电子邮箱:c5f842133f36a812d0cf72f651b71c73b828a6845988c7d8c28dd63a21e0b0c35f12d68571dffd3b70ffd8572b5465c0c58a8adfde07e21f3d21cc4e39d356508d45a9150afb56429c899577f26ef0fac6907142e09304c985cdce719c571bf6c59626ba91c94f94415bf227a09603c06a04022a0695f8bd848e867490a5d16a
学科:大气科学
1、提出了一种基于深度学习的海表粗糙度参数化方案,成功将该方案应用到课题组开发的西北太平洋区域的海洋-大气-波浪耦合模式WindWave1.0中。在2020年8月的五个台风案例中,与四个传统方案相比,在24、48和72小时预报时效,使用新方案预报的海表风的RMSE分别降低了6.02%至14.75%、11.17%至18.30%和11.91%至19.46%,这表明新的海表粗糙度方案能够成功改进西北太平洋海表风的预报。
2、率先论证了北极涛动与西伯利亚高压不存在典型的负相关关系。
3、发现了东亚冬季的暖环流型容易向冷环流型转换,而冷环流型倾向于转换为另外一种冷环流型。
4、率先揭示了欧洲阻塞活动对华南冬季极端降水的激发机制,并发现了华南冬季极端降水的主要水汽来源依次为南海、西北太平洋、东海、华南自身和东南亚。
近期发表论文:
[1] Huang W*, X. He, Z. Yang, T. Qiu, J. S. Wright, B. Wang, and D. Lin (2018), Moisture sources for wintertime extreme precipitation events over South China during1979-2013,Journal of Geophysical Research: Atmospheres,doi:10.1002/2018JD028485.
[2] Huang W*, Z. Yang, X. He, D. Lin, B. Wang, J. S. Wright, R. Chen, W. Ma, and F. Li (2018),A possible mechanism for the occurrence of wintertime extreme precipitation events over South China,Climate Dynamics,doi:10.1007/s00382-018-4262-8.
[3] Huang, W*, R. Chen, Z. Yang, B. Wang, and W. Ma (2017), Exploring the combined effects of the Arctic Oscillation and ENSO on the wintertime climate over East Asia using self-organizing maps, Journal of Geophysical Research: Atmospheres, 122, 9107–9129, doi:10.1002/2017JD026812.
[4] Yang, Z.,W. Huang*, B. Wang, R. Chen, J. S. Wright, and W. Ma (2017), Possible mechanisms for four regimes associated with cold events over East Asia,Climate Dynamics, doi:10.1007/s00382-017-3905-5.
[5] Chen R.,W. Huang*, B. Wang, Z. Yang, J. S. Wright, and W. Ma (2017),On the co-occurrence of wintertime temperature anomalies over eastern Asia and eastern North America,Journal of Geophysical Research: Atmospheres,doi:10.1002/2016jd026435.
[6]Huang, W.*, R. Chen, B. Wang, J. S. Wright, Z. Yang, and W. Ma (2017), Potential vorticity regimes over East Asia during winter,Journal of Geophysical Research: Atmospheres,doi: 10.1002/2016JD025893.
[7] Shi, Y., B. Wang, andW. Huang* (2017), A “self-adjustment” mechanism for mixed-layer heat budget in the equatorial Atlantic cold tongue,Atmospheric Science Letters, doi:10.1002/asl.728.
[8]Huang, W.*, B. Wang, and J. S. Wright (2016), A potential vorticity-based index for the East Asian winter monsoon,Journal of Geophysical Research: Atmospheres,121(16), 9382-9399, doi:10.1002/2016JD025053.
[9]Huang, W. *, B. Wang, J. S. Wright, and R. Chen (2016), On the Non-Stationary Relationship between the Siberian High and Arctic Oscillation,PLoS ONE,11(6), 15, doi:10.1371/journal.pone.0158122.
[10]Huang, W., B. Wang, Y. Yu, and L. Li (2014), Improvements in LICOM2. Part I: Vertical Mixing,Journal of Atmospheric and Oceanic Technology,31(2), 531-544, doi:10.1175/jtech-d-13-00065.1.
[11]Huang, W., B. Wang, L. Li, and Y. Yu (2014), Improvements in LICOM2. Part II: Arctic Circulation,Journal of Atmospheric and Oceanic Technology,31(1), 233-245, doi:10.1175/jtech-d-13-00064.1.
[12]Huang, W., et al. (2014), Variability of atlantic meridional overturning circulation in FGOALS-g2,Advances in Atmospheric Sciences,31(1), 95-109, doi:10.1007/s00376-013-2155-7.
[13]黄文誉*,王斌,李立娟,等. 2014,耦合模式FGOALS-g2中大西洋经向翻转流对3个典型浓度路径的响应,气候与环境研究,19(6), 670-682,doi:10.3878/j.issn.1006-9585.2013.13130.
[14] Dong, F., Y. Li, B. Wang,W. Huang, Y. Shi, and W. Dong (2016), Global Air-Sea CO2 Flux in 22 CMIP5 Models: Multiyear Mean and Interannual Variability,Journal of Climate,29(7), 2407-2431, doi:10.1175/jcli-d-14-00788.1.
[15] Dong, W., Y. Lin., J. S. Wright, Y. Ming, Y. Xie, B. Wang, Y. Luo,W. Huang, J. Huang, L. Wang, L. Tian, Y. Peng, and F. Xu (2016), Summer rainfall over the southwestern Tibetan Plateau controlled by deep convection over the Indian subcontinent,Nature Communications,7, doi:10.1038/ncomms10925.
