发布日期:2024-04-06 浏览次数:次
教师主页 团队成员 科研项目 研究领域 学术成果 教学 科研分享 新闻动态 疼痛医学中心 成果介绍 软件 毕业去向 加入我们 联系我们 叶生毅 Google Scholar ResearcherID 教授 地球与空间科学系 南方科技大学教授。2000年毕业于清华大学物理系,获理学学士学位。2007年于美国达特茅斯学院获空间物理学博士学位。曾任职于美国爱荷华大学物理与天文系(博士后,自2009年起担任研究科学家)。主要从事NASA卡西尼任务(土星探测)及朱诺任务(木星探测)的数据分析研究工作。2019年9月加盟南方科技大学地球与空间科学系。已在Science, Geophysical Research Letters, Journal of Geophysical Research 等国际重要期刊上发表学术论文60余篇。现担任中国地球物理学会行星物理专业委员会副主任。曾担任NASA卡西尼数据分析项目CDAP部门首席科学家。目前主持中科院B类战略先导专项子课题、国自然面上项目、深圳市稳定支持项目各一项。研究领域: 空间物理、行星科学、空间探测。 个人简介 南方科技大学教授。2000年毕业于清华大学物理系,获理学学士学位。2007年于美国达特茅斯学院获空间物理学博士学位。曾任职于美国爱荷华大学物理与天文系(博士后,自2009年起担任研究科学家)。主要从事NASA卡西尼任务(土星探测)及朱诺任务(木星探测)的数据分析研究工作。2019年9月加盟南方科技大学地球与空间科学系。已在Science, Geophysical Research Letters, Journal of Geophysical Research 等国际重要期刊上发表学术论文70余篇。曾担任NASA卡西尼数据分析项目CDAP部门首席科学家。2020年起担任第二届中国地球物理学会行星物理专业委员会副主任。目前主持中科院B类战略先导专项子课题一项、国自然面上项目两项,曾主持深圳市科技创新委员会稳定支持项目一项。研究领域: 空间物理,行星科学。 教育背景 博士,(美)达特茅斯学院, 空间物理学,2007 学士,清华大学,物理学,2000 工作经历 2019- 教授 南方科技大学 2014-2019 副研究科学家 美国爱荷华大学 2009-2014 助理研究科学家 美国爱荷华大学 2007-2009 博士后研究学者 美国爱荷华大学 研究方向 空间物理 (太阳风与行星磁层相互作用,行星射频辐射及等离子波,磁层电离层耦合) 行星科学 (行星磁层周期调制现象,行星尘埃环) 空间探测 (空间等离子体遥感及就位探测,空间尘埃探测) 获奖及成就 深圳市鹏城计划B类人才 广东省珠江领军人才 NASA卡西尼任务大结局科学团队成就奖 NASA 卡西尼数据分析项目部门首席科学家 喷气推进实验室(JPL)卡西尼任务大结局尘埃预警评估专家 创建土星SLS5经度系统 国际空间科学中心(ISSI) “Physics of Dust Impacts: Detection of Cosmic Dust by Spacecraft and its Influence on the Plasma Environment” 会议特邀成员 国际空间科学中心(ISSI) “Rotational phenomena in Saturn's magnetosphere” 会议特邀成员 专业服务 学术期刊审稿人:GRL, JGR, Annales Geophysicae, Icarus, Radio Science, etc. NASA 太阳系研究项目特邀会评专家 NASA 卡西尼数据分析项目函评专家 COSPAR 会议召集人 个人简介 研究领域 空间物理 (太阳风与行星磁层相互作用,行星射电辐射及等离子波,磁层电离层耦合) 行星科学 (行星磁层周期调制现象、行星尘埃环) 空间探测 (空间等离子体遥感及就位探测、空间尘埃探测、空间尘埃等离子体效应) 教学 空间等离子体物理学 (ESS-5033) 空间物理前沿 (ESS-5004) 空间探测原理和实验(ESS-408) 学术成果 查看更多 已在Science, Geophysical Research Letters, Journal of Geophysical Research 等国际重要期刊上发表学术论文60余篇。现担任中国地球物理学会行星物理专业委员会副主任。曾担任NASA卡西尼数据分析项目CDAP部门首席科学家。目前主持中科院B类战略先导专项子课题、国自然面上项目、深圳市稳定支持项目各一项。主要研究方向为空间物理,行星科学和空间探测。 PUBLICATIONS [73] Wu, S., Zarka, P., Lamy, L., Louis, C., Ye, S., Prangé, R., et al., 2023. Rotational modulation of the high frequency limit of Saturn kilometric radiation. Journal of Geophysical Research: Space Physics, 128, e2023JA031287. https://doi.org/10.1029/2023JA031287 [72] Gu, W. D., Yao, Z. H., Pan, D. X., Xu, Y., Zhang, B., Delamere, P. A., Fu, S.Y., Xie, L., Ye, S.Y., Chen, Y. N., Dunn, W. R., Wei, Y., 2023. Hourly periodic variations of ultralow-frequency (ULF) waves in Jupiter’s magnetosheath. Journal of Geophysical Research: Planets, 128, e2022JE007625. https://doi.org/10.1029/2022JE007625 [71] 刘润逸, 诸峰, 王健, 叶生毅. 2023. 基于深度学习的空间尘埃碰撞实时自动检测. 地球物理学报, 66(2): 485-493, http://doi.org/10.6038/cjg2022Q0331 [70] 吴伟仁,王赤,刘洋,秦礼萍,林巍,叶生毅,李晖,沈芳,张哲,2023.深空探测之前沿科学问题探析.