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姓名 岳宗玉 性别:
职称 研究员 学历 博士
电话 - 传真: 010-62010846
Email: yuezy@mail.iggcas.ac.cn 邮编: 100029
地址 北京朝阳区北土城西路19号,中科院地质与地球物理研究所
更多信息:
English地球与行星物理院重点实验室 比较行星学学科组
 
简历:

  岳宗玉,研究员,博士生导师,主要从事行星地质学研究。1980年出生于山东莘县。2002年于山东师范大学获学士学位,2008年于中国地质大学(北京)获博士学位。2008年7月-2022年3月在中国科学院空天信息创新研究院(原中国科学院遥感应用研究所及中国科学院遥感与数字地球研究所)任职助理研究员、副研究员、研究员,2022年4月-迄今在中国科学院地质与地球物理研究所任职研究员。曾在美国得克萨斯大学圣安东尼奥分校、普渡大学进行学习和交流访问。
  迄今已发表SCI期刊文章50余篇,其中以第一/通讯作者发表SCI期刊文章21篇,以第一作者在Nature Geoscience和Nature Astronomy发表2篇论文。荣获2015年中国科学院卢嘉锡青年人才奖,中国科学院青年创新促进会会员,《地球与行星物理论评(中英文)》青年编委。

 
研究方向:

  长期从事行星地质学研究,主要研究对象为类地行星表面的撞击坑,主要研究成果:(1)通过对月球哥白尼撞击坑形成过程的数值模拟指出其中央峰橄榄岩起源于陨石残留物,否认了起源于月球深部的传统观点;(2)利用我国嫦娥五号样品的同位素年龄更新了月球年代函数模型,并将其推广到火星。
  目前的研究主要聚焦于以下三个方面:
  1. 类地行星表面典型地貌遥感观测及对比研究
  2. 类地行星表面撞击坑的形成过程与机制研究
  3. 类地行星表面撞击坑统计定年理论与应用研究

 
学科类别:
行星地质学
 
职务:
 
社会任职:
 
获奖及荣誉:
  1. 中国科学院卢嘉锡青年人才奖(2015年)
 
承担科研项目情况:
  1. 月球东海盆地形成过程三维数值模拟及科学分析(2020.1-2023.12),国家自然科学基金面上项目(41972321);
  2. 类地行星撞击三维成坑机制及效应(2020.1-2024.12),中国科学院战略性先导科技专项(B类)类地行星的形成演化及其宜居性(XDB41000000)子课题;
 
代表论著:

第一作者/通讯作者:

