刘长卿-山东大学空间科学研究院行星科学研究中心

简介：

刘长卿，山东大学（威海）空间科学与物理学院博士后。主要从事月球与行星表面物质成分反演研究研究，研究工作包括激光诱导击穿光谱技术（LIBS）光谱库构建及元素反演、火星黄钾铁矾等硫酸盐结构与光谱特征研究、火星次生矿物及蚀变过程研究。目前发表学术论文19篇。

研究领域：行星科学

邮箱/电话：liucq@mail.sdu.edu.cn

地址(房间号)：闻天楼（南）420

职称：博士后

主要学习和进修经历：

1、2011/9-2015/7，天津大学，电子信息工程学院，电子科学与技术（微电子），工学学士

2、2015/9-2018/7，山东大学（威海），空间科学与物理学院，空间物理学，理学硕士

3、2018/9-2022/9，山东大学（威海），空间科学与物理学院，地球物理学，理学博士

参加国际会议：

2016年6月，第三届月球与行星科学国际研讨会（ISLPS2016），会议论文1篇，并作墙报展示；

2016年10月，2016年中国地球科学联合学术年会，会议论文1篇，并作墙报展示；

2017年9月，第三届北京月球与深空探测国际研讨会（LDSE），发表会议论文1篇，并作口头报告；

2018年3月，第49届月球与行星科学研讨会（LPSC），会议论文1篇，并作墙报展示；

2019年3月，第50届月球与行星科学研讨会（LPSC），会议论文1篇，并作墙报展示；

2020年3月，第51届月球与行星科学研讨会（LPSC），会议论文2篇，并作墙报展示；

2021年3月，第52届月球与行星科学研讨会（LPSC），会议论文2篇，并作墙报展示；

2022年3月，第53届月球与行星科学研讨会（LPSC），会议论文1篇，并作口头报告。

发表学术论文：

[1] Changqing Liu, Zongcheng Ling*, Fengke Cao, Jian Chen. Comparative Raman and visible near-infrared spectroscopic studies of jarosite endmember mixtures and solid solutions relevant to Mars. Journal of Raman Spectroscopy, 2017, 48(11): 1676-1684.

[2] Liu CQ, Ling ZC*, Wu ZC, et al. Composition and mineralogy of martian materials at Tianwen-1 landing site: new constraints on the geologic history of the Vastitas Borealis Formation[J]. Communications Earth & Environment, 2022, in revision.

[3] Liu CQ, Ling ZC*, Zhang J*, et al. Laboratory Raman and VNIR spectroscopic studies of jarosite and other secondary mineral mixtures relevant to Mars[J]. Journal of Raman Spectroscopy, 2020, 51(9): 1575-1588.

[4] Liu CQ, Ling ZC*, Zhang J, et al. A Stand-Off Laser-Induced Breakdown Spectroscopy (LIBS) System Applicable for Martian Rocks Studies[J]. Remote Sensing, 2021, 13(23): 4773.

[5] Liu CQ, Liu L, Chen J, Cao HJ, Qu HK, Qiao L, Zhang J, Qi XB, Lu XJ, Xu R, Wang ZD, He ZP*, and Ling ZC*. Mafic mineralogy assemblages at the Chang’e-4 landing site: A combined laboratory and lunar in situ spectroscopic study[J]. Astronomy & Astrophysics, 2022, 658: A67.

[6] Liu CQ, Wu ZC, Fu XH, Liu P, Xin YQ, Xiao AY, Bai HC, Tian SK, Wan S, Liu YH, Ju EM, Jin GB, Lu XJ, Qi XB, and Ling ZC*. A Martian Analogues Library (MAL) Applicable for Tianwen-1 MarSCoDe-LIBS Data Interpretation[J]. Remote Sensing, 2022, 14(12): 2937.