科学通报,68(06):606-627. [69] Feng, E., Zhang, B., Yao, Z., Delamere, P. A., Zheng, Z., Brambles, O. J., et al. 2022. Dynamic Jovian magnetosphere responses to enhanced solar wind ram pressure: Implications for auroral activities. Geophysical Research Letters, 49, e2022GL099858. https://doi.org/10.1029/2022GL099858 [68] Wu, S., Zarka, P., Lamy, L., Taubenschuss, U., Cecconi, B., Ye, S., et al. 2022. Observations of the first harmonic of Saturn Kilometric Radiation during Cassini’s Grand Finale. Journal of Geophysical Research: Space Physics, 127, e2022JA030776. https://doi.org/10.1029/2022JA030776 [67] Wu, S. Y., Ye, S. Y., Fischer, G., Taubenschuss, U., Jackman, C. M., O’Dwyer, E., et al. 2022. Saturn Anomalous Myriametric radiation, a new type of Saturn radio emission revealed by Cassini. Geophysical Research Letters, 49, e2022GL099237. https://doi.org/10.1029/2022GL099237 [66] Long, M., Cao, X., Gu, X., Ni, B., Qu, S., Ye, S., Yao, Z., Wu, S. and Xu, Y., 2022. Statistics of Water-group Band Ion Cyclotron Waves in Saturn’s Inner Magnetosphere Based on 13 yr of Cassini Measurements. The Astrophysical Journal, 932(1), p.56. https://doi.org/10.3847/1538-4357/ac6bf0 [65] Wu, S. Y., Ye, S. Y., Fischer, G., Jackman, C. M., Wang, J., Menietti, J. D., Cecconi, B., and Long, M. Y., 2022. Reflection and Refraction of the L‐O Mode 5 kHz Saturn Narrowband Emission by the Magnetosheath. Geophysical Research Letters, 49(5), e2021GL096990. https://doi.org/10.1029/2021GL096990 [64] Hadid, L. Z., Shebanits, O., Wahlund, J. E., Morooka, M. W., Nagy, A. F., Farrell, W. M., Holmberg, M.K.G., Modolo, R., Persoon, A. M., Tseng, W. L., and Ye, S. Y., 2022. Ambipolar electrostatic field in negatively charged dusty plasma. Journal of Plasma Physics, 88(2). https://doi.org/10.1017/S0022377822000186 [63] Xu, Y., Guo, R. L., Yao, Z. H., Pan, D. X., Dunn, W. R., Ye, S. Y., Zhang, B., Sun, Y. X., Wei, Y., and Coates, A. J.,2021. Properties of plasmoids observed in Saturn’s dayside and nightside magnetodisc. Geophysical Research Letters, 48(24), e2021GL096765. [62] Guo, R.L., Yao, Z.H., Dunn, W.R., Palmaerts, B., Sergis, N., Grodent, D., Badman, S.V., Ye, S.Y., Pu, Z.Y., Mitchell, D.G. and Zhang, B.Z., 2021. A Rotating Azimuthally Distributed Auroral Current System on Saturn Revealed by the Cassini Spacecraft. The Astrophysical Journal Letters, 919(2), p.L25. https://doi.org/10.3847/2041-8213/ac26b5 [61] He, Q., Liu, K., Ye, S., Liu, Q. and Deng, T., 2021. Investigation on unexpected variations of differential phase delay of Chang’E-3. Advances in Space Research. https://doi.org/10.1016/j.asr.2021.07.025 [60] Wu,S.Y., Ye, S. Y., Fischer, G., Wang, J., Long, M.Y., Menietti, J. D., Cecconi, B., and Kurth, W.S., 2021. Statistical study on spatial distribution and polarization of Saturn narrowband emissions, Astrophys. J., https://doi.org/10.3847/1538-4357/ac0af1 [59] Persoon, A. M., Kurth, W. S., Gurnett, D. A., Groene, J. B., Smith, H. T., Perry, M. E., et al., 2020. Evidence of electron density enhancements in the post‐apoapsis sector of Enceladus’ orbit. Journal of Geophysical Research: Space Physics, 125, e2019JA027768. https://doi.org/10.1029/2019JA027768 [58] Ye, S.Y., Averkamp, T. F., Kurth, W. S., Brennan, M., Bolton, S., Connerney, J. E. P., and Joergensen, J. L., 2020. Juno Waves detection of dust impacts near Jupiter. Journal of Geophysical Research: Planets, 124, e2019JE006367. https://doi.org/10.1029/2019JE006367 [57] Nouzák, L., Sternovsky, Z., Horányi, M., Hsu, S., Pavlů, J., Shen, M.