崔峻、男、1974年9月出生,北京大学物理系学士、中国科学院国家天文台硕士、美国亚利桑那大学天文系博士、英国帝国理工大学物理系博士后。先后为南京大学天文与空间科学学院专职研究员、中国科学院国家天文台百人计划研究员、行星物理创新团组首席科学家、中国科学院大学天文与空间科学学院岗位教授、中国科学院月球与深空探测重点实验室副主任。现为中山大学大气科学学院教授、博士生导师、空间与行星科学系主任、行星环境与宜居性研究实验室主任、中国地球物理学会行星物理专业委员会主任、中国科学院比较行星学卓越创新中心执委会委员、中国高校行星科学联盟副秘书长、JGR-Planets、EPP、RAA等期刊主编/副主编/编委、同时任广东省政协委员、中国农工民主党中央专业委员会委员、澳门科技发展基金顾问、中国青少年科技教育工作者协会天文科学教育专业委员会副主任、广东省天文发展研究院顾问等。主要从事行星大气与电离层方向的研究,多年来广泛参与国内外重大深空探测项目,研究成果在国内外学术界获得广泛认可,2015年获得国家自然科学基金委杰出青年基金的资助,并获得欧洲空间局颁发的金星快车杰出贡献奖。迄今为止在国际主流SCI期刊发表论文200余篇,先后培养硕士/博士研究生及博士后30余人,获各类国家级和省部级项目资助20余项,包括国家自然科学基金委重点项目、杰出青年项目、国际地区合作交流项目、面上项目、国防科工局民用航天重点项目、澳门科技发展基金项目等。

联系方式:cuijun7@mail.sysu.edu.cn

办公地址:珠海市唐家湾镇中山大学珠海校区海琴2号A220

研究方向:

  • 行星大气逃逸与演化

  • 行星电离层结构与变化性

主持项目:

  • 行星高层大气输运过程研究:国家自然科学基金委专项基金项目,2011.1-2011.12,15万,主持

  • 月表磁异常结构与太阳风相互作用的统计分析:国家自然科学基金委面上基金项目,2012.1-2015.12,70万,主持

  • Titan逃逸层粒子速度分布函数及逃逸机制研究:国家自然科学基金委面上基金项目,2014.1-2017.12,80万,主持

  • 中国科学院Z类百人计划:中国科学院国家天文台台级调控经费,2014.3-2017.2,200万,主持

  • 火星电离层形成机制研究:国家自然科学基金委杰出青年基金项目,2016.1-2020.12,400万,主持

  • 类地行星大气中的声重波:澳门科技发展基金项目,2016.3-2019.2,223万(葡币,MOP),主持

  • 土星环状大气结构研究:国家自然科学基金委面上基金项目,2018.1-2021.12,71万,主持

  • 火星极端天气对全空间环境的影响:国防科技与工业委员会民用航天技术预先研究项目,2020.1-2022.12,430万,主持

  • 类地行星大气演化过程及其对宜居性的影响—类地行星的大气逃逸率和逃逸机制:中国科学院战略性科技先导B类专项子课题,2020.01-2024.12,280万,主持

  • 类地天体大气逃逸率与逃逸机制:国家自然科学基金委重点基金项目,2021.1-2025.12,296万,主持

  • 太阳风与火星大气多圈层耦合研究:国家自然科学基金委国际地区合作与交流项目,2023.1-2025.12,165万,主持

代表性论文:

