葛骏
助理教授(博导,特任研究员)
邮箱:junge@nju.edu.cn
电话:+86-025-89681619
办公室:bwin必赢A504
招生信息
每年招收硕士和博士研究生各1名,欢迎具有大气科学、自然地理学、生态学、遥感科学等专业背景的同学报考(目前2025年硕士和博士名额已招满)。
教育经历
2017.11—2019.03:新南威尔士大学(澳大利亚),联合培养博士
2016.09—2019.12:bwin必赢,大气科学专业,理学博士
2013.09—2016.06:中国科学院西北生态环境资源研究院,气象学专业,理学硕士
2009.09—2013.06:南京信息工程大学,大气科学专业,理学学士
工作经历
2023.10至今:bwin必赢,助理教授
2020.04—2023.09:南京大学,助理研究员(专职科研)
研究方向
● 陆地生态系统-气候相互作用
● 土地利用和覆盖变化的气候效应
● 区域气候模拟
科研项目
[5] 江苏省基础研究专项资金(自然科学基金)优秀青年基金,BK20240170,2024-07至2027-06,在研,主持
[4] 中央高校基本科研业务费创新人才项目,2024300330,2024-06至2024-10,在研,主持
[3] 国家自然科学基金委员会,面上项目,42375115,基于观测和CMIP6/LUMIP试验的毁林/造林生物物理效应模拟评估和约束研究,2024-01至2027-12,在研,主持
[2] bwin必赢队伍建设科研启动经费,2023-10至2026-12,在研,主持
[1] 国家自然科学基金委员会,青年科学基金项目,42005096,中国植树造林的非局地生物物理效应,2021-01至2023-12,结题,主持
奖项荣誉
2024:南京市第十一批中青年拔尖人才
2024:关键地球物质循环前沿科学中心优秀青年人才奖
2024:谢义炳青年气象科技奖
2021:bwin必赢优秀博士学位论文
2019:bwin必赢“博士研究生国际交流奖励计划”一等奖学金
学术论文
第一/通讯(*)作者论文,下划线表示指导的员工
[18] Zan, B. L., Ge, J.*, Mu, M. Y., Sun, Q. H., Luo, X. and Wei, J. F. Spatiotemporal inequality in land water availability amplified by global tree restoration. Nature Water, 2, 863-874 (2024).
[17] Luo, X., Ge, J.*, Cao, Y. P., Liu, Y., Yang, L. M., Wang, S. Y. and Guo, W. D. Local and nonlocal biophysical effects of historical land use and land cover change in CMIP6 models and the intermodel uncertainty. Earth's Future, 12, e2023EF004220 (2024).
[16] Yang, L. M., Ge, J.*, Cao, Y. P., Liu, Y., Luo, X., Wang, S. Y. and Guo, W. D. Enhanced cooling efficiency of urban trees on hotter summer days in 70 cities of China. Advances in Atmospheric Sciences, 41(11), 2259-2275 (2024).
[15] Cao, Y. P., Guo, W. D.*, Ge, J.*, Liu, Y. Chen, C. R., Luo, X. and Yang, L. M. Greening vegetation cools mean and extreme near-surface air temperature in China. Environmental Research Letters, 19, 014040 (2024).
[14] Ge, J., Huang, X., Zan, B. L., Qiu, B., Cao, Y. P. and Guo, W. D. Local surface cooling from afforestation amplified by lower aerosol pollution. Nature Geoscience, 16, 781–788 (2023).
[13] Luo, X., Ge, J.*, Guo, W. D., Cao, Y. P., Liu, Y., Chen, C. R. and Yang, L. M. An evaluation of CMIP6 models in representing the biophysical effects of deforestation with satellite-based observations, Journal of Geophysical Research–Atmospheres, 128(12), e2022JD038198 (2023).
[12] Liu, Y., Ge, J.*, Guo, W. D.*, Cao, Y. P., Chen, C. R., Luo, X., Yang, L. M. and Wang, S. Y. Revisiting biophysical impacts of greening on precipitation over the Loess Plateau of China using WRF with water vapor tracers. Geophysical Research Letters, 50(8), e2023GL102809 (2023).