  1. Yue, Z., Di, K., Wan, W., Liu, Z., Gou, S., Liu, B., Peng, M., Wang, Y., Jia, M., Liu, J., Ouyang, Z. Updated lunar cratering chronology model with the radiometric age of Chang'e-5 samples. Nature Astronomy, 2022, 6, 541–545.
  2. Yue, Z., Shi, K., Michael, G., Di, K., Gou, S., Liu, J., Niu, S. Chronology of the basalt units surrounding Chang’e-4 landing area. Remote Sensing, 2022, 14, 49.
  3. Yue, Z., Yang, M., Jia, M., Michael, G., Di, K., Gou, S., Liu, J. Refined model age for Orientale Basin derived from zonal crater dating of its ejecta, Icarus, 2020, 346, 113804.
  4. Yue, Z., Di, K., Liu, Z., Michael, G., Jia, M., Xin, X., Liu, B., Peng, M., Liu, J. Lunar regolith thickness deduced from concentric craters in the CE-5 landing area. Icarus, 2019, 329, 46-54.
  5. Yue, Z., Michael, G., Di, K., Liu, J. Global survey of lunar wrinkle ridge formation times. Earth and Planetary Science Letters, 2017, 447, 14-20.
  6. Yue, Z., Di, K. Hydrocode simulation of the impact melt layer distribution underneath Xiuyan crater, China. Journal of Earth Science, 2017, 28, 180-186.
  7. Yue, Z., Li, W., Di, K., Liu, Z., Liu, J. Global mapping and analysis of lunar wrinkle ridges. Journal of Geophysical Research: Planets, 2015, 120, 978-994.
  8. Yue, Z., Hu, W., Liu, B., Liu, Y., Sun, X., Zhao, Q., Di, K. Quantitative analysis of the morphology of martian gullies and insights into their formation. Icarus, 2014, 243, 208-221.
  9. Yue, Z., Johnson, B. C., Minton, D. A., Melosh, H. J., Di, K., Hu, W., Liu, Y. Projectile remnants in central peaks of lunar impact craters. Nature Geoscience, 2013, 6, 435-437.
  10. Yue, Z., Xie, H., Di, K, Ouyang, Z. Mapping lunar olivine using Clementine spectral indices and chemical composition parameters. Acta Geologica Sinica (English edition), 2012, 86, 65-72.
  11. Yue, Z., Liu, J., Wu, G. Automated detection of lunar craters based on object-oriented approach. Chinese Science Bulletin, 2008, 53, 3699-3704.
  12. Yue, Z., Ouyang, Z., Li, H., Liu, J., Wu, G. The origin and geological significance of lunar ridges. Chinese Journal of Geochemistry, 2007, 26, 418-424.
  13. Shi, K., Yue, Z., Di, K., Liu, J., Dong, Z. The gardening process of lunar regolith by small impact craters: A case study in Chang’E-4 landing area. Icarus, 2022, 377, 114908. (通讯作者)
  14. Michael, G., Yue, Z., Gou, S., Di, K. Dating individual several-km lunar impact craters from the rim annulus in region of planned Chang'E-5 landing: Poisson age-likelihood calculation for a buffered crater counting area. Earth and Planetary Science Letters, 2021, 568, 117031. (通讯作者)
  15. Liu, J., Yue, Z., Di, K., Gou, S., Niu, S. A study about the temporal constraints on the Martian yardangs’ development in Medusae Fossae Formation. Remote Sensing, 2021, 13, 1316-1329. (通讯作者)
  16. Gou, S., Di, K., Yue, Z., Liu, Z., He, Z., Xu, R., Liu, B., Peng, M., Wan, W., Wang, Y., Liu, J. Forsteritic olivine and magnesium-rich orthopyroxene materials measured by Chang’e-4 rover. Icarus, 2020, 345, 113776. (通讯作者)
  17. Gou, S., Di, K., Yue, Z., Liu, Z., He, Z., Xu, R., Lin, H., Liu, B., Peng, M., Wan, W., Wang, Y., Liu, J. Lunar deep materials observed by Chang’e-4 rover. Earth and Planetary Science Letters, 2019, 528, 115829. (通讯作者)
  18. Jia, M., Yue, Z., Di, K., Liu, B., Liu, J. A reanalysis of the relationship between the size of boulders and craters in lunar surface. Icarus, 2019, 331, 116-126. (通讯作者)
  19. Liu, Z., Yue, Z., Michael, G., Gou, S., Di, K., Sun, S., Liu, J. A global database and statistical analyses of (4) Vesta craters. Icarus, 2018, 311: 242-257. (通讯作者)
  20. Sun, S., Yue, Z., Di, K. Investigation of the depth and diameter relationship of subkilometer-diameter lunar craters. Icarus, 2018, 309, 61-68. (通讯作者)
  21. Di, K., Sun, S., Yue, Z., Liu, B. Lunar regolith thickness determination from 3D morphology of small fresh craters. Icarus, 2016, 267, 12-23. (通讯作者)
  22. Di, K., Li, W., Yue, Z., Sun, Y., Liu, Y. A machine learning approach to crater detection from topographic data. Advances in Space Research, 2014, 54, 2419-2429. (通讯作者)
  23. 岳宗玉, 邸凯昌, 刘建忠. 行星表面撞击坑统计定年原理及应用. 矿物岩石地球化学通报, 2021, 40, 1130-1142.
  24. 岳宗玉, 邸凯昌, 刘召芹, 胡文敏, 芶盛. 撞击坑数值模拟中状态方程替代原则及误差分析. 地学前缘, 2014, 21, 204-211.
  25. 岳宗玉, 邸凯昌, 张平. 月表撞击坑形成过程数值模拟理论与方法. 地学前缘, 2012, 19, 110-117.
  26. 岳宗玉, 邸凯昌. 好奇心号巡视器及其特点分析. 航天器工程, 2012, 12, 110-116.
  27. 岳宗玉, 谢红接, 刘建忠, 欧阳自远. 火星表面沙丘中冲沟的成因及对撞击坑壁冲沟成因的启发. 地球科学-中国地质大学学报, 2010, 35, 291-301.
  28. 岳宗玉, 刘建忠, 吴淦国. 应用面向对象分类方法对月球撞击坑进行自动识别. 科学通报, 2008, 53, 2809-2813.
  29. 岳宗玉, 吴淦国, 刘建忠, 欧阳自远. 地月系统不同成因环形构造及其影像特征. 矿物学报, 2006, 26, 441-447.
  30. 岳宗玉, 刘建忠, 吴淦国, 欧阳自远. 地球的原始不均一性起源及其对超大型矿床分布的制约. 矿物岩石地球化学学报, 2005, 24, 357-362.
  31. 史珂, 岳宗玉, 邸凯昌, 刘建忠, 牛胜利. Apollo11和嫦娥四号着陆区撞击坑退化对比分析. 矿物岩石地球化学通报, 2021, 40, 711-719. (通讯作者)
  32. 阳梅萍, 岳宗玉, 邸凯昌, 万文辉, 刘建忠, 史珂. 基于全景相机数据的嫦娥四号着陆区次级坑统计分析. 矿物岩石地球化学通报, 2021, 40, 720-729. (通讯作者)

