基于卫星时变重力、卫星激光测高以及其他多源遥感数据的应用与解释

l  亚洲高山区冰川的质量平衡、融水量评估以及气候敏感性分析

l  全球尺度的质量迁移，重点在研究青藏高原上湖泊水、地下水、冰川的储量变化

硕士研究生（每年一名）、博士研究生（每年一名)

欢迎测绘科学与技术、地球物理学、遥感等相关专业有志青年加入团队！

欢迎博士后/特别研究助理加入（长期有效，招满为止）

基础年薪25万元+6千/月房补+五险一金单位缴纳部分不低于9.6万元/年

基础年薪40万元+6千/月房补+五险一金单位缴纳部分不低于13万元/年（优秀者）

协助博后基金、自然基金、校启动专项基金的申请，合作开展冰川遥感与模型、水文湖泊遥感、地球动力学等方向研究。

081601-大地测量学与测量工程
070801-固体地球物理学

卫星测高理论与应用，时变重力观测与解释，多源遥感观测应用

2013-09--2018-06   中国科学院大学   博士
2008-09--2012-06   中国石油大学（华东）   学士

   

2021-12~现在, 中国科学院大学, 长聘教轨助理教授
2019-12~2021-12,中国科学院大学, 博士后/特别研究助理

1. Wang, Q., S. Yi, and W. Sun* (2021). Continuous estimates of glacier mass balance in High Mountain Asia based on ICESat-1,2 and GRACE/GRACE Follow‐On data. Geophysical Research Letters, 48, e2020GL090954. https://doi.org/10.1029/2020GL090954. 
2. Wang, Q., S. Yi, and W. Sun* (2018), Consistent interannual changes in glacier mass balance and their relationship with climate variation on the periphery of the Tibetan Plateau, Geophysical Journal International, 214(1), 573-582, doi:10.1093/gji/ggy164.
3. Wang, Q., S. Yi, L. Chang, and W. Sun*(2017), Large-Scale Seasonal Changes in Glacier Thickness Across High Mountain Asia, Geophysical Research Letters, 44(20), 10,427-410,435, doi:10.1002/2017gl075300. 
4. Wang, Q., S. Yi, and W. Sun* (2017), Precipitation-driven glacier changes in the Pamir and Hindu Kush mountains, Geophysical Research Letters, 44(6), 2817-2824, doi:10.1002/2017gl072646. 
5. Wang, Q., S. Yi, and W. Sun* (2016), The changing pattern of lake and its contribution to increased mass in the Tibetan Plateau derived from GRACE and ICESat data, Geophysical Journal International, 207(1), 528-541. 
6. Yi, S. *, C. Song, K. Heki, S. Kang, Q. Wang, and L. Chang (2020), Satellite-observed monthly glacier and snow mass changes in southeast Tibet: implication for substantial meltwater contribution to the Brahmaputra, The Cryosphere, 14(7), 2267-2281, doi:10.5194/tc-14-2267-2020. 
7. Chang, L., H. Tang, Q. Wang, and W. Sun* (2019), Global thermosteric sea level change contributed by the deep ocean below 2000 m estimated by Argo and CTD data, Earth and Planetary Science Letters, 524, 115727, doi:https://doi.org/10.1016/j.epsl.2019.115727. 
8. Zhang, L., S. Yi, Q. Wang, L. Chang, H. Tang, and W. Sun* (2019), Evaluation of GRACE mascon solutions for small spatial scales and localized mass sources, Geophysical Journal International, 218(2), 1307-1321, doi:10.1093/gji/ggz198. 
9. Yi, S*., C. Song, Q. Wang, L. Wang, K. Heki, and W. Sun (2017), The potential of GRACE gravimetry to detect the heavy rainfall-induced impoundment of a small reservoir in the upper Yellow River, Water Resources Research, 53(8), 6562-6578. 
10. Yi, S., Q. Wang, and W. Sun* (2016), Basin mass dynamic changes in China from GRACE based on a multibasin inversion method, Journal of Geophysical Research: Solid Earth, 121(5), 3782-3803. 
11. Yi, S., Q. Wang, L. Chang, and W. Sun* (2016), Changes in Mountain Glaciers, Lake Levels, and Snow Coverage in the Tianshan Monitored by GRACE, ICESat, Altimetry, and MODIS, Remote Sensing, 8(10), 798. 
12. Yi, S., Q. Wang, and W. Sun* (2016), Is it possible that a gravity increase of 20 ugal yr−1 in southern Tibet comes from a wide-range density increase?, Geophysical Research Letters, 43(4), 1481-1486. 

（1） 应用卫星测高和卫星重力数据研究青藏高原冰川和湖泊的质量变化, Mass changes in glacier and lake in the Tibetan Plateau using satellite altimetry and satellite gravimetry data, 2022, 2022-12, 第 1 作者

   

（ 1 ） 青藏高原地区冰川质量变化的多源卫星数据联合研究, 主持, 国家级, 2022-01--2024-12
（ 2 ） 利用GRACE等多源数据研究天山地区多源质量迁移问题, 参与, 国家级, 2022-01--2025-12

（1）New Constrains on Glacier Mass Balance on High Mountain Asia   国际大地测量协会2021科学大会   汪秋昱   2021-06-28
（2）基于ICESat2和GRACE Follow-on评估亚洲高山冰川的近期质量变化   中国地球科学联合学术年会   汪秋昱   2020-10-18