[7] 凌宗成*, 刘长卿, 柏红春, 田尚可, 石二彬, 刘平, 辛艳青, 武中臣, 付晓辉, 张立, 张江. 基于激光诱导击穿光谱技术的火星表面物质成分探测研究进展[J].矿物岩石地球化学通报, 2022, 41(1): 92-112.

[8] Haijun Cao, Chen Wang, Jian Chen, Xiaochao Che, Xiaohui Fu, Yuruo Shi, Dunyi Liu, Zongcheng Ling*, Le Qiao, Xuejin Lu, Xiaobin Qi, Chengxiang Yin, Ping Liu, Changqing Liu, Yanqing Xin, Jianzhong Liu. A Raman Spectroscopic and Microimage Analysis Perspective of the Chang'e‐5 Lunar Samples[J]. Geophysical Research Letters, 2022, 49(13): e2022GL099282.

[9] Jian Chen, Zongcheng Ling*, Bradley L. Jolliff, Lingzhi Sun, Le Qiao, Jianzhong Liu, Xiaohui Fu, Jiang Zhang, Bo Li, Changqing Liu, et al. Radiative Transfer Modeling of Chang’e-4 Spectroscopic Observations and Interpretation of the South Pole-Aitken Compositional Anomaly[J]. The Astrophysical Journal Letters, 2022, 931(2): L24.

[10] Jin GB, Wu ZC, Ling ZC, Liu CQ, et al. A New Spectral Transformation Approach and Quantitative Analysis for MarSCoDe Laser-Induced Breakdown Spectroscopy (LIBS) Data[J]. Remote Sensing, 2022, 14(16): 3960.

[11] Bai HC, Bi XY, Liu CQ, et al. Spatial distributions and origin of hydrated sulfate minerals at the mineral bowl in Ophir Chasma, Mars[J]. Planetary and Space Science, 2021, 207: 105323.

[12] Qu HK, Ling ZC, Qi XB, Xin YQ, Liu CQ, Cao HJ. A Remote Raman System and Its Applications for Planetary Material Studies[J]. Sensors, 2021, 21(21): 6973.

[13] Xin YQ, Cao HJ, Liu CQ, et al. A systematic spectroscopic study of laboratory synthesized manganese oxides relevant to Mars[J]. Journal of Raman Spectroscopy, 2021. DOI: 10.1002/jrs.6231

[14] Wu ZC, Ling ZC, Zhang J, Fu XH, Liu CQ, et al. A Mars Environment Chamber Coupled with Multiple In Situ Spectral Sensors for Mars Exploration[J]. Sensors, 2021, 21(7): 2519.

[15] Fu XH, Jia LC, Wang AL, Cao HJ, Ling ZC, Liu CQ, et al. Thermal stability of akaganeite and its desiccation process under conditions relevant to Mars[J]. Icarus, 2020, 336: 113435.

[16] Qi XB, Ling ZC, Zhang J, Chen J, Cao HJ, Liu CQ, et al. Photometric Normalization of Chang’e-4 Visible and Near-Infrared Imaging Spectrometer Datasets: A Combined Study of In-Situ and Laboratory Spectral Measurements[J]. Remote Sensing, 2020, 12(19): 3211.

[17] Chen J, Ling ZC, Qiao L, He ZP, Xu R, Sun LZ, Zhang J, Li B, Fu XH, Liu CQ, Qi XB. Mineralogy of Chang’e-4 landing site: Preliminary results of visible and near-infrared imaging spectrometer[J]. Science China-Information Sciences, 2020, 63(4): 1-12.

[18] Ling ZC, Qiao L, Liu CQ, et al. Composition, mineralogy and chronology of mare basalts and non-mare materials in Von Kármán crater: landing site of the Chang’E−4 mission[J]. Planetary and Space Science, 2019, 179: 104741.

[19] Bo Li, Zongcheng Ling, Jiang Zhang, Jian Chen, Changqing Liu, Xiangyu Bi. Geological mapping of lunar highland crater Lalande: Topographic configuration, morphology and cratering process. Planetary & Space Science, 2018, 151, 85-96.