    合作作者文章:
  33. Bo, Z., Di, K., Liu, Z., Yue, Z., Liu, J., Shi, K. A catalogue of meter-scale impact craters in the Chang’e-5 landing area measured from centimeter-resolution descent imagery. Icarus, 2022, 378, 114943.
  34. Niu, S., Zhang, F., Di, K., Gou, S., Yue, Z. Layered ejecta craters in the candidate landing areas of China's first Mars mission (Tianwen-1): Implications for subsurface volatile concentrations. Journal of Geophysical Research: Planets, 2022, 127, e2021JE007089.
  35. Li, H., Zhang, N., Yue, Z., Zhang, Y. Lunar cratering asymmetries with high orbital obliquity and inclination of the Moon. Research in Astronomy and Astrophysics, 2021, 21, 140.
  36. Gou, S., Yue, Z., Di, K., Bugiolacchi, R., Wan, W., Yang, M., Ye, L. Geologically old but freshly exposed rock fragments encountered by Yutu-2 rover. Journal of Geophysical Research: Planets, 2021, 126, e2020JE006565.
  37. Gou, S., Yue, Z., Di, K., Bugiolacchi, R., Zhu, M., Pinet, P., Cai, Z. Mare basalt flooding events surrounding Chang’e-4 landing site as revealed by Zhinyu crater ejecta. Icarus, 2021, 360, 114370.
  38. Jia, M., Di, K., Yue, Z., Liu, B., Wan, W., Niu, S., Liu, J., Cheng, W., Lin, Y. Multi-scale morphologic investigation of craters in the Chang'e-4 landing area. Icarus, 2021, 355, 114164.
  39. Gou, S., Yue, Z., Di, K., Cai, Z., Liu, Z., Niu, S. Absolute model age of lunar Finsen crater and geologic implications. Icarus, 2021, 354, 114046.
  40. Zhang, J., Zhou, B., Lin, Y., Zhu, M., Song, H., Dong, Z., Gao, Y., Di, K., Yang, W., Lin, H., Yang, J., Liu, E., Wang, L., Lin, Y., Li, C., Yue, Z., Yao, Z., Ouyang, Z. Lunar regolith and substructure at Chang'E-4 landing site in South Pole-Aitken basin. Nature Astronomy, 2021, 5, 25-30.
  41. Gou, S., Yue, Z., Di, K., Wang, J., Wan, W., Liu, Z., Liu, B., Peng, M., Wang, Y., He, Z., Xu, R. Impact melt breccia and surrounding regolith measured by Chang’e-4 rover. Earth and Planetary Science Letters, 2020, 544, 116378.
  42. Liu, J., Di, K., Gou, S., Yue, Z., Liu, B., Xiao, J., Liu, Z. Mapping and spatial statistical analysis of Mars Yardangs. Planetary and Space Science, 2020, 192, 105035.
  43. Li, B., Zhang, J., Yue, Z., Yao, P., Li, C., Chen, S., Qiao, L., Fu, X., Ling, Z., Chen, J., Liu, S. Deriving terrain factors from high-resolution lunar images: A case study of the Mons Rümker Region. Geomorphology, 2020, 358, 107114.
  44. Gou, S., Yue, Z., Di, K., Wan, W., Liu, Z., Liu, B., Peng, M., Wang, Y., He, Z., Xu, R. In situ spectral measurements of space weathering by Chang’e-4 rover. Earth and Planetary Science Letters, 2020, 535, 116117.
  45. Di, K., Liu, Z., Wan, W., Peng, M., Liu, B., Wang, Y., Gou, S., Yue, Z. Geospatial technologies for Chang’e-3 and Chang’e-4 lunar rover missions. Geo-spatial Information Science, 2020, 23, 87-97.
