Lenton, T. M. et al. The Global Tipping Points Report 2023 (Univ. of Exeter, 2023). This report assesses Earth system and social tipping points, aiming to inform decision-makers and the public about the risks and opportunities associated with the urgent global challenges of climate change and biodiversity loss.<\/p>\n
Biggs, R., Carpenter, S. R. & Brock, W. A. Turning back from the brink: detecting an impending regime shift in time to avert it. Proc. Natl Acad. Sci. USA 106, 826\u2013831 (2009).<\/p>\n
ADS<\/a>\u00a0 Rocha, J. C., Peterson, G., Bodin, \u00d6. & Levin, S. Cascading regime shifts within and across scales. Science 362, 1379\u20131383 (2018).<\/p>\n ADS<\/a>\u00a0 Folke, C. et al. Regime shifts, resilience, and biodiversity in ecosystem management. Annu. Rev. Ecol. Evolut. Systemat. 35, 557\u2013581 (2004).<\/p>\n Armstrong McKay, D. I. et al. Exceeding 1.5 \u00b0C global warming could trigger multiple climate tipping points. Science 377, eabn7950 (2022).<\/p>\n PubMed<\/a>\u00a0 Kopp, R. E. et al. \u2018Tipping points\u2019 confuse and can distract from urgent climate action. Nat. Clim. Change 15, 29\u201336 (2025). This article critiques the tipping points framework by examining the history and effectiveness of this framework, and provides recommendations for clearer and more specific descriptions of abrupt changes to better inform decision making.<\/p>\n IPCC. Summary for Policymakers, in IPCC Special Report on the Ocean and Cryosphere in a Changing Climate (eds P\u00f6rtner H.-O. et al.) (Cambridge Univ. Press, 2019).<\/p>\n Meredith, M. et al. Polar Regions, in IPCC Special Report on the Ocean and Cryosphere in a Changing Climate (eds P\u00f6rtner, H.-O. et al.) 203\u2013320 (Cambridge Univ. Press, 2019).<\/p>\n Fox-Kemper, B. et al. Ocean, Cryosphere and Sea Level Change, in Climate Change 2021: The Physical Science Basis (eds Masson-Delmotte, V. et al.) 1211\u20131362 (Cambridge Univ. Press, 2021).<\/p>\n Constable, A. J. et al. Cross-Chapter Paper 6: Polar Regions, in Climate Change 2022: Impacts, Adaptation and Vulnerability (eds P\u00f6rtner, H.-O. et al.) 2319\u20132368 (Cambridge Univ. Press, 2022).<\/p>\n Turner, J., Hosking, J. S., Bracegirdle, T. J., Marshall, G. J. & Phillips, T. Recent changes in Antarctic Sea Ice. Phil. Trans. R. Soc. A 373, 20140163 (2015).<\/p>\n ADS<\/a>\u00a0 Bintanja, R., van Oldenborgh, G. J., Drijfhout, S. S., Wouters, B. & Katsman, C. A. Important role for ocean warming and increased ice-shelf melt in Antarctic sea-ice expansion. Nat. Geosci. 6, 376\u2013379 (2013).<\/p>\n ADS<\/a>\u00a0 Holland, P. R. & Kwok, R. Wind-driven trends in Antarctic sea-ice drift. Nat. Geosci. 5, 872\u2013875 (2012).<\/p>\n ADS<\/a>\u00a0 Ferreira, D., Marshall, J., Bitz, C. M., Solomon, S. & Plumb, A. Antarctic Ocean and sea ice response to ozone depletion: a two-time-scale problem. J. Clim. 28, 1206\u20131226 (2015).<\/p>\n ADS<\/a>\u00a0 Banerjee, A., Fyfe, J. C., Polvani, L. M., Waugh, D. & Chang, K.-L. A pause in Southern Hemisphere circulation trends due to the Montreal Protocol. Nature 579, 544\u2013548 (2020).<\/p>\n ADS<\/a>\u00a0 Schroeter, S., O\u2019Kane, T. J. & Sandery, P. A. Antarctic sea ice regime shift associated with decreasing zonal symmetry in the Southern Annular Mode. The Cryosphere 17, 701\u2013717 (2023).<\/p>\n ADS<\/a>\u00a0 Siegert, M. J. et al. Antarctic extreme events. Front. Environ. Sci. https:\/\/doi.org\/10.3389\/fenvs.2023.1229283<\/a> (2023).