-H., and Ye, S.Y., 2020. Magnetic field effect on antenna signals induced by dust particle impacts, Journal of Geophysical Research. https://doi.org/10.1029/2019JA027245 [56] Carbary, J.F., Mitchell, D.G. and Ye, S.Y., 2019. Energetic Electron Patterns in the New SLS5 Longitude System, Journal of Geophysical Research. https://doi.org/10.1029/2019JA027036 [55] Vaverka, J., Pavlu, J., Nouzak, L, Safrankova, J., Nemecek, Z., Mann, I., Ye, S.Y. and Lindqvist, P. -A., 2019. One-year analysis of dust impact-like events onto the MMS spacecraft, Journal of Geophysical Research. https://doi.org/10.1029/2019JA027035 [54] Ye, S. Y., Vaverka, J., Nouzak, L., Sternovsky, Z., Zaslavsky, A., Pavlu, J., Mann, I., Hsu, H.-W., Averkamp, T. F., Sulaiman, A. H., Pisa, D., Hospodarsky, G. B., Kurth, W. S. and Horanyi, M., 2019. Understanding Cassini RPWS Antenna Signals Triggered by Dust Impacts, Geophysical Research Letters, 46(13), pp. 10941-10950, https://doi.org/10.1029/2019GL084150 [53] Mann, I., Nouzák, L., Vaverka, J., Antonsen, T., Fredriksen, Å, Issautier, K., Malaspina, D., Meyer-Vernet, N., Pavlů, J., Sternovsky, Z., Stude, J., Ye, S. Y., Zaslavsky, A., 2019. Dust observations with antenna measurements and its prospects for observations with Parker Solar Probe and Solar Orbiter, Annales Geophysicae. https://doi.org/10.5194/angeo-37-1121-2019 [52] Yao, Z.H., Grodent, D., Kurth, W.S., Clark, G., Mauk, B.H., Kimura, T., Bonfond, B., Ye, S.Y., Lui, A.T., Radioti, A., Palmaerts, B., Dunn, W. R., Ray, L.C., Bagenal, F., Badman, S.V., Rae, I.J., Guo, R.L., Pu, Z.Y., Gérard, J.-C., Yoshioka, K., Nichols, J.D., Connerney, J.E.P., Bolton, S. and Levin, S. M., 2019. On the relation between Jovian aurorae and the loading/unloading of the magnetic flux: simultaneous measurements from Juno, HST and Hisaki. Geophysical Research Letters. https://doi.org/10.1029/2019GL084201 [51] Sulaiman, A. H., Farrell, W. M., Ye, S.Y., Kurth, W. S., Gurnett, D. A., Hospodarsky, G. B., Menietti, J. D., Píša, D., Hunt, G. J., Agiwal, O. and Dougherty, M. K., 2019. A Persistent, Large‐Scale, and Ordered Electrodynamic Connection Between Saturn and Its Main Rings, Geophysical Research Letters, 46(13), pp. 7166-7172. https://doi.org/10.1029/2019GL083541 [50] Chancia, R.O., Hedman, M.M., Cowley, S.W.H., Provan, G. and Ye, S.Y., 2019. Seasonal structures in Saturn’s dusty Roche Division are tied to periodicities of the planet’s magnetosphere. Icarus. 330, pp. 230 -255.https://doi.org/10.1016/j.icarus.2019.04.012 [49] Azari, A.R., Jia, X., Liemohn, M.W., Hospodarsky, G.B., Provan, G., Ye, S.Y., Cowley, S.W.H., Paranicas, C., Sergis, N., Rymer, A.M., Thomsen, M.F. and Mitchell, D.G., 2019. Are Saturn’s Interchange Injections Organized by Rotational Longitude? Journal of Geophysical Research: Space Physics, 124(3), pp.1806-1822. https://doi.org/10.1029/2018JA026196 [48] Yao, Z.H., Radioti, A., Grodent, D., Ray, L.C., Palmaerts, B., Sergis, N., Dialynas, K., Coates, A.J., Arridge, C.S., Roussos, E. and Badman, S.V., Ye, S.Y., Gérard, G.