Past climates inform our future JE Tierney, CJ Poulsen, IP Montañez, T Bhattacharya, R Feng, HL Ford, ... science 370 (6517), eaay3701, 2020 | 346 | 2020 |
The Miocene: The future of the past M Steinthorsdottir, HK Coxall, AM De Boer, M Huber, N Barbolini, ... Paleoceanography and Paleoclimatology 36 (4), e2020PA004037, 2021 | 278 | 2021 |
Tightly linked zonal and meridional sea surface temperature gradients over the past five million years AV Fedorov, NJ Burls, KT Lawrence, LC Peterson Nature Geoscience 8 (12), 975-980, 2015 | 127 | 2015 |
Global mean surface temperature and climate sensitivity of the EECO, PETM and latest Paleocene GN Inglis, F Bragg, N Burls, D Evans, GL Foster, M Huber, DJ Lunt, N Siler, ... Climate of the past Discussions 2020, 1-43, 2020 | 119* | 2020 |
Wetter subtropics in a warmer world: Contrasting past and future hydrological cycles NJ Burls, AV Fedorov Proceedings of the National Academy of Sciences 114 (49), 12888-12893, 2017 | 108 | 2017 |
The Cape Town “Day Zero” drought and Hadley cell expansion NJ Burls, RC Blamey, BA Cash, ET Swenson, AA Fahad, MJM Bopape, ... Npj Climate and Atmospheric Science 2 (1), 27, 2019 | 100 | 2019 |
Active Pacific meridional overturning circulation (PMOC) during the warm Pliocene NJ Burls, AV Fedorov, DM Sigman, SL Jaccard, R Tiedemann, GH Haug Science Advances 3 (9), e1700156, 2017 | 85 | 2017 |
Simulating miocene warmth: insights from an opportunistic multi‐model ensemble (MioMIP1) NJ Burls, CD Bradshaw, AM De Boer, N Herold, M Huber, M Pound, ... Paleoceanography and Paleoclimatology 36 (5), e2020PA004054, 2021 | 78 | 2021 |
Time scales and mechanisms for the tropical Pacific response to global warming: A tug of war between the ocean thermostat and weaker Walker UK Heede, AV Fedorov, NJ Burls Journal of Climate 33 (14), 6101-6118, 2020 | 76 | 2020 |
What controls the mean east–west sea surface temperature gradient in the equatorial Pacific: The role of cloud albedo NJ Burls, AV Fedorov Journal of Climate 27 (7), 2757-2778, 2014 | 75 | 2014 |
Extra-tropical origin of equatorial Pacific cold bias in climate models with links to cloud albedo NJ Burls, L Muir, EM Vincent, A Fedorov Climate Dynamics 49, 2093-2113, 2017 | 60 | 2017 |
Variability in the South Atlantic anticyclone and the Atlantic Niño mode JF Lübbecke, NJ Burls, CJC Reason, MJ McPhaden Journal of Climate 27 (21), 8135-8150, 2014 | 54 | 2014 |
Simulating Pliocene warmth and a permanent El Niño‐like state: The role of cloud albedo NJ Burls, AV Fedorov Paleoceanography 29 (10), 893-910, 2014 | 53 | 2014 |
How will southern hemisphere subtropical anticyclones respond to global warming? Mechanisms and seasonality in CMIP5 and CMIP6 model projections A Fahad, NJ Burls, Z Strasberg Climate dynamics 55, 703-718, 2020 | 41 | 2020 |
Energetics of the tropical Atlantic zonal mode NJ Burls, CJC Reason, P Penven, SG Philander Journal of climate 25 (21), 7442-7466, 2012 | 40 | 2012 |
Evaluating the large-scale hydrological cycle response within the PlioMIP2 ensemble Z Han, Q Zhang, Q Li, R Feng, AM Haywood, JC Tindall, SJ Hunter, ... Climate of the Past Discussions 2021, 1-32, 2021 | 36* | 2021 |
Similarities between the tropical Atlantic seasonal cycle and ENSO: An energetics perspective NJ Burls, CJC Reason, P Penven, SG Philander J. Geophys. Res 116 (C11010), C11010, 2011 | 29 | 2011 |
The strength of low-cloud feedbacks and tropical climate: A CESM sensitivity study E Erfani, NJ Burls Journal of Climate 32 (9), 2497-2516, 2019 | 27 | 2019 |
Sea surface temperature fronts in the midlatitude South Atlantic revealed by using microwave satellite data NJ Burls, CJC Reason Journal of Geophysical Research: Oceans 111 (C8), 2006 | 27 | 2006 |
A stronger versus weaker Walker: understanding model differences in fast and slow tropical Pacific responses to global warming UK Heede, AV Fedorov, NJ Burls Climate Dynamics 57 (9), 2505-2522, 2021 | 26 | 2021 |