<\/p>\n Gilbert, E. & Holmes, C. 2023\u2019s Antarctic sea ice extent is the lowest on record. Weather 79, 46\u201351 (2024).<\/p>\n ADS<\/a>\u00a0 Purich, A. & Doddridge, E. W. Record low Antarctic sea ice coverage indicates a new sea ice state. Commun. Earth Environ. 4, 314 (2023). This influential study demonstrates that Antarctic sea ice has shifted to a new low sea-ice state, and connects this regime shift to the confluence with subsurface warming of the Southern Ocean.<\/p>\n ADS<\/a>\u00a0 Hobbs, W. et al. Observational evidence for a regime shift in summer Antarctic sea ice. J. Clim. 37, 2263\u20132275 (2024).<\/p>\n ADS<\/a>\u00a0 Fogt, R. L., Sleinkofer, A. M., Raphael, M. N. & Handcock, M. S. A regime shift in seasonal total Antarctic sea ice extent in the twentieth century. Nat. Clim. Change 12, 54\u201362 (2022). This study developed an observation-based reconstruction of Antarctic sea-ice extent that demonstrated the increase in Antarctic sea ice during the satellite era was unusual in a twentieth century context, and also provides a basis for demonstrating the extraordinary nature of abrupt sea-ice loss since 2014.<\/p>\n ADS<\/a>\u00a0 Dalaiden, Q. et al. An unprecedented sea ice retreat in the Weddell Sea driving an overall decrease of the Antarctic sea-ice extent over the 20th century. Geophys. Res. Lett. 50, e2023GL104666 (2023).<\/p>\n ADS<\/a>\u00a0 Goosse, H., Dalaiden, Q., Feba, F., Mezzina, B. & Fogt, R. L. A drop in Antarctic sea ice extent at the end of the 1970s. Commun. Earth Environ. 5, 628 (2024).<\/p>\n Raphael, M. N., Maierhofer, T. J., Fogt, R. L., Hobbs, W. R. & Handcock, M. S. A twenty-first century structural change in Antarctica\u2019s sea ice system. Commun. Earth Environ. 6, 131 (2025).<\/p>\n Maierhofer, T. J., Raphael, M. N., Fogt, R. L. & Handcock, M. S. A Bayesian model for 20th century Antarctic sea ice extent reconstruction. Earth Space Sci. 11, e2024EA003577 (2024).<\/p>\n Morioka, Y. et al. Antarctic sea ice multidecadal variability triggered by Southern Annular Mode and deep convection. Commun. Earth Environ. 5, 633 (2024).<\/p>\n Boers, N. Observation-based early-warning signals for a collapse of the Atlantic Meridional Overturning Circulation. Nat. Clim. Change 11, 680\u2013688 (2021).<\/p>\n ADS<\/a>\u00a0 Dakos, V. et al. Tipping point detection and early warnings in climate, ecological, and human systems. Earth Syst. Dynam. 15, 1117\u20131135 (2024).<\/p>\n Espinosa, Z. I., Blanchard-Wrigglesworth, E. & Bitz, C. M. Understanding the drivers and predictability of record low Antarctic sea ice in austral winter 2023. Commun. Earth Environ. 5, 723 (2024).<\/p>\n Zhang, L. et al. The relative role of the subsurface Southern Ocean in driving negative Antarctic Sea ice extent anomalies in 2016\u20132021. Commun. Earth Environ. 3, 302 (2022).<\/p>\n ADS<\/a>\u00a0 Himmich, K. et al. Thermodynamics drive post-2016 changes in the Antarctic sea ice seasonal cycle. J. Geophys. Res. Oceans 129, e2024JC021112 (2024).<\/p>\n Lenton, T. M. et al. Tipping elements in the Earth\u2019s climate system. Proc. Natl Acad. Sci. USA 105, 1786\u20131793 (2008).<\/p>\n ADS<\/a>\u00a0 Chamberlain, M. A., Ziehn, T. & Law, R. M. The Southern Ocean as the climate\u2019s freight train\u2014driving ongoing global warming under zero-emission scenarios with ACCESS-ESM1.5. Biogeosciences 21, 3053\u20133073 (2024).