Characteristics of surface “melt potential” over Antarctic ice shelves based on regional atmospheric model simulations of summer air temperature extremes from 1979/80 to 2018/19

We calculate a regional surface “melt potential” index (MPI) over Antarctic ice shelves that describes the frequency (MPI-freq, %) and intensity (MPI-int, K) of daily maximum summer temperatures exceeding a melt threshold of 273.15 K. This is used to determine which ice shelves are vulnerable to melt-induced hydrofracture and is calculated using near-surface temperature output for each summer from 1979/80 to 2018/19 from two high-resolution regional atmospheric model hindcasts (using the MetUM and HIRHAM5). MPI is highest for Antarctic Peninsula ice shelves (MPI-freq 23-35%, MPI-int 1.2-2.1 K), lowest (2-3%, < 0 K) for Ronne-Filchner and Ross ice shelves, and around 10-24% and 0.6-1.7 K for the other West and East Antarctic ice shelves. Hotspots of MPI are apparent over many ice shelves, and they also show a decreasing trend in MPI-freq. The regional circulation patterns associated with high MPI values over West and East Antarctic ice shelves are remarkably consistent for their respective region but tied to different large-scale climate forcings. The West Antarctic circulation resembles the central Pacific El Niño pattern with a stationary Rossby wave and a strong anticyclone over the high-latitude South Pacific. By contrast, the East Antarctic circulation comprises a zonally symmetric negative Southern Annular Mode pattern with a strong regional anticyclone on the plateau and enhanced coastal easterlies/weakened Southern Ocean westerlies. Values of MPI are 3-4 times larger for a lower temperature/melt threshold of 271.15 K used in a sensitivity test, as melting can occur at temperatures lower than 273.15 K depending on snowpack properties.

[1]  A. Orr,et al.  Variability in Antarctic surface climatology across regional climate models and reanalysis datasets , 2022, The Cryosphere.

[2]  J. Turner,et al.  Central tropical Pacific convection drives extreme high temperatures and surface melt on the Larsen C Ice Shelf, Antarctic Peninsula , 2022, Nature Communications.

[3]  X. Fettweis,et al.  Intense atmospheric rivers can weaken ice shelf stability at the Antarctic Peninsula , 2022, Communications Earth & Environment.

[4]  J. King,et al.  A 20‐Year Study of Melt Processes Over Larsen C Ice Shelf Using a High‐Resolution Regional Atmospheric Model: 2. Drivers of Surface Melting , 2022, Journal of Geophysical Research: Atmospheres.

[5]  R. Cordero,et al.  Warming events projected to become more frequent and last longer across Antarctica , 2021, Scientific Reports.

[6]  D. McGrath,et al.  Comparison of kilometre and sub‐kilometre scale simulations of a foehn wind event over the Larsen C Ice Shelf, Antarctic Peninsula using the Met Office Unified Model (MetUM) , 2021, Quarterly Journal of the Royal Meteorological Society.

[7]  D. Holland,et al.  Atmospheric Rivers, Warm Air Intrusions, and Surface Radiation Balance in the Amundsen Sea Embayment , 2021, Journal of Geophysical Research: Atmospheres.

[8]  D. Bromwich,et al.  Major surface melting over the Ross Ice Shelf part I: Foehn effect , 2021, Quarterly Journal of the Royal Meteorological Society.

[9]  R. Alley,et al.  The Paris Climate Agreement and future sea-level rise from Antarctica , 2021, Nature.

[10]  C. Kittel,et al.  Surface Melt and Runoff on Antarctic Ice Shelves at 1.5°C, 2°C, and 4°C of Future Warming , 2021, Geophysical Research Letters.

[11]  J. Turner,et al.  Extreme Temperatures in the Antarctic , 2021, Journal of Climate.

[12]  Francis Codron,et al.  Antarctic Atmospheric River Climatology and Precipitation Impacts , 2021, Journal of Geophysical Research: Atmospheres.

[13]  C. Shuman,et al.  The 32-year record-high surface melt in 2019/2020 on the northern George VI Ice Shelf, Antarctic Peninsula , 2021 .

[14]  C. Zender,et al.  Climatology and Evolution of the Antarctic Peninsula Föhn Wind‐Induced Melt Regime From 1979–2018 , 2021, Journal of Geophysical Research: Atmospheres.

[15]  D. Bromwich,et al.  Temperature and precipitation projections for the Antarctic Peninsula over the next two decades: contrasting global and regional climate model simulations , 2021, Climate Dynamics.

[16]  M. R. van den Broeke,et al.  Spatial Variability of the Snowmelt‐Albedo Feedback in Antarctica , 2021, Journal of Geophysical Research: Earth Surface.