  46. Liu, Z., Di, K., Li, J., Xie, J., Cui, X., Xi, L., Wan, W., Peng, M., Liu, B., Wang, Y., Gou, S., Yue, Z., Yu, T., Li, L., Wang, J., Liu, C., Xin, X., Jia, M., Bo, Z., Liu, J., Wang, R., Niu, S., Zhang, K., You, Y., Liu, B., Liu, J. Landing site topographic mapping and rover localization for Chang’e-4 mission. Science China Information Sciences, 2020, 63, 170-181.
  47. Jia, M., Yue, Z., Di, K., Liu, B., Liu, J., Michael, G. A catalogue of impact craters larger than 200 m and surface age analysis in the Chang’e-5 landing area. Earth and Planetary Science Letters, 2020, 541, 116272.
  48. Xin, X., Liu, B., Di, K., Yue, Z., Gou, S. Geometric quality assessment of Chang’e-2 global DEM product. Remote Sensing, 2020, 12, 526-546.
  49. Di, K., Zhu, M., Yue, Z., Lin, Y., Wan, W., Liu, Z., Gou, S., Liu, B., Peng, M., Wang, Y., Niu, S., Zhang, J., Li, J., Xie, J., Xi, L., Yang, J., Xue, B. Topographic evolution of Von Kármán crater revealed by the Lunar Rover Yutu-2. Geophysical Research Letters, 2019, 46, 12764-12770.
  50. Di, K., Jia, M., Xin, X., Wang, J., Liu, B., Li, J., Xie, J., Liu, Z., Peng, M., Yue, Z., Liu, J., Chen, R., Zhang, C. High-resolution large-area digital orthophoto map generation using LROC NAC images. Photogrammetric Engineering and Remote Sensing, 2019, 85, 481-491.
  51. Gou, S., Yue, Z., Di, K., Xu, Y. Comparative study between rivers in Tarim Basin in northwest China and Evros Vallis on Mars. Icarus, 2019, 328, 127-140.
  52. Li, B., Yue, Z., Zhang, J., Fu, X., Ling, Z., Chen, S., Chen, J., Yao, P. High-resolution terrain analysis for lander safety landing and rover path planning based on lunar reconnaissance orbiter narrow angle camera images: A case study of China's Chang’e4 probe. Earth and Space Science, 2019, 6, 398-410.
  53. Dang, Y. N., Xiao, L., Xu, Y., Zhang, F., Huang, J., Wang, J., Zhao, J. N., Komatsu, G., Yue, Z. The polygonal surface structures in the Dalangtan Playa, Qaidam Basin, NW China: Controlling factors for their formation and implications for analogous Martian landforms. Journal of Geophysical Research: Planets, 2018, 123, 1910-1933.
  54. Gou, S., Yue, Z., Di, K., Liu, Z. A global catalogue of Ceres impact craters ≥1 km and preliminary analysis. Icarus, 2017, 302, 296-307.
  55. Xin, X., Di, K., Wang, Y., Wan, W., Yue, Z. Automated detection of new impact sites on Martian surface from HiRISE images. Advances in Space Research, 2017, 60, 1557-1569.
  56. Xin, X., Liu, B., Di, K., Zhu, Z., Zhao, Z., Liu, J., Yue, Z., Zhang, G. Monitoring urban expansion using time series of night time light data a case study in Wuhan China. International Journal of Remote Sensing, 2017, 6, 1-19.
  57. Di, K., Xu, B., Peng, M., Yue, Z., Liu, Z., Wan, W., Li, L., Zhou, J. Rock size-frequency distribution analysis at the Chang’E-3 landing site. Planetary and Space Science, 2016, 20, 103-112.