<\/p>\n CAS<\/a>\u00a0 King, A. D. et al. Exploring climate stabilisation at different global warming levels in ACCESS-ESM-1.5. Earth Syst. Dynam. 15, 1353\u20131383 (2024).<\/p>\n Morioka, Y. et al. Role of anthropogenic forcing in Antarctic sea ice variability simulated in climate models. Nat. Commun. 15, 10511 (2024).<\/p>\n CAS<\/a>\u00a0 King, A. D., Abram, N. J., Alastru\u00e9 de Asenjo, E. & Ziehn, T. ESD Ideas: Extended net zero simulations are critical for informed decision making. EGUsphere https:\/\/doi.org\/10.5194\/egusphere-2025-903<\/a> (2025).<\/p>\n Holmes, C. R., Bracegirdle, T. J., Holland, P. R., Stroeve, J. & Wilkinson, J. New perspectives on the skill of modelled sea ice trends in light of recent Antarctic sea ice loss. Cryosphere 18, 5641\u20135652 (2024). This paper demonstrates that recent unprecedented Antarctic sea-ice loss challenges the skill of current climate models in accurately predicting sea-ice trends, emphasizing the urgent need for model refinements to better capture potential abrupt changes.<\/p>\n Duspayev, A., Flanner, M. G. & Riihel\u00e4, A. Earth\u2019s sea ice radiative effect from 1980 to 2023. Geophys. Res. Lett. 51, e2024GL109608 (2024).<\/p>\n Rantanen, M. et al. The Arctic has warmed nearly four times faster than the globe since 1979. Commun. Earth Environ. 3, 168 (2022).<\/p>\n ADS<\/a>\u00a0 Vogt, L. et al. Increased future ocean heat uptake constrained by Antarctic sea ice extent. Preprint at Res. Sq. https:\/\/doi.org\/10.21203\/rs.3.rs-3982037\/v2<\/a> (2025).<\/p>\n England, M. R., Polvani, L. M., Sun, L. & Deser, C. Tropical climate responses to projected Arctic and Antarctic sea-ice loss. Nat. Geosci. 13, 275\u2013281 (2020).<\/p>\n ADS<\/a>\u00a0 Ayres, H. C., Screen, J. A., Blockley, E. W. & Bracegirdle, T. J. The coupled atmosphere\u2013ocean response to Antarctic sea ice loss. J. Clim. 35, 4665\u20134685 (2022).<\/p>\n ADS<\/a>\u00a0 Zhou, S. et al. Slowdown of Antarctic Bottom Water export driven by climatic wind and sea-ice changes. Nat. Clim. Change 13, 701\u2013709 (2023).<\/p>\n ADS<\/a>\u00a0 Silvano, A. et al. Recent recovery of Antarctic Bottom Water formation in the Ross Sea driven by climate anomalies. Nat. Geosci. 13, 780\u2013786 (2020).<\/p>\n ADS<\/a>\u00a0 Josey, S. A. et al. Record-low Antarctic sea ice in 2023 increased ocean heat loss and storms. Nature 636, 635\u2013639 (2024).<\/p>\n CAS<\/a>\u00a0 Reid, P. A. & Massom, R. A. Change and variability in Antarctic coastal exposure, 1979\u20132020. Nat. Commun. 13, 1164 (2022).<\/p>\n ADS<\/a>\u00a0 Fretwell, P. T., Boutet, A. & Ratcliffe, N. Record low 2022 Antarctic sea ice led to catastrophic breeding failure of emperor penguins. Commun. Earth Environ. 4, 273 (2023). The catastrophic regional-scale breeding failure of emperor penguins in 2022 due to record low Antarctic sea ice underscores the vulnerability of polar ecosystems to climate-driven abrupt change, highlighting the potential for irreversible ecological shifts.<\/p>\n ADS<\/a>\u00a0 Kawaguchi, S. et al. Climate change impacts on Antarctic krill behaviour and population dynamics. Nat. Rev. Earth Environ. 5, 43\u201358 (2024).<\/p>\n ADS<\/a>\u00a0 McManus, J. F., Francois, R., Gherardi, J. M., Keigwin, L. D. & Brown-Leger, S. Collapse and rapid resumption of Atlantic meridional circulation linked to deglacial climate changes. Nature 428, 834\u2013837 (2004).