[17]  Thomas M. Smith,et al.  Improvements of the Daily Optimum Interpolation Sea Surface Temperature (DOISST) Version 2.1 , 2020, Journal of Climate.

[18]  P. Gentine,et al.  Vulnerability of Antarctica’s ice shelves to meltwater-driven fracture , 2020, Nature.

[19]  J. Turner,et al.  Record warming at the South Pole during the past three decades , 2020, Nature Climate Change.

[20]  J. Thepaut,et al.  The ERA5 global reanalysis , 2020, Quarterly Journal of the Royal Meteorological Society.

[21]  J. F. Arthur,et al.  Recent understanding of Antarctic supraglacial lakes using satellite remote sensing , 2020, Progress in Physical Geography: Earth and Environment.

[22]  J. King,et al.  Summertime cloud phase strongly influences surface melting on the Larsen C ice shelf, Antarctica , 2020, Quarterly Journal of the Royal Meteorological Society.

[23]  A. Orr,et al.  Lateral meltwater transfer across an Antarctic ice shelf , 2020, The Cryosphere.

[24]  S. Krakovska,et al.  Climate projections over the Antarctic Peninsula region to the end of the 21st century. Part 1: cold temperature indices , 2019, Ukrainian Antarctic Journal.

[25]  J. Turner,et al.  West Antarctic surface melt triggered by atmospheric rivers , 2019, Nature Geoscience.

[26]  Ting Wei,et al.  Distribution and temporal trends of temperature extremes over Antarctica , 2019, Environmental Research Letters.

[27]  A. Maycock,et al.  On the Seasonality of the El Niño Teleconnection to the Amundsen Sea Region , 2019, Journal of Climate.

[28]  Sascha Willmes,et al.  A Satellite-Based Climatology of Wind-Induced Surface Temperature Anomalies for the Antarctic , 2019, Remote. Sens..

[29]  X. Fettweis,et al.  The Effect of Foehn‐Induced Surface Melt on Firn Evolution Over the Northeast Antarctic Peninsula , 2019, Geophysical Research Letters.

[30]  D. Macayeal,et al.  Direct measurements of ice-shelf flexure caused by surface meltwater ponding and drainage , 2019, Nature Communications.

[31]  Eric Rignot,et al.  Four decades of Antarctic Ice Sheet mass balance from 1979–2017 , 2019, Proceedings of the National Academy of Sciences.

[32]  D. Bromwich,et al.  Meteorological Drivers and Large-Scale Climate Forcing of West Antarctic Surface Melt , 2019, Journal of Climate.

[33]  A. Luckman,et al.  Intense Winter Surface Melt on an Antarctic Ice Shelf , 2018 .

[34]  A. Orr,et al.  The Springtime Influence of Natural Tropical Pacific Variability on the Surface Climate of the Ross Ice Shelf, West Antarctica: Implications for Ice Shelf Thinning , 2018, Scientific Reports.

[35]  D. Bromwich,et al.  Summer Drivers of Atmospheric Variability Affecting Ice Shelf Thinning in the Amundsen Sea Embayment, West Antarctica , 2018 .

[36]  R. Garreaud,et al.  Foehn Event Triggered by an Atmospheric River Underlies Record‐Setting Temperature Along Continental Antarctica , 2018 .

[37]  W. J. van de Berg,et al.  Climate and surface mass balance of coastal West Antarctica resolved by regional climate modelling , 2017, Annals of Glaciology.

[38]  J. Shukla,et al.  Reforecasting the ENSO Events in the Past 57 Years (1958-2014) , 2017 .

[39]  Dan Lubin,et al.  January 2016 extensive summer melt in West Antarctica favoured by strong El Niño , 2017, Nature Communications.

[40]  Robin E. Bell,et al.  Widespread movement of meltwater onto and across Antarctic ice shelves , 2017, Nature.

[41]  P. Brown,et al.  The Role of Precipitation in Controlling the Transition from Stratocumulus to Cumulus Clouds in a Northern Hemisphere Cold-Air Outbreak , 2017 .

[42]  S. Jacobs,et al.  Decadal ocean forcing and Antarctic ice sheet response: Lessons from the Amundsen Sea , 2016 .

[43]  A. Timmermann,et al.  Tropical Pacific SST Drivers of Recent Antarctic Sea Ice Trends , 2016 .

[44]  Michel Rixen,et al.  WCRP COordinated Regional Downscaling EXperiment (CORDEX): A diagnostic MIP for CMIP6 , 2016 .

[45]  John Turner,et al.  Absence of 21st century warming on Antarctic Peninsula consistent with natural variability , 2016, Nature.

[46]  J. Turner,et al.  An assessment of the Polar Weather Research and Forecasting (WRF) model representation of near‐surface meteorological variables over West Antarctica , 2016 .