  1. Distribution and escape of molecular hydrogen in Titan's thermosphere and exosphere, Cui, J.*, Yelle, R. V., and Volk, K., 2008, Journal of Geophysical Research - Planets, 113(E10), E10004
  2. Analysis of Titan's upper atmosphere from Cassini Ion Neutral Mass Spectrometer measurements, Cui, J.*, Yelle, R. V., Vuitton, V., Waite Jr., J. H., Kasprzak, W. T., Gell, D., Niemann, H. B., Müller-Wodarg, I. C. F., Borggren, N., Fletcher, G. G., Patrick, E. L., Raaen, E., and Magee, B. A., 2009, Icarus, 200, 581-615
  3. Diurnal variations of Titan's ionosphere, Cui, J.*, Galand, M., Yelle, R. V., Vuitton, V., Wahlund, J.-E., Lavvas, P. P., Müller-Wodarg, I. C. F., Cravens, T. E., Kaprzak, W. T., and Waite Jr., J. H., 2009, Journal of Geophysical Research – Space Physics, 114(A6), A06310
  4. Ion transport in Titan's upper atmosphere, Cui, J.*, Galand, M., Yelle, R. V., Wahlund, J.-E., Ågren, K., Waite Jr., J. H., and Dougherty, M. K., 2010, Journal of Geophysical Research – Space Physics, 115(A6), A06314
  5. Suprathermal electron spectra in the Venus ionosphere, Cui, J.*, Galand, M., Coates, A. J., Zhang, T.-L., and Müller-Wodarg, I. C. F., 2011, Journal of Geophysical Research – Space Physics, 116(A4), A04321
  6. The implications of the H2 variability in Titan’s exosphere, Cui, J.*, Yelle, R. V., Müller-Wodarg, I. C. F., Lavvas, P. P., and Galand, M., 2011, Journal of Geophysical Research – Space Physics, 116(A11), A11324
  7. The CH4 structure in Titan’s upper atmosphere revisited, Cui, J.*, Yelle, R. V., Strobel, D. F., Müller-Wodarg, I. C. F., Snowden, D. S., Koskinen, T. T., and Galand, M., 2012, Journal of Geophysical Research – Planets, 117(E11), E11006
  8. Compositional effects in Titan’s thermospheric gravity waves, Cui, J.*, Lian, Y., and Müller-Wodarg, I. C. F., 2013, Geophysical Research Letters, 40(1), 43-47
  9. Density waves in Titan’s upper atmosphere, Cui, J.*, Yelle, R. V., Li, T., Snowden, D. S., and Müller-Wodarg, I. C. F., 2014, Journal of Geophysical Research – Space Physics, 119(1), 490-518
  10. The electron thermal structure in the dayside Martian ionosphere implied by the MGS radio occultation data, Cui, J.*, Galand, M., Zhang, S.-J., Vigren, E., and Zou, H., 2015, Journal of Geophysical Research – Planets, 120(2), 278-286
  11. Day-to-night transport in the Martian ionosphere: Implications from total electron content measurements, Cui, J.*, Galand, M., Yelle, R. V., Wei, Y., and Zhang, S.-J., 2015, Journal of Geophysical Research – Space Physics, 120(3), 2333-2346
  12. The variability of HCN in Titan’s upper atmosphere implied by the Cassini Ion Neutral Mass Spectrometer measurements, Cui, J.*, Cao, Y.-T., Lavvas, P. P., and Koskinen, T. T., 2016, The Astrophysical Journal Letters, 826(1), L5
  13. The structure of Titan’s N2 and CH4 coronae, Jiang, F.-Y., Cui, J.*, and Xu, J.-Y., 2017, The Astronomical Journal, 154(6), 271
  14. The impact of crustal magnetic fields on the thermal structure of the Martian upper atmosphere, Cui, J.*, Yelle, R. V., Zhao, L.-L., Stone, S., Jiang, F.-Y., Cao, Y.-T., Yao, M.-J., Koskinen, T. T., and Wei, Y., 2018, The Astrophysical Journal Letters, 853(2), L33
  15. Ionization efficiency in the dayside Martian upper atmosphere, Cui, J.*, Wu, X.-S., Xu, S.-S., Wang, X.-D., Wellbrock, A., Nordheim, T. A., Wang, W.-R., and Wei, Y., 2018, The Astrophysical Journal Letters, 857(2), L18
  16. Photochemical escape of atomic C and N on Mars: Clues from a multi-instrument MAVEN dataset, Cui, J.*, Wu, X.-S., Gu, H., Jiang, F.-Y., and Wei, Y., 2019, Astronomy and Astrophysics, 621, A23
  17. A test particle Monte Carlo investigation of the CH4 torus around Saturn, Niu, D.-D., Cui, J.*, Gu, H., Dong, C.-Y., Zhou, L.-Y., Wellbrock, A., Jiang, F.-Y., and Xu, X.-J., 2019, The Astronomical Journal, 157(1), 15
  18. Monte Carlo calculations of the atmospheric sputtering yields on Titan, Gu, H., Cui, J.*, Niu, D.-D., Wellbrock, A., Tseng, W.-L., and Xu, X.-J., 2019, Astronomy and Astrophysics, 623, A18
  19. The morphology of the topside Martian ionosphere: Implications on bulk ion flow, Wu, X.-S., Cui, J.*, Xu, S.-S., Lillis, R.J., Yelle, R.V., Edberg, N.J.T., Vigren, E., Rong, Z.-J., Fan, K., Guo, J.-P., Cao, Y.-T., Jiang, F.-Y., Wei, Y., and Mitchell, D.L., 2019, Journal of Geophysical Research – Planets, 124(3), 734-751
  20. Evaluating local ionization balance in the nightside Martian upper atmosphere during MAVEN Deep Dip campaigns, Cui, J.*, Cao, Y.-T., Wu, X.-S., Xu, S.-S., Yelle, R.V., Stone, S., Vigren, E., Edberg, N.J.T., Shen, C.-L., He, F., and Wei, Y., 2019, The Astrophysical Journal Letters, 876(1), L12