<\/p>\n ADS<\/a>\u00a0 Abernathey, R. P. et al. Water-mass transformation by sea ice in the upper branch of the Southern Ocean overturning. Nat. Geosci. 9, 596\u2013601 (2016).<\/p>\n ADS<\/a>\u00a0 Heuz\u00e9, C. Antarctic Bottom Water and North Atlantic Deep Water in CMIP6 models. Ocean Sci. 17, 59\u201390 (2021).<\/p>\n ADS<\/a>\u00a0 Purich, A. & England, M. H. Historical and future projected warming of Antarctic Shelf Bottom Water in CMIP6 models. Geophys. Res. Lett. 48, e2021GL092752 (2021).<\/p>\n ADS<\/a>\u00a0 de Lavergne, C., Palter, J. B., Galbraith, E. D., Bernardello, R. & Marinov, I. Cessation of deep convection in the open Southern Ocean under anthropogenic climate change. Nat. Clim. Change 4, 278\u2013282 (2014).<\/p>\n Lago, V. & England, M. H. Projected slowdown of Antarctic Bottom Water formation in response to amplified meltwater contributions. J. Clim. 32, 6319\u20136335 (2019).<\/p>\n ADS<\/a>\u00a0 Li, Q., England, M. H., Hogg, A. M., Rintoul, S. R. & Morrison, A. K. Abyssal ocean overturning slowdown and warming driven by Antarctic meltwater. Nature 615, 841\u2013847 (2023). Using a high-resolution ocean model that captures the four known regions of Antarctic Bottom Water formation, this study projects a 40% slowdown of the Antarctic Overturning Circulation by 2050 in response to expected increases in Antarctic meltwater.<\/p>\n ADS<\/a>\u00a0 Huneke, W. G. C., Hobbs, W. R., Klocker, A. & Naughten, K. A. Dynamic response to ice shelf basal meltwater relevant to explain observed sea ice trends near the Antarctic Continental Shelf. Geophys. Res. Lett. 50, e2023GL105435 (2023).<\/p>\n ADS<\/a>\u00a0 Jacobs, S. S., Giulivi, C. F. & Dutrieux, P. Persistent Ross Sea freshening from imbalance West Antarctic ice shelf melting. J. Geophys. Res. Oceans 127, e2021JC017808 (2022).<\/p>\n ADS<\/a>\u00a0 Gunn, K. L., Rintoul, S. R., England, M. H. & Bowen, M. M. Recent reduced abyssal overturning and ventilation in the Australian Antarctic Basin. Nat. Clim. Change 13, 537\u2013544 (2023). Observations from the Australian Antarctic Basin show that over recent decades there has been a reduction in Antarctic Bottom Water transport, coincident with a strong freshening on the continental shelf; this finding is reinforced by equivalent observations from the Weddell sector (ref. 43).<\/p>\n ADS<\/a>\u00a0 Schmidt, C., Morrison, A. K. & England, M. H. Wind- and sea-ice-driven interannual variability of Antarctic Bottom Water formation. J. Geophys. Res. Oceans 128, e2023JC019774 (2023).<\/p>\n ADS<\/a>\u00a0 Adkins, J. F. The role of deep ocean circulation in setting glacial climates. Paleoceanography 28, 539\u2013561 (2013).<\/p>\n ADS<\/a>\u00a0 Ferrari, R. et al. Antarctic sea ice control on ocean circulation in present and glacial climates. Proc. Natl Acad. Sci. USA 111, 8753\u20138758 (2014).<\/p>\n ADS<\/a>\u00a0 Burke, A. & Robinson, L. F. The Southern Ocean\u2019s role in carbon exchange during the Last Deglaciation. Science 335, 557\u2013561 (2012).<\/p>\n ADS<\/a>\u00a0 Skinner, L. C., Fallon, S., Waelbroeck, C., Michel, E. & Barker, S. Ventilation of the deep Southern Ocean and deglacial CO2 rise. Science 328, 1147\u20131151 (2010).<\/p>\n ADS<\/a>\u00a0 Rae, J. W. B. et al. CO2 storage and release in the deep Southern Ocean on millennial to centennial timescales. Nature 562, 569\u2013573 (2018).