[47]  J. Cassano,et al.  The surface climatology of the Ross Ice Shelf Antarctica , 2016, International journal of climatology : a journal of the Royal Meteorological Society.

[48]  Karen E. Frey,et al.  Divergent trajectories of Antarctic surface melt under two twenty-first-century climate scenarios , 2015 .

[49]  D. Macayeal,et al.  Ice-shelf fracture due to viscoelastic flexure stress induced by fill/drain cycles of supraglacial lakes , 2015, Antarctic Science.

[50]  Fernando S. Paolo,et al.  Volume loss from Antarctic ice shelves is accelerating , 2015, Science.

[51]  A. Gadian,et al.  Validation of the summertime surface energy budget of Larsen C Ice Shelf (Antarctica) as represented in three high‐resolution atmospheric models , 2015 .

[52]  N. Barrand,et al.  Surface melt and ponding on Larsen C Ice Shelf and the impact of föhn winds , 2014, Antarctic Science.

[53]  John Turner,et al.  Met Office Unified Model high‐resolution simulations of a strong wind event in Antarctica , 2014 .

[54]  Ben Jolly,et al.  Synoptic climatology of the Ross Ice Shelf and Ross Sea region of Antarctica: k‐means clustering and validation , 2014 .

[55]  A. Timmermann,et al.  Increasing frequency of extreme El Niño events due to greenhouse warming , 2014 .

[56]  E. Meijgaard,et al.  Updated cloud physics in a regional atmospheric climate model improves the modelled surface energy balance of Antarctica , 2014 .

[57]  Karen E. Frey,et al.  Satellite‐based estimates of Antarctic surface meltwater fluxes , 2013 .

[58]  R. Clark,et al.  Simulation and Projection of the Southern Hemisphere Annular Mode in CMIP5 Models , 2013 .

[59]  D. Macayeal,et al.  Breakup of the Larsen B Ice Shelf triggered by chain reaction drainage of supraglacial lakes , 2013 .

[60]  E. Guilyardi,et al.  Late-twentieth-century emergence of the El Niño propagation asymmetry and future projections , 2013, Nature.

[61]  Nerilie J. Abram,et al.  Acceleration of snow melt in an Antarctic Peninsula ice core during the twentieth century , 2013 .

[62]  N. Barrand,et al.  Trends in Antarctic Peninsula surface melting conditions from observations and regional climate modeling , 2012 .

[63]  Matthew A. Lazzara,et al.  Antarctic Automatic Weather Station Program: 30 Years of Polar Observation , 2012 .

[64]  K. Frey,et al.  Antarctic surface melting dynamics: Enhanced perspectives from radar scatterometer data , 2012 .

[65]  J. Cassano,et al.  A description of the Ross Ice Shelf air stream (RAS) through the use of self-organizing maps (SOMs) , 2012 .

[66]  D. Vaughan,et al.  Antarctic ice-sheet loss driven by basal melting of ice shelves , 2012, Nature.

[67]  R. Fogt,et al.  Seasonal Zonal Asymmetries in the Southern Annular Mode and Their Impact on Regional Temperature Anomalies , 2012 .

[68]  D. Bromwich,et al.  Evaluation of Polar WRF forecasts on the Arctic System Reanalysis Domain: 2. Atmospheric hydrologic cycle , 2012 .

[69]  C. Genthon,et al.  Atmospheric Temperature Measurement Biases on the Antarctic Plateau , 2011 .

[70]  N. Glasser,et al.  From ice-shelf tributary to tidewater glacier: continued rapid recession, acceleration and thinning of Röhss Glacier following the 1995 collapse of the Prince Gustav Ice Shelf, Antarctic Peninsula , 2011, Journal of Glaciology.

[71]  J. King,et al.  Near-surface climate and surface energy budget of Larsen C ice shelf, Antarctic Peninsula , 2011 .

[72]  P. Cox,et al.  The Joint UK Land Environment Simulator (JULES), model description – Part 1: Energy and water fluxes , 2011 .

[73]  M. R. van den Broeke,et al.  Temperature thresholds for degree‐day modelling of Greenland ice sheet melt rates , 2010 .

[74]  Stephen D. McPhail,et al.  Observations beneath Pine Island Glacier in West Antarctica and implications for its retreat , 2010 .

[75]  D. Bromwich,et al.  Foehn Winds in the McMurdo Dry Valleys, Antarctica: The Origin of Extreme Warming Events* , 2010 .

[76]  M. Tedesco Assessment and development of snowmelt retrieval algorithms over Antarctica from K-band spaceborne brightness temperature (1979-2008) , 2009 .

[77]  T. Scambos,et al.  Ice shelf disintegration by plate bending and hydro-fracture: Satellite observations and model results of the 2008 Wilkins ice shelf break-ups , 2009 .