[11] Ge, J., Liu, Q., Zan, B. L., Lin, Z. Q., Lu, S., Qiu, B. and Guo, W. D. Deforestation intensifies daily temperature variability in the northern extratropics. Nature Communications, 13, 5955 (2022).
[10] Chen, C. R., Ge, J.*, Guo, W. D., Cao, Y. P., Liu, Y., Luo, X. and Yang, L. M. The biophysical impacts of idealized afforestation on surface temperature in China: the local and nonlocal effects. Journal of Climate, 35(23), 4233–4252 (2022).
[9] Luo, X., Ge, J.*, Guo, W. D., Fan, L., Chen, C. R., Liu, Y. and Yang, L. M. The biophysical impacts of deforestation on precipitation: results from the CMIP6 model intercomparison. Journal of Climate, 35(11), 3293–3311 (2022).
[8] Ge, J., Qiu, B., Chu, B. W., Li, D. Z. T., Jiang, L. L., Zhou, W. D., Tang, J. P. and Guo, W. D. Evaluation of coupled regional climate models in representing the local biophysical effects of afforestation over continental China. Journal of Climate, 34(24), 9879–9898 (2021).
[7] Ge, J., Qiu, B., Wu, R. Q., Cao, Y. P., Zhou, W. D., Guo, W. D. and Tang, J. P. Does dynamic downscaling modify the projected impacts of stabilized 1.5 and 2 ℃ warming on hot extremes over China? Geophysical Research Letters, 48(6), e2021GL092792 (2021).
[6] Ge, J., Pitman, A. J., Guo, W. D., Zan, B. L. and Fu, C. B. Impact of revegetation of the Loess Plateau of China on the regional growing season water balance. Hydrology and Earth System Sciences, 24(2), 515–533 (2020).
[5] Qiu, B.*, Ge, J.*, Guo, W. D., Pitman, A. J. and Mu, M. Y. Responses of Australian dryland vegetation to the 2019 heat waves at a subdaily scale. Geophysical Research Letters, 47(4), e2019GL086569 (2020).
[4] Ge, J., Guo, W. D., Pitman, A. J., De Kauwe, M. G., Chen, X. L. and Fu, C. B. The non-radiative effect dominates local surface temperature change caused by afforestation in China. Journal of Climate, 32(14), 4445–4471 (2019).
[3] Ge, J., Pitman, A. J., Guo, W. D., Wang, S. Y. and Fu, C. B. Do uncertainties in the reconstruction of land cover affect the simulation of air temperature and rainfall in the CORDEX region of East Asia? Journal of Geophysical Research–Atmospheres, 124(7), 3647–3670 (2019).
[2] 葛骏, 余晔 , 解晋 , 昝蓓蕾. 青藏高原两类下垫面地表能量分配对气候要素的响应研究. 大气科学, 41(5), 918–932 (2017).
[1] 葛骏, 余晔, 李振朝, 解晋, 刘川, 昝蓓蕾. 青藏高原多年冻土区土壤冻融过程对地表能量通量的影响研究. 高原气象, 35(3), 608–620 (2016).
合作作者论文
[17] Yuan, T. F., Huang, S. J., Zhang, P., Song, Z. C., Ge, J., Miao, X., Wang, Y. J., Pang, Q. T., Peng, D., Wu, P. P., Shao, J. J., Zhang, P. P., Wang, Y. B., Guo, H. Y., Guo, W. D. & Zhang, Y. X. Potential decoupling of CO2 and Hg uptake process by global vegetation in the 21st century. Nature Communications, 15, 4490 (2024).
[16] 崔亚朱, 华文剑, 葛骏, 刘殊瑜, 陈虹玮. 基于 FLUXNET 站点数据的中纬度森林对地表通量的影响研究. 气候与环境研究, 29(2), 1–12 (2024).