<\/p>\n ADS<\/a>\u00a0 Huang, H., Gutjahr, M., Eisenhauer, A. & Kuhn, G. No detectable Weddell Sea Antarctic Bottom Water export during the Last and Penultimate Glacial Maximum. Nat. Commun. 11, 424 (2020).<\/p>\n ADS<\/a>\u00a0 Weber, M. E. et al. Millennial-scale variability in Antarctic ice-sheet discharge during the last deglaciation. Nature 510, 134\u2013138 (2014).<\/p>\n ADS<\/a>\u00a0 Yeung, N. K. H., Menviel, L., Meissner, K. J. & Sikes, E. Assessing the spatial origin of meltwater pulse 1A using oxygen-isotope fingerprinting. Paleoceanogr. Paleoclimatol. 34, 2031\u20132046 (2019).<\/p>\n ADS<\/a>\u00a0 Golledge, N. R. et al. Antarctic contribution to meltwater pulse 1A from reduced Southern Ocean overturning. Nat. Commun. 5, 5107 (2014).<\/p>\n ADS<\/a>\u00a0 Turney, C. S. M. et al. Early Last Interglacial ocean warming drove substantial ice mass loss from Antarctica. Proc. Natl Acad. Sci. USA 117, 3996\u20134006 (2020).<\/p>\n ADS<\/a>\u00a0 Blackburn, T. et al. Ice retreat in Wilkes Basin of East Antarctica during a warm interglacial. Nature 583, 554\u2013559 (2020).<\/p>\n ADS<\/a>\u00a0 Hayes, C. T. et al. A stagnation event in the deep South Atlantic during the last interglacial period. Science 346, 1514\u20131517 (2014).<\/p>\n ADS<\/a>\u00a0 Glasscock, S. K., Hayes, C. T., Redmond, N. & Rohde, E. Changes in Antarctic Bottom Water formation during interglacial periods. Paleoceanogr. Paleoclimatol. 35, e2020PA003867 (2020).<\/p>\n ADS<\/a>\u00a0 Rohling, E. J. et al. Asynchronous Antarctic and Greenland ice-volume contributions to the last interglacial sea-level highstand. Nat. Commun. 10, 5040 (2019).<\/p>\n ADS<\/a>\u00a0 Yeung, N. K.-H. et al. Last Interglacial subsurface warming on the Antarctic shelf triggered by reduced deep-ocean convection. Commun. Earth Environ. 5, 212 (2024).<\/p>\n ADS<\/a>\u00a0 Bronselaer, B. et al. Change in future climate due to Antarctic meltwater. Nature 564, 53\u201358 (2018). Global climate impacts of Antarctic meltwater are shown to be far-reaching using a coupled climate model, identifying global surface temperature changes, shifting tropical precipitation and subsurface warming around the Antarctic margins that may accelerate ice shelf basal melting.<\/p>\n ADS<\/a>\u00a0 Ribeiro, N. et al. Warm modified Circumpolar Deep Water intrusions drive ice shelf melt and inhibit dense shelf water formation in Vincennes Bay, East Antarctica. J. Geophys. Res. Oceans 126, e2020JC016998 (2021).<\/p>\n ADS<\/a>\u00a0 Rintoul, S. R. et al. Ocean heat drives rapid basal melt of the Totten Ice Shelf. Sci. Adv. 2, e1601610 (2016).<\/p>\n ADS<\/a>\u00a0 Adusumilli, S., Fricker, H. A., Medley, B., Padman, L. & Siegfried, M. R. Interannual variations in meltwater input to the Southern Ocean from Antarctic ice shelves. Nat. Geosci. 13, 616\u2013620 (2020).<\/p>\n ADS<\/a>\u00a0 Naughten, K. A., Holland, P. R. & De Rydt, J. Unavoidable future increase in West Antarctic ice-shelf melting over the twenty-first century. Nat. Clim. Change 13, 1222\u20131228 (2023). Regional ocean modelling finds rapid ocean warming in the Amundsen Sea for a range of different emission scenarios, suggesting that future mitigation efforts cannot prevent ocean-driven melting of ice shelves in this region.<\/p>\n ADS<\/a>\u00a0 Ribeiro, N. et al. Oceanic regime shift to a warmer continental shelf adjacent to the Shackleton Ice Shelf, East Antarctica. J. Geophys. Res. Oceans 128, e2023JC019882 (2023).