[78]  J. Cassano,et al.  An Analysis of Low-Level Jets in the Greater Ross Ice Shelf Region Based on Numerical Simulations , 2008 .

[79]  Zong-Liang Yang,et al.  Assessment of three dynamical climate downscaling methods using the Weather Research and Forecasting (WRF) model , 2008 .

[80]  Swadhin K. Behera,et al.  El Niño Modoki and its possible teleconnection , 2007 .

[81]  M. Fily,et al.  Surface melting derived from microwave radiometers: a climatic indicator in Antarctica , 2007, Annals of Glaciology.

[82]  H. J. Zwally,et al.  Persistent surface snowmelt over Antarctica (1987–2006) from 19.35 GHz brightness temperatures , 2007 .

[83]  J. Cassano,et al.  Characteristics of the Ross Ice Shelf air stream as depicted in Antarctic Mesoscale Prediction System simulations , 2006 .

[84]  M. L’Heureux,et al.  Observed relationships between the El Niño-southern oscillation and the extratropical zonal-mean circulation , 2006 .

[85]  Regine Hock,et al.  Glacier melt: a review of processes and their modelling , 2005 .

[86]  Jan-Gunnar Winther,et al.  Antarctic Surface and Subsurface Snow and Ice Melt Fluxes , 2005 .

[87]  J. Hunt,et al.  A ‘low‐level’ explanation for the recent large warming trend over the western Antarctic Peninsula involving blocked winds and changes in zonal circulation , 2004 .

[88]  G. Marshall Trends in the Southern Annular Mode from Observations and Reanalyses , 2003 .

[89]  John R. Lanzante,et al.  The Atmospheric Bridge: The Influence of ENSO Teleconnections on Air-Sea Interaction over the Global Oceans , 2002 .

[90]  Atsumu Ohmura,et al.  Physical Basis for the Temperature-Based Melt-Index Method , 2001 .

[91]  H. Nakamura,et al.  A Formulation of a Phase-Independent Wave-Activity Flux for Stationary and Migratory Quasigeostrophic Eddies on a Zonally Varying Basic Flow , 2001 .

[92]  K. Keay,et al.  Mean Southern Hemisphere Extratropical Cyclone Behavior in the 40-Year NCEP–NCAR Reanalysis , 2000 .

[93]  K. Keay,et al.  Variability of Southern Hemisphere extratropical cyclone behavior, 1958-97 , 2000 .

[94]  C. Genthon,et al.  Altitude dependence of the ice sheet surface climate , 1999 .

[95]  H. Rott,et al.  Breakup and conditions for stability of the northern Larsen Ice Shelf, Antarctica , 1998, Nature.

[96]  H. Rott,et al.  Rapid Collapse of Northern Larsen Ice Shelf, Antarctica , 1996, Science.

[97]  D. Bromwich,et al.  Satellite Observations of Katabatic-Wind Propagation for Great Distances across the Ross Ice Shelf , 1992 .

[98]  D. Bromwich,et al.  Continental-Scale Simulation of the Antarctic Katabatic Wind Regime , 1991 .

[99]  David J. Karoly,et al.  Southern Hemisphere Circulation Features Associated with El Niño-Southern Oscillation Events , 1989 .

[100]  David H. Bromwich,et al.  Instrumented Aircraft Observations of the Katabatic Wind Regime Near Terra Nova Bay , 1989 .

[101]  Xavier Fettweis,et al.  What is the Surface Mass Balance of Antarctica? An Intercomparison of Regional Climate Model Estimates , 2020 .

[102]  Frank Pattyn,et al.  Meltwater produced by wind-albedo interaction stored in an East Antarctic ice shelf , 2017 .

[103]  A. Elvidge,et al.  Foehn warming distributions in nonlinear and linear flow regimes: a focus on the Antarctic Peninsula , 2016 .

[104]  J. Turner,et al.  The Influence of the Amundsen–Bellingshausen Seas Low on the Climate of West Antarctica and Its Representation in Coupled Climate Model Simulations , 2013 .

[105]  D. Bromwich,et al.  Climate of West Antarctica and Influence of Marine Air Intrusions , 2011 .

[106]  Mikel L. Forcada,et al.  ATLAS , 2011, EAMT.

[107]  J. Christensen,et al.  The HIRHAM Regional Climate Model. Version 5 (beta) , 2007 .

[108]  HOWARD M. ETLINGER,et al.  J O U R N A L , 2006 .

[109]  T. Scambos,et al.  The link between climate warming and break-up of ice shelves in the Antarctic Peninsula , 2000, Journal of Glaciology.

[110]  B. Liebmann,et al.  Description of a complete (interpolated) outgoing longwave radiation dataset , 1996 .