  21. Structural variability of the cross-terminator Martian ionosphere: Implications on plasma sources, Cao, Y.-T., Cui, J.*, Wu, X.-S., and Wei, Y., 2019, Journal of Geophysical Research - Planets, 124(6), 1495-1511
  22. On the hardness of the photoelectron energy spectrum near Mars, Wu, X.-S., Cui, J.*, Cao, Y.-T., Liu, L.-J., He, F., and Wei, Y., 2019, Journal of Geophysical Research - Planets, 124(11), 2745-2753
  23. Dayside nitrogen and carbon escape on Titan: The role of exothermic chemistry, Gu, H., Cui, J.*, Lavvas, P.P., Niu, D.-D., Wu, X.-S., Guo, J.-H., He, F., and Wei, Y., 2020, Astronomy and Astrophysics, 633, A8
  24. Neutral heating efficiency in the dayside Martian upper atmosphere, Gu, H., Cui, J.*, Niu, D.-D., Cao, Y.-T., Wu, X.-S., Wu, Z.-P., Li, J., He, F., and Wei, Y., 2020, The Astronomical Journal, 159(2), 39
  25. Atomic oxygen escape on Mars driven by electron impact ionization and excitation, Zhang, Q., Gu, H., Cui, J.*, Cheng, Y.-M., He, Z.-G., Zhong, J.-H., He, F., and Wei, Y., 2020, The Astronomical Journal, 159(2), 54
  26. Energetic electron depletions in the nightside Martian upper atmosphere revisited, Niu, D.-D., Cui, J.*, Gu, H., Wu, X.-S., Wu, S.-Q., Lu, H.-Y., Chai, L.-H., and Wei, Y., 2020, Journal of Geophysical Research – Space Physics, 125(4), e27670
  27. Nitric oxide abundance in the Martian thermosphere and its diurnal variation, Cui, J.*, Fu, M.-H., Ren, Z.-P., Gu, H., Guo, J.-H., Wu, X.-S., Wu, Z.-P., Lai, H.-R., and Wei, Y., 2020, Geophysical Research Letters, 47(9), e87252
  28. Abnormal dawn-dusk asymmetry in the Martian ionosphere, Cui, J.*, Ren, Z.-P., Wu, Z.-P., Wu, X.-S., Hao, Y.-Q., and Wei, Y., 2020, The Astrophysical Journal Letters, 895(2), L43
  29. Temperature variability in Titan’s upper atmosphere: The role of wave dissipation, Wang, X., Lian, Y., Cui, J.*, Richardson, M., Wu, Z.-P., and Li, J., 2020, Journal of Geophysical Research - Planets, 125(6), e06163
  30. Photoelectrons as a tracer of planetary atmospheric composition: Application to CO on Mars, Wu, X.-S., Cui, J.*, Cao, Y.-T., He, Z.-G., He, F., and Wei, Y., 2020, Journal of Geophysical Research – Planets, 125(7), e2020JE006441
  31. Solar and magnetic control of minor ion peaks in the dayside Martian ionosphere, Huang, J.-P., Cui, J.*, Hao, Y.-Q., Guo, J.-P., Wu, X.-S., Niu, D.-D., and Wei, Y., 2020, Journal of Geophysical Research – Space Physics, 125, e2020JA028254
  32. Monte Carlo calculations of helium escape on Mars via energy transfer from hot oxygen atoms, Gu, H., Cui, J.*, Niu, D.-D., He, Z.-G., and Li, K., 2020, The Astrophysical Journal, 902, 2
  33. A survey of photoelectrons on the nightside of Mars, Cao, Y.-T., Cui, J.*, Wu, X.-S., Niu, D.-D., Lai, H.-R., Ni, B.-B., Luo, Q., J. Yu, and Wei, Y., 2021, Geophysical Research Letters, 48(2), e2020GL089998
  34. Species-dependent response of the Martian ionosphere to the 2018 global dust storm, Niu, D.-D., Cui, J.*, Wu, S.-Q., Gu, H., Cao, Y.-T., Wu, Z.-P., Wu, X.-S., Zhong, J.-H., Wu, M.-Y., Wei, Y., and Zhang, T.-L., 2021, Journal of Geophysical Research - Planets, 126(2), e2020JE006679
  35. Hydrogen and helium escape on Venus via energy transfer from hot oxygen atoms, Gu, H., Cui, J.*, Niu, D.-D., and Yu, J., 2021, Monthly Notices of the Royal Astronomical Society, 501(2), 2394-2402
  36. In-situ heating of the nightside Martian upper atmosphere and ionosphere: The role of Solar Wind electron precipitation, Niu, D.-D., Cui, J.*, Gu, H., Wu, X.-S., Cao, Y.-T., Dai, L.-K., Wu, M.-Y., Zhang, T.-L., Rong, Z.-J., and Wei, Y., 2021, The Astrophysical Journal, 909(2), 108
  37. Non-thermal escape from Triton’s dayside atmosphere driven by chemistry, Gu, H., Cui, J.*, Niu, D.-D., Wu, X.-S., He, F., and Wei, Y., 2021, Astronomy and Astrophysics, 650, AA130
  38. Compositional variation of the dayside Martian ionosphere: Inference from photochemical equilibrium computations, Wu, X.-S., Cui, J.*, Niu, D.-D., Ren, Z.-P., and Wei, Y., 2021, The Astrophysical Journal, 923(1), 29
  39. Wind-enhanced hydrogen escape on Mars, Gu, H., Cui, J.*, Huang, X., and Sun, M.-Y., 2022, Geophysical Research Letters, 49(10), e2022GL098312
  40. Characteristic timescales for the dayside Martian ionosphere: Chemistry, diffusion, and magnetization, Cao, Y.-T., Cui, J.*, Liang, W.-J., Wu, X.-S., Wu, S.-Q., and Lu, H.-Y., 2023, The Astronomical Journal, in press