邹宓君 Mijun ZOU
讲师(Assistant Professor)
陆-气相互作用、卫星遥感估算地表蒸散发、极端气候下的生态系统稳定性评价、光伏功率预测
教育背景
博士,中国科学技术大学地球和空间科学学院,大气物理与大气环境
博士联培,荷兰屯特大学地球信息与地球观测学院,水资源
学士,兰州大学大气科学学院,大气科学类
Email:zoumj@shnu.edu.cn
邹宓君博士主要从事地表蒸散发与辐射的遥感估算、青藏高原陆-气相互作用相关研究。目前结合生态学理论和陆面模式的思想构建了参数少且机理性强的碳-水耦合蒸散发遥感模型,同时融合微波和光学遥感建立了考虑穿透效应的全天空地表温度反演算法。
科研与学术工作经历
2020/9月-2022/9月,清华大学地球系统与科学系,博士后
研究项目
主持,基于生态最优性原理的复杂地表蒸散发模型,国家自然科学基金青年科学基金项目(C类),结题
主持,蒸散发阻抗的土壤水分调控模块优化,地球系统数值模拟教育部重点实验室(清华大学)开放基金,在研
参与,青藏高原全天空地表辐射收支与热状况的卫星遥感估算研究,国家自然科学基金面上项目,结题
承担课程
《自然地理学》、《气象气候学》、《气候变化与气候资源》
论文著作
(1)Zou, M., Zhong, L., Jia, W., Ge, Y., & Mamtimin, A. (2025). Improving soil surface evaporation estimates with transformer-based model. Atmospheric Research, 107972.
(2)He, Q., Lu, H., Yang, K., Zhao, L., & Zou, M. (2024). Benefit of incorporating GLASS remote sensing vegetation products in improving Noah-MP land surface temperature simulations on the Tibetan Plateau. Science of Remote Sensing, 9, 100115.
(3)He, Y., Yang, K., Ren, Y., Zou, M., Yuan, X., & Tang, W. (2023). Causes of the extremely low solar radiation in the 2021 growing season over southeastern Tibetan Plateau and its impact on vegetation growth. Bulletin of the American Meteorological Society, 104(2), E359-E366.
(4)Yuan, X., Yang, K., Sun, J., Wang, Y., He, Y. Y., Zou, M. J., & Jiang, Y. Z. (2023). Why was Pakistan extreme precipitation stronger in 2022 than in 2010? Advances in Climate Change Research, 14(6), 913-920.
(5)Zou, M., Zhong, L., Ma, Y., Wang, X., Fu, Y., & Su, Z. (2023). Retrieval of all-sky land surface temperature considering penetration effect using spaceborne thermal and microwave radiometry. IEEE Transactions on Geoscience and Remote Sensing, 61, 1-12.
(6)Zou, M., Yang, K., Lu, H., Ren, Y., Sun, J., Wang, H., ... & Zhao, L. (2023). Integrating eco-evolutionary optimality principle and land processes for evapotranspiration estimation. Journal of Hydrology, 616, 128855.
(7)Zou, M., Zhong, L., Ma, Y., Hu, Y., Huang, Z., Xu, K., & Feng, L. Comparison of two satellite-based evapotranspiration models of the Nagqu River Basin of the Tibetan Plateau. Journal of Geophysical Research: Atmospheres, 2018, 123(8): 3961-3975.
(8)Zou, M., Zhong, L., Ma, Y., Hu, Y., & Feng., L. Estimation of actual evapotranspiration in the Nagqu river basin of the Tibetan Plateau. Theoretical and Applied Climatology, 2018, 132(3-4): 1039-1047.
(9)Zhong, L., Zou, M., Ma, Y., Huang, Z., Xu, K., Wang, X., Ge, N., & Cheng, M. (2019). Estimation of downwelling shortwave and longwave radiation in the Tibetan Plateau under all sky conditions. Journal of Geophysical Research: Atmospheres, 124(21): 11086-11102.
(10)Xu, K., Zhong, L., Ma, Y., Zou, M., & Huang, Z. (2020). A study on the water vapor transport trend and water vapor source of the Tibetan Plateau. Theoretical and Applied Climatology, 2020: 1-12.
(11)Cheng, M., Zhong, L., Ma, Y., Zou, M., Ge, N., Wang, X., & Hu, Y. (2019). A study on the assessment of multi-source satellite soil moisture products and reanalysis data for the Tibetan Plateau. Remote Sensing, 11(10): 1196.
(12)Ge, N., Zhong, L., Ma, Y., Cheng, M., Wang, X., Zou, M., & Huang, Z. (2019). Estimation of land surface heat fluxes based on Landsat 7 ETM+ data and field measurements over the Northern Tibetan Plateau. Remote Sensing, 11(24): 2899.
(13)阳坤,陈莹莹,拉珠,詹昌辉,令小艳,周旭... & 邹宓君.(2023).青藏高原暖季中西部的断面降雨观测:系统设计与初步结果.中国科学:地球科学, 53(05),1006-1021.
(14)邹宓君; 邵长坤; 阳坤. (2020). 1979-2018年西藏自治区气候与冰川冻土变化及其对可再生能源的潜在影响, 大气科学学报, 43(6): 980-991.
(15)胡媛媛,仲雷,马耀明,邹宓君,黄子煜,徐可飘,冯璐. 青藏高原典型下垫面地表能量通量的模型估算与验证. (2018). 高原气象, 37(6): 1499-1510.
(16)冯璐,仲雷,马耀明,傅云飞,邹宓君. (2016). 基于土壤温湿度观测资料估算藏北高原地区土壤热通量.高原气象,35(2):297-308
学术兼职
Journal of Hydrology、ISPRS Journal of Photogrammetry and Remote Seng、International Journal of Climatology和Chinese Geographical Science等学术期刊审稿人
欢迎具有大气科学、生态学、水文学与水资源、计算机、地图学与地理信息系统等专业背景的同学加入