<\/p>\n ADS<\/a>\u00a0 Mathiot, P. & Jourdain, N. C. Southern Ocean warming and Antarctic ice shelf melting in conditions plausible by late 23rd century in a high-end scenario. Ocean Sci. 19, 1595\u20131615 (2023).<\/p>\n ADS<\/a>\u00a0 Gottschalk, J. et al. Biological and physical controls in the Southern Ocean on past millennial-scale atmospheric CO2 changes. Nat. Commun. 7, 11539 (2016).<\/p>\n ADS<\/a>\u00a0 Long, M. C. et al. Strong Southern Ocean carbon uptake evident in airborne observations. Science 374, 1275\u20131280 (2021).<\/p>\n ADS<\/a>\u00a0 Liu, Y., Moore, J. K., Primeau, F. & Wang, W. L. Reduced CO2 uptake and growing nutrient sequestration from slowing overturning circulation. Nat. Clim. Change 13, 83\u201390 (2023).<\/p>\n ADS<\/a>\u00a0 Dong, Y., Pauling, A. G., Sadai, S. & Armour, K. C. Antarctic ice-sheet meltwater reduces transient warming and climate sensitivity through the sea-surface temperature pattern effect. Geophys. Res. Lett. 49, e2022GL101249 (2022).<\/p>\n ADS<\/a>\u00a0 Shin, S.-J. et al. Southern Ocean control of 2\u2009\u00b0C global warming in climate models. Earth Future 11, e2022EF003212 (2023).<\/p>\n ADS<\/a>\u00a0 Garbe, J., Albrecht, T., Levermann, A., Donges, J. F. & Winkelmann, R. The hysteresis of the Antarctic Ice Sheet. Nature 585, 538\u2013544 (2020).<\/p>\n ADS<\/a>\u00a0 Rosier, S. H. R. et al. The tipping points and early warning indicators for Pine Island Glacier, West Antarctica. Cryosphere 15, 1501\u20131516 (2021).<\/p>\n ADS<\/a>\u00a0 Pattyn, F. & Morlighem, M. The uncertain future of the Antarctic Ice Sheet. Science 367, 1331\u20131335 (2020).<\/p>\n ADS<\/a>\u00a0 Schoof, C. Ice sheet grounding line dynamics: steady states, stability, and hysteresis. J. Geophys. Res. Earth Surf. https:\/\/doi.org\/10.1029\/2006JF000664<\/a> (2007).<\/p>\n Weertman, J. Stability of the junction of an ice sheet and an ice shelf. J. Glaciol. 13, 3\u201311 (1974).<\/p>\n ADS<\/a>\u00a0 Stokes, C. R. et al. Response of the East Antarctic Ice Sheet to past and future climate change. Nature 608, 275\u2013286 (2022). This paper reveals the potential vulnerability of the East Antarctic Ice Sheet to past and future climate change, highlighting its contribution to sea-level rise and underscoring the importance of understanding ice sheet dynamics in the context of climate tipping points.<\/p>\n ADS<\/a>\u00a0 Dutton, A. & Lambeck, K. Ice volume and sea level during the Last Interglacial. Science 337, 216\u2013219 (2012).<\/p>\n ADS<\/a>\u00a0 Dumitru, O. A. et al. Last interglacial global mean sea level from high-precision U-series ages of Bahamian fossil coral reefs. Quat. Sci. Rev. 318, 108287 (2023).<\/p>\n Lau, S. C. Y. et al. Genomic evidence for West Antarctic Ice Sheet collapse during the Last Interglacial. Science 382, 1384\u20131389 (2023). This study uses novel genetic indicators to infer that the West Antarctic Ice Sheet underwent major collapse during the last warm period in Earth\u2019s past when global temperatures were similar to present day.<\/p>\n ADS<\/a>\u00a0 Wolff, E. W. et al. The Ronne Ice Shelf survived the last interglacial. Nature 638, 133\u2013137 (2025).<\/p>\n CAS<\/a>\u00a0 Iizuka, M. et al. Multiple episodes of ice loss from the Wilkes Subglacial Basin during the Last Interglacial. Nat. Commun. 14, 2129 (2023).<\/p>\n ADS<\/a>\u00a0 Hutchinson, D. K., Menviel, L., Meissner, K. J. & Hogg, A. M. East Antarctic warming forced by ice loss during the Last Interglacial. Nat. Commun. 