| The impact of westerly wind bursts and ocean initial state on the development, and diversity of El Niño events AV Fedorov, S Hu, M Lengaigne, E Guilyardi Climate Dynamics 44, 1381-1401, 2015 | 203 | 2015 |
| The extreme El Niño of 2015–2016 and the end of global warming hiatus S Hu, AV Fedorov Geophysical Research Letters 44 (8), 3816-3824, 2017 | 175 | 2017 |
| Exceptionally strong easterly wind burst stalling El Niño of 2014 S Hu, AV Fedorov Proceedings of the National Academy of Sciences 113 (8), 2005-2010, 2016 | 170 | 2016 |
| Climate impacts of a weakened Atlantic Meridional Overturning Circulation in a warming climate W Liu, AV Fedorov, SP Xie, S Hu Science advances 6 (26), eaaz4876, 2020 | 166 | 2020 |
| Cross-equatorial winds control El Niño diversity and change S Hu, AV Fedorov Nature Climate Change 8 (9), 798-802, 2018 | 120 | 2018 |
| The extreme El Niño of 2015–2016: The role of westerly and easterly wind bursts, and preconditioning by the failed 2014 event S Hu, AV Fedorov Climate Dynamics 52 (12), 7339-7357, 2019 | 112 | 2019 |
| The impact of westerly wind bursts on the diversity and predictability of El Niño events: An ocean energetics perspective S Hu, AV Fedorov, M Lengaigne, E Guilyardi Geophysical research letters 41 (13), 4654-4663, 2014 | 97 | 2014 |
| Indian Ocean warming can strengthen the Atlantic meridional overturning circulation S Hu, AV Fedorov Nature climate change 9 (10), 747-751, 2019 | 82 | 2019 |
| Glacial to Holocene changes in trans-Atlantic Saharan dust transport and dust-climate feedbacks RH Williams, D McGee, CW Kinsley, DA Ridley, S Hu, A Fedorov, I Tal, ... Science advances 2 (11), e1600445, 2016 | 60 | 2016 |
| Indian Ocean warming as a driver of the North Atlantic warming hole S Hu, AV Fedorov Nature communications 11 (1), 4785, 2020 | 52 | 2020 |
| Eastern Pacific wind effect on the evolution of El Niño: Implications for ENSO diversity Q Peng, SP Xie, D Wang, Y Kamae, H Zhang, S Hu, XT Zheng, W Wang Journal of Climate 33 (8), 3197-3212, 2020 | 33 | 2020 |
| ENSO low‐frequency modulation and mean state interactions AV Fedorov, S Hu, AT Wittenberg, AFZ Levine, C Deser El Niño southern oscillation in a changing climate, 173-198, 2020 | 31 | 2020 |
| Meridional structure and future changes of tropopause height and temperature S Hu, GK Vallis Quarterly Journal of the Royal Meteorological Society 145 (723), 2698-2717, 2019 | 28 | 2019 |
| Global pattern formation of net ocean surface heat flux response to greenhouse warming S Hu, SP Xie, W Liu Journal of Climate 33 (17), 7503-7522, 2020 | 21 | 2020 |
| An interpretable deep learning ENSO forecasting model H Wang, S Hu, X Li Ocean-Land-Atmosphere Research 2, 0012, 2023 | 17 | 2023 |
| Historical changes in wind‐driven ocean circulation can accelerate global warming K McMonigal, S Larson, S Hu, R Kramer Geophysical Research Letters 50 (4), e2023GL102846, 2023 | 17 | 2023 |
| Global warming pattern formation: The role of ocean heat uptake S Hu, SP Xie, SM Kang Journal of Climate 35 (6), 1885-1899, 2022 | 17 | 2022 |
| Disentangling the mechanisms of equatorial Pacific climate change SM Kang, Y Shin, H Kim, SP Xie, S Hu Science advances 9 (19), eadf5059, 2023 | 14 | 2023 |
| North Pacific temperature and precipitation response to El Niño-like equatorial heating: sensitivity to forcing location J Shi, AV Fedorov, S Hu Climate Dynamics 53 (5), 2731-2741, 2019 | 13 | 2019 |
| The physics of orographic elevated heating in radiative–convective equilibrium S Hu, WR Boos Journal of the Atmospheric Sciences 74 (9), 2949-2965, 2017 | 13 | 2017 |
Alexey V. FedorovYale University在 yale.edu 的电子邮件经过验证