-C., Delamere, P. A., Guo, R. L., Pu, Z.Y., Waite, J. H., Krupp, N., Mitchell, D.G. and Dougherty, M.K., 2018. Recurrent magnetic dipolarization at Saturn: revealed by Cassini. Journal of Geophysical Research: Space Physics, 123(10), pp.8502-8517. https://doi.org/10.1029/2018JA025837 [47] Ye, S.Y., Kurth, W.S., Hospodarsky, G.B., Persoon, A.M., Sulaiman, A.H., Gurnett, D.A., Morooka, M., Wahlund, J.E., Hsu, H.W., Sternovsky, Z. and Wang, X., 2018. Dust Observations by the Radio and Plasma Wave Science Instrument During Cassini’s Grand Finale. Geophysical Research Letters, 45(19), pp.10-101. https://doi.org/10.1029/2018GL078059 [46] Hsu, H.W., Schmidt, J., Kempf, S., Postberg, F., Moragas-Klostermeyer, G., Seiß, M., Hoffmann, H., Burton, M., Ye, S., Kurth, W.S. and Horányi, M., 2018. In situ collection of dust grains falling from Saturn’s rings into its atmosphere. Science, 362(6410), p.eaat3185. https://doi.org/10.1126/science.aat3185 [45] Ye, S.Y., Fischer, G., Kurth, W.S., Menietti, J.D. and Gurnett, D.A., 2018. An SLS5 longitude system based on the rotational modulation of Saturn radio emissions. Geophysical Research Letters, 45(15), pp.7297-7305. https://doi.org/10.1029/2018GL077976 [44] Ye, S.Y., Kurth, W.S., Hospodarsky, G.B., Persoon, A.M., Gurnett, D.A., Morooka, M., Wahlund, J.E., Hsu, H.W., Seiß, M. and Srama, R., 2018. Cassini RPWS Dust Observation Near the Janus/Epimetheus Orbit. Journal of Geophysical Research: Space Physics, 123(6), pp.4952-4960. https://doi.org/10.1029/2017JA025112 [43] Sulaiman, A.H., Kurth, W.S., Hospodarsky, G.B., Averkamp, T.F., Ye, S.Y., Menietti, J.D., Farrell, W.M., Gurnett, D.A., Persoon, A.M., Dougherty, M.K. and Hunt, G.J., 2018. Enceladus auroral hiss emissions during Cassini’s Grand Finale. Geophysical Research Letters, 45(15), pp.7347-7353. https://doi.org/10.1029/2018GL078130 [42] Menietti, J.D., Averkamp, T.F., Ye, S.Y., Persoon, A.M., Morooka, M.W., Groene, J.B. and Kurth, W.S., 2018. Extended Survey of Saturn Z‐Mode Wave Intensity Through Cassini’s Final Orbits. Geophysical Research Letters, 45(15), pp.7330-7336. https://doi.org/10.1029/2018GL079287 [41] Sulaiman, A.H., Kurth, W.S., Hospodarsky, G.B., Averkamp, T.F., Persoon, A.M., Menietti, J.D., Ye, S.Y., Gurnett, D.A., Píša, D., Farrell, W.M. and Dougherty, M.K., 2018. Auroral hiss emissions during Cassini’s Grand Finale: Diverse electrodynamic interactions between Saturn and its rings. Geophysical Research Letters, 45(14), 6782–6789. https://doi.org/10.1029/2018GL077875 [40] Menietti, J.D., Averkamp, T.F., Ye, S.Y., Sulaiman, A.H., Morooka, M.W., Persoon, A.M., Hospodarsky, G.B., Kurth, W.S., Gurnett, D.A. and Wahlund, J.E., 2018. Analysis of intense Z‐mode emission observed during the Cassini proximal orbits. Geophysical Research Letters, 45, 6766–6772. https://doi.org/10.1002/2018GL077354 [39] Morooka, M.W., Wahlund, J.E., Andrews, D.J., Persoon, A.M., Ye, S.Y., Kurth, W.S., Gurnett, D.A. and Farrell, W.M., 2018. The Dusty plasma disk around the Janus/Epimetheus ring. Journal of Geophysical Research: Space Physics, 123(6), pp.4668-4678. https://doi.org/10.1002/2017JA024917 [38] Hedman, M.M., Dhingra, D., Nicholson, P.D., Hansen, C.J., Portyankina, G., Ye, S. and Dong, Y., 2018. Spatial Variations in the Dust-to-Gas Ratio of Enceladus’ Plume. Icarus. Vol 305, p123-138, https://doi.org/10.1016/j.icarus.2018.01.006 [37] Ye, S.Y., Fischer, G., Kurth, W.S., Menietti, J.D. and Gurnett, D.A., 2017. Rotational modulation of Saturn Kilometric Radiation, narrrowband emission and auroral hiss. Planetary Radio Emissions VIII, pp. 191-204. https://doi.org/10.1553/PRE8s191 [36] Kurth, W.S., Imai, M., Hospodarsky, G.B., Gurnett, D.A., Tetrick, S.S., Ye, S.Y., Bolton, S.J., Connerney, J.E.P. and Levin, S.M., 2017. First observations near Jupiter by the Juno Waves investigation. Planetary Radio Emissions VIII, pp. 1-12. https://doi.org/10.1553/PRE8s1 [35] Sulaiman, A. H., Kurth, W. S., Persoon, A. M., Menietti, J. D., Farrell, W. M., Ye, S.Y., Hospodarsky, G. B., Gurnett, D. A., Hadid, L. Z. (2017). Intense harmonic emissions observed in Saturn’s ionosphere. Geophysical Research Letters, 44(24), pp.12049-12056. https://doi.org/10.1002/2017GL076184 [34] Wahlund, J.E., Morooka, M.W., Hadid, L.Z., Persoon, A.M., Farrell, W.M., Gurnett, D.A., Hospodarsky, G., Kurth, W.S., Ye, S.Y., Andrews, D.J. and Edberg, N.J., 2018. In situ measurements of Saturn’s ionosphere show that it is dynamic and interacts with the rings. Science, 359(6371), pp.66-68. https://doi.org/10.1126/science.aao4134 [33] Nouzák, L., Hsu, S., Malaspina, D., Thayer, F.M., Ye, S.Y., Pavlů, J., Němeček, Z., Šafránková, J. and Sternovsky, Z., 2018. Laboratory modeling of dust impact detection by the Cassini spacecraft. Planetary and Space Science, 156, pp.85-91. https://doi.org/10.1016/j.pss.2017.11.014 [32] Krupp, N., Roussos, E., Paranicas, C., Mitchell, D.G., Kollmann, P., Ye, S., Kurth, W.S., Khurana, K.K., Perryman, R., Waite, H. and Srama, R., 2018. Energetic electron measurements near Enceladus by Cassini during 2005–2015. Icarus, 306, pp.256-274. https://doi.org/10.1016/j.icarus.2017.10.022 [31] Menietti, J.D., Averkamp, T.F., Kurth, W.S., Ye, S.Y., Gurnett, D.A. and Cecconi, B., 2017. Survey of Saturn electrostatic cyclotron harmonic wave intensity. Journal of Geophysical Research: Space Physics, 122(8), pp.8214-8227. https://doi.org/10.1002/2017JA023929 [30] Menietti, J.D., Yoon, P.H., Písa, D., Ye, S.Y., Santolík, O., Arridge, C.S., Gurnett, D.A. and Coates, A.J., 2016. Source region and growth analysis of narrowband Z‐mode emission at Saturn. Journal of Geophysical Research: Space Physics, 121(12), pp. 11929-11942. https://doi.org/10.1002/2016JA022913 [29] Ye, S.Y., Kurth, W.S., Hospodarsky, G.B., Averkamp, T.F. and Gurnett, D.A., 2016. Dust detection in space using the monopole and dipole electric field antennas. Journal of Geophysical