人才详细信息
简介
教育背景:
2010.10 -2015.11 荷兰University of Twente 水文气象专业 博士
2007.09 -2010.07 北京师范大学 地理学与地理信息系统专业 硕士
2003.09 -2007.07 福建师范大学 地理科学国家理科基地专业 学士
研究经历:
2021.12 -至今 中国科学院青藏高原研究所 研究员
2018.04 -2021.11 中国科学院青藏高原研究所 聘期研究员
2015.04 -2018.03 荷兰ITC, University of Twente Researcher
研究方向
水循环、微波遥感
职务
社会任职
2024-至今 《Information Geography》副主编
2023-至今 中国地理学会信息地理专业委员会秘书长
2024-至今 中国地理学会冻土与寒区工程专业委员会秘书长
承担项目
1. 基金委优青项目“冻土微波遥感”,批准号42422108,执行期间:2025.01-2027.12,主持
2. 国家重点研发计划课题“陆表复杂场景像元尺度真值获取技术”,批准号2023YFB3905801,执行期间:2023.12-2026.11,主持
3. 基金委面上项目“青藏高原土壤未冻水的微波遥感监测和数据同化方法研究”,批准号41871273,执行期间:2019.01-2022.12,主持
4. 中国科学院率先行动“引才计划”青年俊才(C类)项目,执行期间:2018.04-2023.03,主持
获奖及荣誉
代表论著
第一作者及通讯作者:
1. Zhang, P., Zheng, D.*, van der Velde, R., Zeng, J., Wang, X., Wang, Z., Zeng, Y., Wen, J., Li, X., and Su, Z. (2024). Assessment of long-term multisource surface and subsurface soil moisture products and estimate methods on the Tibetan Plateau. Journal of Hydrology, 640, 131713.
2. Bai, X., Zheng, D.*, Li, X., Wigneron, J. P., van der Velde, R., Zhang, P., and Su, Z. (2023). Simulation of SMAP and AMSR2 observations and estimation of multi-frequency vegetation optical depth using a discrete scattering model in the Tibetan grassland. Remote Sensing of Environment, 292, 113592.
3. Zhang, P., Zheng, D.*, van der Velde, R., Wen, J., Ma, Y., Zeng, Y., Wang, X., Wang, Z., Chen, J., and Su, Z.* (2022). A dataset of 10-year regional-scale soil moisture and soil temperature measurements at multiple depths on the Tibetan Plateau. Earth Syst. Sci. Data, 14, 5513–5542.
4. Bai, X., Zheng, D.*, Liu, X., Fan, L., Zeng, J., and Li, X. (2022). Simulation of Sentinel-1A observations and constraint of water cloud model at the regional scale using a discrete scattering model. Remote Sensing of Environment, 283, 113308.
5. Zhang, K., Li, X.*, Zheng, D.*, Zhang, L., and Zhu, G. (2022). Estimation of global irrigation water use by the integration of multiple satellite observations. Water Resources Research, 58, e2021WR030031.
6. Zhou, Y., Li, X.*, Zheng, D.*, and Li, Z. (2022). Evolution of geodetic mass balance over the largest lake-terminating glacier in the Tibetan Plateau with a revised radar penetration depth based on multi-source high-resolution satellite data. Remote Sensing of Environment, 275, 113029.
7. Sun, S., Zheng, D.*, Liu, S.*, Xu, Z., Xu, T., Zheng, H., and Yang, X. (2022). Assessment and improvement of Noah-MP for simulating water and heat exchange over alpine grassland in growing season. Science China Earth Sciences, 65(3): 536–552.
8. Zheng, D., Li, X., Wen, J., Hofste, J.G., van der velde, R., Wang, X., Wang, Z., Bai, X., Schwank, M., and Su, Z. (2022). Active and Passive Microwave Signatures of Diurnal Soil Freeze-Thaw Transitions on the Tibetan Plateau. IEEE Transactions on Geoscience and Remote Sensing, 60, doi: 10.1109/TGRS.2021.3092411.
9. Zheng, D., Li, X., Zhao, T., Wen, J., van der Velde, R., Schwank, M., Wang, X., Wang, Z., and Su, Z. (2021). Impact of Soil Permittivity and Temperature Profile on L-Band Microwave Emission of Frozen Soil. IEEE Transactions on Geoscience and Remote Sensing, 59(5), 4080-4093.
10. Zhang, P., Zheng, D.*, van der Velde, R., Wen, J., Zeng, Y., Wang, X., Wang, Z., Chen, J., and Su, Z.* (2021). Status of the Tibetan Plateau observatory (Tibet-Obs) and a 10-year (2009–2019) surface soil moisture dataset. Earth Syst. Sci. Data, 13, 3075–3102.
11. Bai, X., Zheng, D.*, Wen, J., Wang, X., and van der velde, R. (2021). Using a Discrete Scattering Model to Constrain Water Cloud Model for Simulating Ground-Based Scatterometer Measurements and Retrieving Soil Moisture. IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing, 14, 9424–9434.