[15] Miao, X., Guo, W. D., Li, W. K., Cao, Y. P., Ge, J. and Qiu, B. Instant response of Tibetan Plateau surface albedo to snow coverage and depth in snow season. Geophysical Research Letters, 51(3), e2023GL108010 (2024).
[14] Lin, Z. Q., Guo, W. D., Ge, J., Yao, X. P. and Su, D. S. Interdecadal change of Tibetan Plateau vortices during the past four decades and its possible mechanism. Climate Dynamics, in press (2023).
[13] 林志强, 郭维栋, 姚秀萍, 杜军, 葛骏, 周振波. 基于多源资料的高原低涡源地研究. 大气科学, 47(3), 837–852 (2023).
[12] Mu, M. Y., Pitman, A. J., De Kauwe, M. G., Ukkola, A. M. and Ge, J. How do groundwater dynamics influence heatwaves in southeast Australia? Weather and Climate Extremes, 37, 100479 (2022).
[11] Lu, S., Guo, W. D., Ge, J. and Zhang, Y. Impacts of land surface parameterizations on simulations over an arid and semi-arid region: the case of the Loess Plateau in China. Journal of Hydrometeorology, 23(6), 891–907 (2022).
[10] Lin, Z. Q., Guo, W. D., Ge, J., Wu, R. Q. and Du, J. Increased Tibetan Plateau vortex activities under 2°C warming compared to 1.5°C warming: NCAR CESM low-warming experiments, Advances in Climate Change Research, 12(3), 322–332 (2021).
[9] Liu, Y., Guo, W. D., Huang, H. L., Ge, J. and Qiu, B. Estimating global aerodynamic parameters in 1982-2017 using remote-sensing data and a turbulent transfer model. Remote Sensing of Environment, 260, 112428 (2021).
[8] Lu, S., Guo, W. D., Xue, Y. K., Huang, F. and Ge, J. Simulation of summer climate over Central Asia shows high sensitivity to different land surface schemes in WRF. Climate Dynamics, 57(7-8), 2249–2268 (2021).
[7] Lin, Z. Q., Guo, W. D., Yao, X. P., Du, J., Li, W. K. and Ge, J. Tibetan Plateau vortex‐associated precipitation and its link with the Tibetan Plateau heating anomaly. International Journal of Climatology, 41(4), 6300–6313 (2021).
[6] Ling, X. L., Huang, Y., Guo, W. D., Wang, Y. X., Chen, C. R., Qiu, B., Ge, J., Qin, K., Xue, Y. and Peng, J. Comprehensive evaluation of satellite-based and reanalysis soil moisture products using in situ observations over China. Hydrology and Earth System Science, 25(7), 4209–4229 (2021).
[5] Zan, B. L., Yu, Y., Li, J. L., Zhao, G., Zhang, T. and Ge, J. Solving the storm split-merge problem-A combined storm identification, tracking algorithm. Atmospheric Research, 218, 335–346 (2019).
[4] Deng, M. S., Meng, X. H., Li, Z. G., Lv, Y. Q., Lei, H. J., Zhao, L., Ge, J. and Jing, H. Responses of soil moisture to regional climate change over the Three Rivers Source Region on the Tibetan plateau. International Journal of Climatology, 40(4), 2403–2417 (2019).
[3] Xie, J., Yu, Y., Li, J. L., Ge, J. and Liu, C. Comparison of surface sensible and latent heat fluxes over the Tibetan Plateau from reanalysis and observations. Meteorology and Atmospheric Physics, 131(3), 567–584 (2018).
[2] 解晋, 余晔, 刘川, 葛骏. 青藏高原地表感热通量变化特征及其对气候变化的响应. 高原气象, 37(1), 28–42 (2018).
[1] 刘川, 余晔, 解晋, 周欣, 李江林, 葛骏. 多套土壤温湿度资料在青藏高原的适用性. 高原气象, 34(3), 653–665 (2015).
学位论文
葛骏. 2019: 中国大型生态工程的生物物理过程及其区域气候效应, bwin必赢.
葛骏. 2016: 青藏高原典型下垫面陆-气能量和水分交换特征及其对气候要素的响应, 中国科学院大学.