Research: Space Physics, 121(12), pp. 11964-11972. https://doi.org/10.1002/2016JA023266 [28] Ye, S.Y., Fischer, G., Kurth, W.S., Menietti, J.D. and Gurnett, D.A., 2016. Rotational modulation of Saturn’s radio emissions after equinox. Journal of Geophysical Research: Space Physics, 121(12). pp. 11714-11728. https://doi.org/10.1002/2016JA023281 [27] Ye, S.Y., Gurnett, D.A. and Kurth, W.S., 2016. In-situ measurements of Saturn’s dusty rings based on dust impact signals detected by Cassini RPWS. Icarus, 279, pp.51-61. https://doi.org/10.1016/j.icarus.2016.05.006 [26] Engelhardt, I.A.D., Wahlund, J.E., Andrews, D.J., Eriksson, A.I., Ye, S., Kurth, W.S., Gurnett, D.A., Morooka, M.W., Farrell, W.M. and Dougherty, M.K., 2015. Plasma regions, charged dust and field-aligned currents near Enceladus. Planetary and Space Science, 117, pp.453-469. https://doi.org/10.1016/j.pss.2015.09.010 [25] Menietti, J.D., Averkamp, T.F., Ye, S.Y., Horne, R.B., Woodfield, E.E., Shprits, Y.Y., Gurnett, D.A., Persoon, A.M. and Wahlund, J.E., 2015. Survey of Saturn Z‐mode emission. Journal of Geophysical Research: Space Physics, 120(8), pp.6176-6187. https://doi.org/10.1002/2015JA021426 [24] Fischer, G., Gurnett, D.A., Kurth, W.S., Ye, S.Y. and Groene, J.B., 2015. Saturn kilometric radiation periodicity after equinox. Icarus, 254, pp.72-91. https://doi.org/10.1016/j.icarus.2015.03.014 [23] Dong, Y., Hill, T.W. and Ye, S.Y., 2015. Characteristics of ice grains in the Enceladus plume from Cassini observations. Journal of Geophysical Research: Space Physics, 120(2), pp.915-937. https://doi.org/10.1002/2014JA020288 [22] Fischer, G., Ye, S.Y., Groener, J.B., Ingersoll, A.P., Sayanagi, K.M., Menietti, J.D., Kurth, W.S. and Gurnett, D.A., 2014, December. A possible influence of the Great White Spot on Saturn kilometric radiation periodicity. In Annales Geophysicae(Vol. 32, No. 12, pp. 1463-1476). European Geosciences Union. https://doi.org/10.5194/angeo-32-1463-2014 [21] Ye, S.Y., Gurnett, D.A., Kurth, W.S., Averkamp, T.F., Kempf, S., Hsu, H.W., Srama, R. and Grün, E., 2014. Properties of dust particles near Saturn inferred from voltage pulses induced by dust impacts on Cassini spacecraft. Journal of Geophysical Research: Space Physics, 119(8), pp.6294-6312. https://doi.org/10.1002/2014JA020024 [20] Ye, S.Y., Gurnett, D.A., Kurth, W.S., Averkamp, T.F., Morooka, M., Sakai, S. and Wahlund, J.E., 2014. Electron density inside Enceladus plume inferred from plasma oscillations excited by dust impacts. Journal of Geophysical Research: Space Physics, 119(5), pp.3373-3380. https://doi.org/10.1002/2014JA019861 [19] Gu, X., Thorne, R.M., Ni, B. and Ye, S.Y., 2013. Resonant diffusion of energetic electrons by narrowband Z mode waves in Saturn’s inner magnetosphere. Geophysical Research Letters, 40(2), pp.255-261. https://doi.org/10.1029/2012GL054330 [18] Ye, S.Y., Gurnett, D.A., Menietti, J.D., Kurth, W.S., Fischer, G., Schippers, P. and Hospodarsky, G.B., 2012. Cassini observation of Jovian anomalous continuum radiation. Journal of Geophysical