15, 1026 (2024).<\/p>\n ADS<\/a>\u00a0 DeConto, R. M. & Pollard, D. Contribution of Antarctica to past and future sea-level rise. Nature 531, 591\u2013597 (2016).<\/p>\n ADS<\/a>\u00a0 Otosaka, I. N. et al. Mass balance of the Greenland and Antarctic ice sheets from 1992 to 2020. Earth Syst. Sci. Data 15, 1597\u20131616 (2023).<\/p>\n ADS<\/a>\u00a0 Rignot, E. et al. Four decades of Antarctic Ice Sheet mass balance from 1979\u20132017. Proc. Natl Acad. Sci. USA 116, 1095\u20131103 (2019).<\/p>\n ADS<\/a>\u00a0 Shepherd, A. et al. Mass balance of the Antarctic Ice Sheet from 1992 to 2017. Nature 558, 219\u2013222 (2018).<\/p>\n ADS<\/a>\u00a0 Smith, B. et al. Pervasive ice sheet mass loss reflects competing ocean and atmosphere processes. Science 368, 1239\u20131242 (2020).<\/p>\n ADS<\/a>\u00a0 Gudmundsson, G. H., Paolo, F. S., Adusumilli, S. & Fricker, H. A. Instantaneous Antarctic ice sheet mass loss driven by thinning ice shelves. Geophys. Res. Lett. 46, 13903\u201313909 (2019).<\/p>\n ADS<\/a>\u00a0 Reese, R., Gudmundsson, G. H., Levermann, A. & Winkelmann, R. The far reach of ice-shelf thinning in Antarctica. Nat. Clim. Change 8, 53\u201357 (2018).<\/p>\n ADS<\/a>\u00a0 Konrad, H. et al. Net retreat of Antarctic glacier grounding lines. Nat. Geosci. 11, 258\u2013262 (2018).<\/p>\n ADS<\/a>\u00a0 Milillo, P. et al. Rapid glacier retreat rates observed in West Antarctica. Nat. Geosci. 15, 48\u201353 (2022).<\/p>\n ADS<\/a>\u00a0 Favier, L. et al. Retreat of Pine Island Glacier controlled by marine ice-sheet instability. Nat. Clim. Change 4, 117\u2013121 (2014).<\/p>\n ADS<\/a>\u00a0 Joughin, I., Smith, B. E. & Medley, B. Marine ice sheet collapse potentially underway for the Thwaites Glacier Basin, West Antarctica. Science 344, 735\u2013738 (2014).<\/p>\n ADS<\/a>\u00a0 Mouginot, J., Rignot, E. & Scheuchl, B. Sustained increase in ice discharge from the Amundsen Sea Embayment, West Antarctica, from 1973 to 2013. Geophys. Res. Lett. 41, 1576\u20131584 (2014).<\/p>\n ADS<\/a>\u00a0 Rignot, E., Mouginot, J., Morlighem, M., Seroussi, H. & Scheuchl, B. Widespread, rapid grounding line retreat of Pine Island, Thwaites, Smith and Kohler glaciers, West Antarctica from 1992 to 2011. Geophys. Res. Lett. 41, 3502\u20133509 (2014).<\/p>\n ADS<\/a>\u00a0 Ritz, C. et al. Potential sea-level rise from Antarctic ice-sheet instability constrained by observations. Nature 528, 115\u2013118 (2015).<\/p>\n ADS<\/a>\u00a0 Christie, F. D. W., Steig, E. J., Gourmelen, N., Tett, S. F. B. & Bingham, R. G. Inter-decadal climate variability induces differential ice response along Pacific-facing West Antarctica. Nat. Commun. 14, 93 (2023).<\/p>\n ADS<\/a>\u00a0 Hill, E. A. et al. The stability of present-day Antarctic grounding lines, part 1: No indication of marine ice sheet instability in the current geometry. Cryosphere 17, 3739\u20133759 (2023).<\/p>\n ADS<\/a>\u00a0 Reese, R. et al. The stability of present-day Antarctic grounding lines, part 2: Onset of irreversible retreat of Amundsen Sea glaciers under current climate on centennial timescales cannot be excluded. Cryosphere 17, 3761\u20133783 (2023). This paper investigates the committed evolution of Antarctic grounding lines under the present-day climate, finding irreversible retreat in the Amundsen Sea Embayment is initiated within centuries but is not yet inevitable.