12. Wu, X., and Zheng, D.* (2021). Surface Roughness Effect on L-Band Multiangular Brightness Temperature Modeling and Soil Liquid Water Retrieval of Frozen Soil. IEEE Geoscience and Remote Sensing Letters, 18(9), 1615-1619.
13. Su, J., Li, X., Ren, W., Lü, H.*, and Zheng, D.*(2021). How reliable are the satellite-based precipitation estimations in guiding hydrological modelling in South China? Journal of Hydrology, 602, 126705.
15. Cao, B., Gruber, S., Zheng, D.*, and Li, X.* (2020). The ERA5-Land Soil-Temperature Bias in Permafrost Regions. The Cryosphere, 14, 2581-2595.
16. Zheng, D., Li, X., Wang, X., Wang, Z., Wen, J., van der Velde, R., Schwank, M., and Su, Z. (2019). Sampling depth of L-band radiometer measurements of soil moisture and freeze-thaw dynamics on the Tibetan Plateau. Remote Sensing of Environment, 226, 16-25.
17. Zheng, D., Wang, X., van der Velde, R., Schwank, M., Ferrazzoli, P., Wen, J., Wang, Z., Colliander, A., Bindlish, R., and Su, Z. (2019). Assessment of Soil Moisture SMAP Retrievals and ELBARA-III Measurements in a Tibetan Meadow Ecosystem. IEEE Geoscience and Remote Sensing Letters, 16(9), 1407-1411.
18. Zheng, D., Wang, X., van der Velde, R., Ferrazzoli, P., Wen, J., Wang, Z., Schwank, M., Colliander, A., Bindlish, R., and Su, Z. (2018). Impact of surface roughness, vegetation opacity and soil permittivity on L-band microwave emission and soil moisture retrieval in the third pole environment. Remote Sensing of Environment, 209, 633-647.
19. Zheng, D., van der Velde, R., Wen, J., Wang, X., Ferrazzoli, P., Schwank, M., Colliander, A., Bindlish, R., and Su, Z. (2018). Assessment of the SMAP Soil Emission Model and Soil Moisture Retrieval Algorithms for a Tibetan Desert Ecosystem. IEEE Transactions on Geoscience and Remote Sensing, 56, 3786-3799.
20. Zheng, D., van der Velde, R., Su, Z., Wen, J., Wang, X., and Yang, K. (2018). Impact of soil freeze-thaw mechanism on the runoff dynamics of two Tibetan rivers. Journal of Hydrology, 563, 382-394.
21.Zheng, D., Wang, X., van der Velde, R., Zeng, Y., Wen, J., Wang, Z., Schwank, M., Ferrazzoli, P., and Su, Z. (2017).L-Band Microwave Emission of Soil Freeze-Thaw Process in the Third Pole Environment. IEEE Transactions on Geoscience and Remote Sensing, 55(9), 5324-5338.
22. Zheng, D., van der Velde, R., Su, Z., Wen, J., and Wang, X. (2017). Assessment of Noah land surface model with various runoff parameterizations over a Tibetan river. Journal of Geophysical Research: Atmosphere, 122, 1488-1504.
23. Zheng, D., van der Velde, R., Su, Z., Wen, J., Wang, X., and Yang, K. (2017). Evaluation of Noah Frozen Soil Parameterization for Application to a Tibetan Meadow Ecosystem. Journal of Hydrometeorology, 18(6), 1749-1763.
24. Zheng, D., van der Velde, R., Su, Z., Wen, J., Wang, X., Booij, M. J., Hoekstra, A. Y., Lv, S., Zhang, Y., and Ek, M. B. (2016). Impacts of Noah model physics on catchment-scale runoff simulations. Journal of Geophysical Research: Atmosphere, 121, 807-832.
25. Zheng, D., van der Velde, R., Su, Z., Wang, X., Wen, J., Booij, M. J., Hoekstra, A. Y., and Chen, Y. (2015a). Augmentations to the Noah model physics for application to the Yellow River source area. Part I: Soil water flow. Journal of Hydrometeorology, 16(6), 2659-2676.
26. Zheng, D., van der Velde, R., Su, Z., Wang, X., Wen, J., Booij, M. J., Hoekstra, A. Y., and Chen, Y. (2015b). Augmentations to the Noah model physics for application to the Yellow River source area. Part II: Turbulent heat fluxes and soil heat transport. Journal of Hydrometeorology, 16(6), 2677-2694.
27. Zheng, D., van der Velde, R., Su, Z., Wen, J., Booij, M. J., Hoekstra, A. Y., and Wang, X. (2015). Under-canopy turbulence and root water uptake of a Tibetan meadow ecosystem modeled by Noah-MP. Water Resources Research, 51, 5735-5755.
28. Zheng, D., van der Velde, R., Su, Z., Booij, M. J., Hoekstra, A. Y., and Wen, J. (2014). Assessment of roughness length schemes implemented within the Noah land surface model for high-altitude regions. Journal of Hydrometeorology, 15(3), 921-937.
更多论文见以下个人网页:
ResearchGate: https://www.researchgate.net/profile/Donghai_Zheng