Research: Space Physics, 117(A4). https://doi.org/10.1029/2011JA017135 [17] Menietti, J.D., Mutel, R.L., Schippers, P., Ye, S.Y., Gurnett, D.A. and Lamy, L., 2011. Analysis of Saturn kilometric radiation near a source center. Journal of Geophysical Research: Space Physics, 116(A12). https://doi.org/10.1029/2011JA017056 [16] Ye, S.Y., Fischer, G., Menietti, J.D., Wang, Z., Gurnett, D.A. and Kurth, W.S., 2011. An Overview of Saturn Narrowband Radio Emissions Observed by Cassini RPWS. Planetary, Solar and Heliospheric Radio Emissions (PRE VII), pp.99-113. https://doi.org/10.1553/PRE7s99 [15] Gurnett, D.A., Groene, J.B., Averkamp, T.F., Kurth, W.S., Ye, S.Y. and Fischer, G., 2011. An SLS4 longitude system based on a tracking filter analysis of the rotational modulation of Saturn kilometric radiation. Planetary Radio Emissions VII, pp.51-64. https://doi.org/10.1553/PRE7s51 [14] Menietti, J.D., Mutel, R.L., Schippers, P., Ye, S.Y., Santolik, O., Kurth, W.S., Gurnett, D.A., Lamy, L. and Cecconi, B., 2011. Saturn kilometric radiation near a source center on day 73, 2008. Planetary Radio Emissions VII, pp.87-95. https://doi.org/10.1553/PRE7s87 [13] Gurnett, D.A., Groene, J.B., Persoon, A.M., Menietti, J.D., Ye, S.Y., Kurth, W.S., MacDowall, R.J. and Lecacheux, A., 2010. The reversal of the rotational modulation rates of the north and south components of Saturn kilometric radiation near equinox. Geophysical Research Letters, 37(24). https://doi.org/10.1029/2010GL045796 [12] Ye, S.Y., Gurnett, D.A., Groene, J.B., Wang, Z. and Kurth, W.S., 2010. Dual periodicities in the rotational modulation of Saturn narrowband emissions. Journal of Geophysical Research: Space Physics, 115(A12). https://doi.org/10.1029/2010JA015780 [11] Ye, S.Y., Menietti, J.D., Fischer, G., Wang, Z., Cecconi, B., Gurnett, D.A. and Kurth, W.S., 2010. Z mode waves as the source of Saturn narrowband radio emissions. Journal of Geophysical Research: Space Physics, 115(A8). https://doi.org/10.1029/2009JA015167 [10] Wang, Z., Gurnett, D.A., Fischer, G., Ye, S.Y., Kurth, W.S., Mitchell, D.G., Leisner, J.S. and Russell, C.T., 2010. Cassini observations of narrowband radio emissions in Saturn’s magnetosphere. Journal of Geophysical Research: Space Physics, 115(A6). https://doi.org/10.1029/2009JA014847 [9] Menietti, J.D., Yoon, P.H., Ye, S.Y., Cecconi, B. and Rymer, A.M., 2010. Source mechanism of Saturn narrowband emission. Annales Geophysicae (09927689), 28(4), pp.1013-1021. https://doi.org/10.5194/angeo-28-1013-2010 [8] Menietti, J.D., Ye, S.Y., Piker, C.W. and Cecconi, B., 2010. The influence of Titan on Saturn kilometric radiation. Annales Geophysicae (09927689), 28(2), pp.395-406. https://doi.org/10.5194/angeo-28-395-2010 [7] Ye, S.Y., Gurnett, D.A., Fischer, G., Cecconi, B., Menietti, J.D., Kurth, W.S., Wang, Z., Hospodarsky, G.B., Zarka, P. and Lecacheux, A., 2009. Source locations of narrowband radio emissions detected at Saturn. Journal of Geophysical Research: Space Physics, 114(A6). https://doi.org/10.1029/2008JA013855 [6] Fischer, G., Cecconi, B., Lamy, L., Ye, S.Y., Taubenschuss, U., Macher, W., Zarka, P., Kurth, W.S. and Gurnett, D.A., 2009. Elliptical polarization of Saturn kilometric radiation observed from high latitudes. Journal of Geophysical Research: Space Physics, 114(A8). https://doi.org/10.1029/2009JA014176 [5] Menietti, J.D., Ye, S.Y., Yoon, P.H., Santolik, O., Rymer, A.M., Gurnett, D.A. and Coates, A.J., 2009. Analysis of narrowband emission observed in the Saturn magnetosphere. Journal of Geophysical Research: Space Physics, 114(A6). https://doi.org/10.1029/2008JA013982 [4] Ye, S. and LaBelle, J., 2008. Ground based observations of low frequency auroral hiss fine structure. Journal of Geophysical Research: Space Physics, 113(A1). https://doi.org/10.1029/2007JA012473 [3] Yoon, P.H., Ye, S., LaBelle, J., Weatherwax, A.T. and Menietti, J.D., 2007. Methods in the study of discrete upper hybrid waves. Journal of Geophysical Research: Space Physics, 112(A11). https://doi.org/10.1029/2007JA012683 [2] Ye, S., LaBelle, J., Yoon, P.H. and Weatherwax, A.T., 2007. Experimental tests of the eigenmode theory of auroral roar fine structure and its application to remote sensing. Journal of Geophysical Research: Space Physics, 112(A12). https://doi.org/10.1029/2007JA012525 [1] Ye, S., LaBelle, J. and Weatherwax, A.T., 2006. Further study of flickering auroral roar emission: 1. South Pole observations. Journal of Geophysical Research: Space Physics, 111(A7). https://doi.org/10.1029/2005JA011271 新闻动态 更多新闻 王赤院士和宋普教授南科大讲堂讲述前沿空间技术 2020-08-06 南科大-中山大学行星科学研讨会举行 2020-08-06 我系师生赴文昌观看“天问一号”火星探测计划发射 2020-08-06 团队成员 查看更多 PrevNext UpDown 加入团队 南方科技大学地球与空间科学系成立于2016年12月,由中国科学院院士陈晓非教授担任首届系主任。 本系建系宗旨是:建设国际化的、一流的地球与空间科学人才培养与科研基地,以促进人类对地球及其所处空间这一复杂自然系统运动规律的探索和认知,为应对当前人类社会发展中所面临的来自于自然环境、资源与灾害方面的严峻挑战以及开展行星际空间探索提供科学基础,并培养具有足够能力解决未来地球与空间科学领域科学问题的学术领军人才与管理人才。 南方科技大学地球与空间科学系拟在以下几个学科方向上开展学术研究与人才培养:地球物理学、空间物理学、空间大地测量学和行星科学。目前,本系已有教学科研人员31人,包括教授6人,副教授4人,助理教授11人和研究系列教授10人;其中包括中国科学院院士1人,国家杰青3人,国家优青1人。我们期待更多的优秀人才加盟,共建世界一流地球与空间科学人才培养和科学研究基地。 【课题组每年招聘博士后若干名,博士生1-2名,硕士生2-4名,有意者请邮件联系yesy@sustech.edu.cn】 【博士后招聘】长期有效 岗位要求1)一般在35周岁以下,具有空间物理或相关专业领域博士学位(一般在取得博士学位3年内);2)有责任心和团队合作精神,并能够相对独立的思考、解决科研问题;3)具有良好的英语写作和交流能力;4)以第一作者在相关领域主流期刊上发表过1篇及以上学术论文。 岗位职责1) 参与课题组项目的工作研究;2) 与相关合作单位沟通协调并解决问题;3) 申请研究经费来支持课题研究;4) 完成课题研究,发表具有国际竞争力的高水平学术论文;5) 指导博士、硕士研究生、科研助理等。 薪酬待遇1)博士后在站期间是我校的正式工作人员,可以申请深圳户口,享受医疗、保险、安排子女入学(入托)等待遇;2)博士后年薪33.5万元(含广东省补助15万元(税前)及深圳市生活补助6万元(税后),完成开题考核和中期考核后即可申领);特别优秀者可申请校长卓越博士后,年薪可达41.5万元;3)在站期间学校为每位博士后提供2.5万元的学术交流资助(含国际会议资助);4)课题组提供良好的科研条件,鼓励并协助博士后研究人员申报国家自然科学基金、中国博士后科学基金、广东省博士后科研资助项目等,并大力推荐出站考核优异者申请学校相应的科研教师岗位;5)享受过节费、餐补、计划生育奖励、免费体检等福利待遇;6)提供科研经费支持、良好的办公条件和校内住宿(或公租房补贴);7)依据自身符合的条件,可申请“深圳市孔雀计划C类人才”或者“深圳市后备级人才”,享受5年160万的奖励津贴(免税)(认定标准以深圳市最新人才政策为准)。 应聘方式有意者请将相关申请材料发送至:yesy@sustech.edu.cn(叶老师),邮件标题以“岗位名称+姓名”命名。相关应聘材料如下:1)学习、工作和科研的经历(时间不间断,附近照),主要科研成果(如论文论著、成果证书或奖励),及其他可以证明工作能力的材料;2)请提供身份证、学位证、毕业证扫描件或清晰照片;3)2-3推荐人的姓名及有效联系方式(博士后岗位需提供博士导师的联系方式);4)个人研究计划(限1000字以内) 查看更多 联系我们 联系地址 广东省深圳市南山区学苑大道1088号 创园9栋 310A室 办公电话 0755-88018647 电子邮箱 yesy@sustech.edu.cn