<\/p>\n ADS<\/a>\u00a0 Sun, S. et al. Antarctic ice sheet response to sudden and sustained ice-shelf collapse (ABUMIP). J. Glaciol. 66, 891\u2013904 (2020).<\/p>\n ADS<\/a>\u00a0 M\u00f6ller, T. et al. Achieving net zero greenhouse gas emissions critical to limit climate tipping risks. Nat. Commun. 15, 6192 (2024).<\/p>\n PubMed<\/a>\u00a0 Seroussi, H. et al. Evolution of the Antarctic Ice Sheet over the next three centuries from an ISMIP6 model ensemble. Earth Future 12, e2024EF004561 (2024). This contribution provides multi-century projections of the Antarctic Ice Sheet evolution using an ensemble of ice sheet models, revealing a sharp increase in mass loss and uncertainty from 2100 associated with anthropogenic climate change.<\/p>\n Scambos, T. A., Hulbe, C., Fahnestock, M. & Bohlander, J. The link between climate warming and break-up of ice shelves in the Antarctic Peninsula. J. Glaciol. 46, 516\u2013530 (2000).<\/p>\n ADS<\/a>\u00a0 Lai, C.-Y. et al. Vulnerability of Antarctica\u2019s ice shelves to meltwater-driven fracture. Nature 584, 574\u2013578 (2020).<\/p>\n ADS<\/a>\u00a0 Cook, A. J. & Vaughan, D. G. Overview of areal changes of the ice shelves on the Antarctic Peninsula over the past 50 years. Cryosphere 4, 77\u201398 (2010).<\/p>\n ADS<\/a>\u00a0 De Angelis, H. & Skvarca, P. Glacier surge after ice shelf collapse. Science 299, 1560\u20131562 (2003).<\/p>\n ADS<\/a>\u00a0 Wuite, J. et al. Evolution of surface velocities and ice discharge of Larsen B outlet glaciers from 1995 to 2013. Cryosphere 9, 957\u2013969 (2015).<\/p>\n ADS<\/a>\u00a0 Rott, H. et al. Changing pattern of ice flow and mass balance for glaciers discharging into the Larsen A and B embayments, Antarctic Peninsula, 2011 to 2016. Cryosphere 12, 1273\u20131291 (2018).<\/p>\n ADS<\/a>\u00a0 Trusel, L. D. et al. Divergent trajectories of Antarctic surface melt under two twenty-first-century climate scenarios. Nat. Geosci. 8, 927\u2013932 (2015).<\/p>\n ADS<\/a>\u00a0 Gilbert, E. & Kittel, C. Surface melt and runoff on Antarctic ice shelves at 1.5\u2009\u00b0C, 2\u2009\u00b0C, and 4\u2009\u00b0C of future warming. Geophys. Res. Lett. 48, e2020GL091733 (2021).<\/p>\n ADS<\/a>\u00a0 Dell, R. L., Willis, I. C., Arnold, N. S., Banwell, A. F. & de Roda Husman, S. Substantial contribution of slush to meltwater area across Antarctic ice shelves. Nat. Geosci. 17, 624\u2013630 (2024).<\/p>\n CAS<\/a>\u00a0 Walker, C. C. et al. Multi-decadal collapse of East Antarctica\u2019s Conger\u2013Glenzer Ice Shelf. Nat. Geosci. 17, 1240\u20131248 (2024).<\/p>\n CAS<\/a>\u00a0 Wille, J. D. et al. The extraordinary March 2022 East Antarctica \u201cheat\u201d wave. Part II: Impacts on the Antarctic Ice Sheet. J. Clim. 37, 779\u2013799 (2024).<\/p>\n ADS<\/a>\u00a0 Hill, E. A., Gudmundsson, G. H. & Chandler, D. M. Ocean warming as a trigger for irreversible retreat of the Antarctic ice sheet. Nat. Clim. Change 14, 1165\u20131171 (2024).<\/p>\n Ben-Yami, M., Skiba, V., Bathiany, S. & Boers, N. Uncertainties in critical slowing down indicators of observation-based fingerprints of the Atlantic Overturning Circulation. Nat. Commun. 14, 8344 (2023).<\/p>\n ADS<\/a>\u00a0 Smith, R. S. et al. Coupling the U.K. Earth System Model to dynamic models of the Greenland and Antarctic Ice Sheets. J. Adv. Model. Earth Syst. 13, e2021MS002520 (2021).<\/p>\n
\n CAS<\/a>\u00a0
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