x-ray focusing mirror system. We introduce the principle of such a mirror system and analyze the influence of the mirror gap in the multishell nested mirror of the FXT on the effective area, stray-light ratio, and vignetting. To ensure that no occlusion occurs within adjacent shells and minimize stray-light ratio, the size of the gap is set to a optimized value for corresponding shell. We finished a design of a 54-shell mirror system according to these results. The optical performance of the design was then simulated using a Monte Carlo algorithm and the ray-tracing principle. The simulation shows that the effective area is 414.5 ± 0.2 cm2 at 1.25 keV (considering the spider), and the field of view is 64 arcmin in diameter. These parameters meet the optical requirements of the FXT. [ABSTRACT FROM AUTHOR]

Published

2021

6. Performance of a focal plane detector for soft X-ray imaging spectroscopy based on back-illuminated sCMOS.

Author

Chen, Can, Wang, Yusa, Xu, Yupeng, Zhao, Zijian, Qiu, Hongyun, Hou, Dongjie, Yang, Xiongtao, Ma, Jia, Chen, Yong, Zhao, Yang, Liu, Hua, Zhao, Xiaofan, and Zhu, Yuxuan

Subjects

*FOCAL planes, *SPECTRAL imaging, *X-ray spectroscopy, *X-ray fluorescence, *X-ray imaging, *X-ray telescopes, *X-ray detection

Abstract

Spectroscopy focusing array (SFA) and polarimetry focusing array (PFA) are the two major payloads of the enhanced X-ray Timing and Polarimetry mission (eXTP). Nested Wolter-I X-ray mirror module is implemented in SFA and PFA to achieve a high effective area. When evaluating the properties of the mirror module, the alignment of the optical axis of the X-ray mirror module and a quasi-parallel X-ray beam is a prerequisite for ensuring accuracy of the results. To assist the alignment of the X-ray mirror module, an X-ray focal plane detector with one of the largest detection areas, is designed based on a back-illuminated scientific complementary metal–oxide–semiconductor transistor (sCMOS) sensor(GSENSE6060BSI; Gpixel Inc). Then the characteristics of readout noise, dark current, and split-pixel event properties of the detector are studied with the self-developed multi-target fluorescence X-ray source in a 100-m long X-ray test facility. The energy calibration is performed based on the single-pixel event, and the energy non-linearity of the detector is also observed. Finally, based on the optical model, the eXTP mirror module is simulated, and the alignment test of the Wolter-I X-ray mirror module designed for Einstein Probe/Follow-up X-ray Telescope via the "Burkert test" method is demonstrated. [ABSTRACT FROM AUTHOR]

Published

2022