  58. Li, W., Di, K., Yue, Z., Liu, Y., Sun, S. Automated Detection of Martian Gullies from HiRISE Imagery. Photogrammetric Engineering and Remote Sensing, 2015, 81, 913-920.
  59. Li, L., Yue, Z., Di, K., Peng, M. Observations of Martian layered ejecta craters and constraints on their formation mechanisms. Meteoritics & Planetary Science, 2015, 50, 508-522.
  60. Gou, S., Yue, Z., Di, K., Wang, J. Mineral abundances and different levels of alteration around Mawrth Vallis, Mars. Geosciences Frontiers, 2014, 6,741-758.
  61. Di, K., Yue, Z., Liu, Z., Wang, S. Automated rock detection and shape analysis from Mars rover imagery and 3D point cloud data. Journal of Earth Science, 2012, 24, 125-135.
  62. Di, K., Liu, Z., Yue, Z. Mars rover localization based on feature matching between ground and orbital imagery. Photogrammetric Engineering and Remote Sensing, 2011, 77, 781-791.
  63. Li, Y., Liu, J., Zou, Y., Ouyang, Z., Zheng, Y., Yue, Z. Two lunar mare soil simulants. Acta Geologica Sinica (English edition), 2011, 85, 1016-1021.
  64. Li, Y., Liu, J., Yue, Z. NAO-1: Lunar highland soil simulant developed in China. Journal of Aerospace Engineering, 2009, 22, 53-57.
  65. Xie, H., Guan, H., Zhu, M., Thueson, M., Ackley, S. F., Yue, Z. A conceptual model for explanation of albedo changes in Martian craters. Planetary and Space Science, 2008, 56, 887-894.
  66. 芶盛, 岳宗玉, 邸凯昌, 牛胜利. 火星伊西底斯平原的壁垒撞击坑: 遥感分析及环境启示意义. 遥感学报, 2021, 25, 1374-1384.
  67. 邸凯昌, 刘斌, 辛鑫, 岳宗玉, 叶乐佳. 月球轨道器影像摄影测量制图进展及应用. 测绘学报, 2019, 48, 1562-1574.
  68. 邸凯昌, 刘召芹, 刘斌, 万文辉, 彭嫚, 王晔昕, 芶盛, 岳宗玉, 辛鑫, 贾萌娜, 牛胜利. 多源数据的嫦娥四号着陆点定位. 遥感学报, 2019, 23, 177-184.
  69. 刘佳, 辛鑫, 刘斌, 邸凯昌, 岳宗玉, 王承安. 基于DMSPOLS夜间灯光影像的2000-2013年鄂尔多斯市城市扩张遥感制图与驱动因子分析. 国土资源遥感, 2018, 30, 166-172.
  70. 芶盛, 岳宗玉, 邸凯昌, 徐懿. 火星Evros Vallis与塔里木盆地开都河流域河网形态和水文特征比较研究. 遥感学报, 2018, 22, 313-323.
  71. 赵晓彦, 黄金河, 周一文, 岳宗玉, 李玉龙, 蒋楚生. 坡面锚索与坡脚抗滑桩联合加固边坡设计方法研究. 西南交通大学学报, 2017, 52, 489-495.
  72. 芶盛, 岳宗玉, 邸凯昌, 张霞. 火星表面含水矿物探测进展. 遥感学报, 2017, 21, 531-548.
  73. 李登峰, 胡卸文, 赵晓彦, 岳宗玉. 花岗岩残积土边坡水平拱高竖向变化规律. 西南交通大学学报, 2016, 51, 1024-1032.
  74. 贾萌娜, 邸凯昌, 岳宗玉, 孙姝娟. 火星表面亮温的时空变化特征分析. 遥感学报, 2016, 20, 632-642.
  75. 胡凯, 赵晓彦, 岳宗玉, 张京伍. 高速滑坡锁固段剪切破坏震动效应分析. 工程地质学报, 2016, 24, 258-266.
  76. 张鼎凯, 刘召芹, 邸凯昌, 岳宗玉, 刘峰, 芶盛. 基于OMEGA影像火星北极冰盖季节性变化监测. 国土资源遥感, 2016 , 28, 99-105.
  77. 李巍, 孙义威, 万文辉, 刘召芹, 胡文敏, 岳宗玉, 邸凯昌, 苗毅, 詹磊. 月面形貌仿真设计及在嫦娥三号任务中的应用. 地理研究, 2014, 33, 1040-1048.
  78. 胡文敏, 邸凯昌, 岳宗玉, 刘召芹. 嫦娥一号激光高度计数据交叉点分析与平差处理. 测绘学报, 2013, 42, 218-224.
  79. 王杰, 曾佐勋, 岳宗玉, 胡烨. 月球主要构造特征: 嫦娥一号月球影像初步研究. 空间科学学报, 2011, 31, 482-491.
  80. 邸凯昌, 岳宗玉, 刘召芹. 基于地面图像和卫星图像集成的火星车定位新方法. 航天器工程, 2010, 19, 8-16.
  81. 徐大良, 曾佐勋, 岳宗玉, 张振飞, 闫丹. 基于分形理论的火星冲沟成因机制研究. 高校地质学报, 2009, 15, 445-452.
 

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