Global environmental consequences of twenty-first-century ice-sheet melt NR Golledge, ED Keller, N Gomez, KA Naughten, J Bernales, LD Trusel, ... Nature 566 (7742), 65-72, 2019 | 362 | 2019 |
Long-term climate change commitment and reversibility: an EMIC intercomparison K Zickfeld, M Eby, AJ Weaver, K Alexander, E Crespin, NR Edwards, ... Journal of Climate 26 (16), 5782-5809, 2013 | 274 | 2013 |
Stability of the Atlantic meridional overturning circulation: A model intercomparison AJ Weaver, J Sedláček, M Eby, K Alexander, E Crespin, T Fichefet, ... Geophysical Research Letters 39 (20), 2012 | 216 | 2012 |
Historical and idealized climate model experiments: an intercomparison of Earth system models of intermediate complexity M Eby, AJ Weaver, K Alexander, K Zickfeld, A Abe-Ouchi, AA Cimatoribus, ... Climate of the Past 9 (3), 1111-1140, 2013 | 201 | 2013 |
Future projections of Antarctic ice shelf melting based on CMIP5 scenarios KA Naughten, KJ Meissner, BK Galton-Fenzi, MH England, ... Journal of Climate 31 (13), 5243-5261, 2018 | 91 | 2018 |
Twenty first century changes in Antarctic and Southern Ocean surface climate in CMIP6 TJ Bracegirdle, G Krinner, M Tonelli, FA Haumann, KA Naughten, ... Atmospheric Science Letters 21 (9), e984, 2020 | 76 | 2020 |
Two-timescale response of a large Antarctic ice shelf to climate change KA Naughten, J De Rydt, SHR Rosier, A Jenkins, PR Holland, JK Ridley Nature communications 12 (1), 1991, 2021 | 72 | 2021 |
Simulated twentieth‐century ocean warming in the Amundsen Sea, West Antarctica KA Naughten, PR Holland, P Dutrieux, S Kimura, DT Bett, A Jenkins Geophysical Research Letters 49 (5), e2021GL094566, 2022 | 46 | 2022 |
The software architecture of climate models: a graphical comparison of CMIP5 and EMICAR5 configurations K Alexander, SM Easterbrook Geoscientific Model Development 8 (4), 1221-1232, 2015 | 44 | 2015 |
Necessary conditions for warm inflow toward the Filchner Ice Shelf, Weddell Sea K Daae, T Hattermann, E Darelius, RD Mueller, KA Naughten, ... Geophysical Research Letters 47 (22), e2020GL089237, 2020 | 33 | 2020 |
The Paleocene‐Eocene Thermal Maximum: How much carbon is enough? KJ Meissner, TJ Bralower, K Alexander, TD Jones, W Sijp, M Ward Paleoceanography 29 (10), 946-963, 2014 | 31 | 2014 |
Sudden spreading of corrosive bottom water during the Palaeocene-Eocene Thermal Maximum K Alexander, KJ Meissner, TJ Bralower Nature Geoscience 8 (6), 458, 2015 | 29 | 2015 |
Spurious sea ice formation caused by oscillatory ocean tracer advection schemes KA Naughten, BK Galton-Fenzi, KJ Meissner, MH England, ... Ocean Modelling 116, 108-117, 2017 | 24 | 2017 |
Intercomparison of Antarctic ice-shelf, ocean, and sea-ice interactions simulated by MetROMS-iceshelf and FESOM 1.4 KA Naughten, KJ Meissner, BK Galton-Fenzi, MH England, ... Geoscientific Model Development 11 (4), 1257-1292, 2018 | 23 | 2018 |
Modeling the influence of the Weddell polynya on the Filchner–Ronne ice shelf cavity KA Naughten, A Jenkins, PR Holland, RI Mugford, KW Nicholls, ... Journal of Climate 32 (16), 5289-5303, 2019 | 22 | 2019 |
The dynamics of global change at the P aleocene‐E ocene thermal maximum: A data‐model comparison TJ Bralower, KJ Meissner, K Alexander, DJ Thomas Geochemistry, Geophysics, Geosystems 15 (10), 3830-3848, 2014 | 21 | 2014 |
Anthropogenic and internal drivers of wind changes over the Amundsen Sea, West Antarctica, during the 20th and 21st centuries PR Holland, GK O'Connor, TJ Bracegirdle, P Dutrieux, KA Naughten, ... The Cryosphere 16 (12), 5085-5105, 2022 | 19 | 2022 |
Baroclinic ocean response to climate forcing regulates decadal variability of ice‐shelf melting in the Amundsen Sea A Silvano, PR Holland, KA Naughten, O Dragomir, P Dutrieux, A Jenkins, ... Geophysical Research Letters 49 (24), e2022GL100646, 2022 | 18 | 2022 |
The stability of present-day Antarctic grounding lines–Part B: Possible commitment of regional collapse under current climate R Reese, J Garbe, EA Hill, B Urruty, KA Naughten, O Gagliardini, ... The Cryosphere Discussions 2022, 1-33, 2022 | 14 | 2022 |
Modelling Antarctic ice shelf, ocean, and sea ice interactions under present-day and future climate scenarios K Naughten UNSW Sydney, 2018 | 1 | 2018 |