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：南京大学，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

      2020.04 至今：南京大学，助理研究员

      陆面过程，陆-气相互作用和区域气候模拟

科研项目

第一/通讯（*）作者论文，下划线表示指导的学生

[13] Liu, Y., Ge, J.*, Guo, W. D.*, Cao, Y. P., Chen, C. R., Luo, X., Yang, L. M. and Wang, S. Y. 2023: Revisiting biophysical impacts of greening on precipitation over the Loess Plateau of China using WRF with water vapor tracers. Geophysical Research Letters, major revision.

[12] Luo, X., Ge, J.*, Guo, W. D., Cao, Y. P., Liu, Y., Chen, C. R. and Yang, L. M. 2023: An evaluation of CMIP6 models in representing the biophysical effects of deforestation with satellite-based observations, Journal of Geophysical Research-Atmospheres, minor revision.

[11] Ge, J.#, Liu, Q.#, Zan, B. L., Lin, Z. Q., Lu, S., Qiu, B. and Guo, W. D. 2022: Deforestation intensifies daily temperature variability in the northern extratropics. Nature Communications, 13, 5955.

[10] Chen, C. R., Ge, J.*, Guo, W. D., Cao, Y. P., Liu, Y., Luo, X. and Yang, L. M. 2022: The biophysical impacts of idealized afforestation on surface temperature in China: the local and nonlocal effects. Journal of Climate, 35(23), 4233-4252.

[9] Luo, X., Ge, J.*, Guo, W. D., Fan, L., Chen, C. R., Liu, Y. and Yang, L. M. 2022: The biophysical impacts of deforestation on precipitation: results from the CMIP6 model intercomparison. Journal of Climate, 35(11), 3293-3311.

[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. 2021: Evaluation of coupled regional climate models in representing the local biophysical effects of afforestation over continental China. Journal of Climate, 34(24), 9879-9898.

[7] Ge, J., Qiu, B., Wu, R. Q., Cao, Y. P., Zhou, W. D., Guo, W. D. and Tang, J. P. 2021: Does dynamic downscaling modify the projected impacts of stabilized 1.5 and 2 ℃ warming on hot extremes over China? Geophysical Research Letters, 48(6).

[6] Ge, J., Pitman, A. J., Guo, W. D., Zan, B. L. and Fu, C. B. 2020: 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.

[5] Qiu, B.*, Ge, J.*, Guo, W. D., Pitman, A. J. and Mu, M. Y. 2020: Responses of Australian dryland vegetation to the 2019 heat waves at a subdaily scale. Geophysical Research Letters, 47(4).

[4] Ge, J., Guo, W. D., Pitman, A. J., De Kauwe, M. G., Chen, X. L. and Fu, C. B. 2019: The non-radiative effect dominates local surface temperature change caused by afforestation in China. Journal of Climate, 32(14), 4445-4471.

[3] Ge, J., Pitman, A. J., Guo, W. D., Wang, S. Y. and Fu, C. B. 2019: 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.

[2] 葛骏, 余晔 , 解晋 , 昝蓓蕾. 2017: 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.

[1] 葛骏, 余晔, 李振朝, 解晋, 刘川, 昝蓓蕾. 2016: 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.

合作作者论文

[12] Mu, M. Y., Pitman, A. J., De Kauwe, M. G., Ukkola, A. M. and Ge, J. 2022: How do groundwater dynamics influence heatwaves in southeast Australia? Weather and Climate Extremes, 37, 100479.

[11] Lu, S., Guo, W. D., Ge, J. and Zhang, Y. 2022: 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.

[10] Lin, Z. Q., Guo, W. D., Ge, J., Wu, R. Q. and Du, J. 2021: 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.

[9] Liu, Y., Guo, W. D., Huang, H. L., Ge, J. and Qiu, B. 2021: Estimating global aerodynamic parameters in 1982-2017 using remote-sensing data and a turbulent transfer model. Remote Sensing of Environment, 260, 112428.

[8] Lu, S., Guo, W. D., Xue, Y. K., Huang, F. and Ge, J. 2021: Sensitivity of higher resolution WRF model to land surface schemes in simulating boreal summer climate over Central Asia. Climate Dynamics, 57(7-8), 2249-2268.

[7] Lin, Z. Q., Guo, W. D., Yao, X. P., Du, J., Li, W. K. and Ge, J. 2021: Tibetan Plateau vortex‐associated precipitation and its link with the Tibetan Plateau heating anomaly. International Journal of Climatology, 41(4), 6300-6313.

[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. 2021: 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.

[5] Zan, B. L., Yu, Y., Li, J. L., Zhao, G., Zhang, T. and Ge, J. 2019: Solving the storm split-merge problem-A combined storm identification, tracking algorithm. Atmospheric Research, 218, 335-346.

[4] Deng, M. S., Meng, X. H., Li, Z. G., Lv, Y. Q., Lei, H. J., Zhao, L., Ge, J. and Jing, H. 2019: 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.

[3] Xie, J., Yu, Y., Li, J. L., Ge, J. and  Liu, C. 2018: Comparison of surface sensible and latent heat fluxes over the Tibetan Plateau from reanalysis and observations. Meteorology and Atmospheric Physics, 131(3), 567-584.

[2] 解晋, 余晔, 刘川, 葛骏. 2018: 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.

[1] 刘川, 余晔, 解晋, 周欣, 李江林, 葛骏. 2015: 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.

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, 南京大学.

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.