Future projections for the Antarctic ice sheet until the year 2300 with a climate-index method

Published online by Cambridge University Press: 11 July 2023

Wing-Le Chan and

Ralf Greve*: Affiliation:
Institute of Low Temperature Science, Hokkaido University, Sapporo, Japan Arctic Research Center, Hokkaido University, Sapporo, Japan
Christopher Chambers: Affiliation:
Institute of Low Temperature Science, Hokkaido University, Sapporo, Japan
Takashi Obase: Affiliation:
Atmosphere and Ocean Research Institute, University of Tokyo, Kashiwa, Japan
Fuyuki Saito: Affiliation:
Japan Agency for Marine-Earth Science and Technology, Yokohama, Japan
Wing-Le Chan: Affiliation:
Atmosphere and Ocean Research Institute, University of Tokyo, Kashiwa, Japan Japan Agency for Marine-Earth Science and Technology, Yokohama, Japan
Ayako Abe-Ouchi: Affiliation:
Atmosphere and Ocean Research Institute, University of Tokyo, Kashiwa, Japan
*: Corresponding author: Ralf Greve; Email: [email protected]

Article contents

Abstract
Introduction
Climate forcing
Model experiments
Results
Discussion and conclusion
Code and data availability
Authors’ contributions
Financial support
References

Rights & Permissions

Abstract

As part of the Coupled Model Intercomparison Project Phase 6 (CMIP6), the Ice Sheet Model Intercomparison Project for CMIP6 (ISMIP6) was devised to assess the likely sea-level-rise contribution from the Earth's ice sheets. Here, we construct an ensemble of climate forcings for Antarctica until the year 2300 based on original ISMIP6 forcings until 2100, combined with climate indices from simulations with the MIROC4m climate model until 2300. We then use these forcings to run simulations for the Antarctic ice sheet with the SICOPOLIS model. For the unabated warming pathway RCP8.5/SSP5-8.5, the ice sheet suffers a severe mass loss, amounting to ~ 1.5 m SLE (sea-level equivalent) for the fourteen-experiment mean, and ~ 3.3 m SLE for the most sensitive experiment. Most of this loss originates from West Antarctica. For the reduced emissions pathway RCP2.6/SSP1-2.6, the loss is limited to a three-experiment mean of ~ 0.16 m SLE. The means are approximately two times larger than what was found in a previous study (Chambers and others, 2022, doi:10.1017/jog.2021.124) that assumed a sustained late-21st-century climate beyond 2100, demonstrating the importance of post-2100 climate trends on Antarctic mass changes in the 22nd and 23rd centuries.

Keywords

Antarctic glaciology climate change ice and climate ice-sheet modelling

Type: Article
Information: Journal of Glaciology , First View , pp. 1 - 11

DOI: https://doi.org/10.1017/jog.2023.41 [Opens in a new window]
Creative Commons: This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright: Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of The International Glaciological Society

1. Introduction

The ice sheets of Antarctica and Greenland are the largest potential contributors to future sea-level rise caused by global warming because of their enormous volumes. These amount to 57.9 ± 0.9 m SLE (sea-level equivalent) for the Antarctic ice sheet (AIS) (Morlighem and others, Reference Morlighem2020) and 7.42 ± 0.05 m SLE for the Greenland ice sheet (GrIS) (Morlighem and others, Reference Morlighem2017). Observations revealed that both ice sheets have been losing substantial amounts of mass since the 1990s. For the period 2012–2017, The IMBIE Team (2018) reported a mass loss of 219 ± 43 Gt a^-1 for the AIS, most of which originates from the West Antarctic ice sheet (WAIS), and The IMBIE Team (2020) reported a loss of 244 ± 28 Gt a^-1 for the GrIS (IMBIE: Ice sheet Mass Balance Inter-comparison Exercise). Therefore, the recent absolute losses are of similar size (likely somewhat larger for the GrIS), whereas the relative loss (compared to the total mass) is approximately 10 times smaller for the AIS compared to the GrIS. For both ice sheets, changes in the surface mass balance (SMB) as well as dynamic changes contribute to the mass loss.

A particular threat for the WAIS is that it may undergo a rapid, catastrophic disintegration through a process known as marine-ice-sheet instability (MISI) (e.g., Weertman, Reference Weertman1974; Mercer, Reference Mercer1978; Thomas and Bentley, Reference Thomas and Bentley1978; Schoof, Reference Schoof2007). In contrast to the East Antarctic ice sheet (EAIS), large parts of the WAIS are grounded on a bed which is below sea level and sloping downward inland. Therefore, an initial retreat of the grounding line causes the ice sheet to be thicker at its new location, which may increase discharge and thus mass loss, so that the grounding line retreats even further in a runaway fashion. There is paleoclimatic evidence that the WAIS collapsed during past warm periods (Pollard and DeConto, Reference Pollard and DeConto2009; Alley and others, Reference Alley2015; Dutton and others, Reference Dutton2015; Gasson and others, Reference Gasson, DeConto, Pollard and Levy2016; Turney and others, Reference Turney2020). Recent observations suggest that a new instability may already be in its initial phase (e.g., Joughin and others, Reference Joughin, Smith and Medley2014; Rignot and others, Reference Rignot, Mouginot, Morlighem, Seroussi and Scheuchl2014; The IMBIE Team, 2018).

To estimate the future contribution of the AIS and GrIS to sea-level rise until the end of the 21st century, the Ice Sheet Model Intercomparison Project for CMIP6 (ISMIP6) was devised (Nowicki and others, Reference Nowicki2016, Reference Nowicki2020). It is part of the Coupled Model Intercomparison Project Phase 6 (CMIP6), a major international climate modelling initiative (Eyring and others, Reference Eyring2016) with the main goal to provide input for the recently published Sixth Assessment Report (AR6) of the Intergovernmental Panel on Climate Change (IPCC) (IPCC, 2021). For the AIS, when forced by output from CMIP5 global climate models (GCMs), a mass loss in the range of −7.8 to 30.0 cm SLE was found under the unabated warming pathway RCP8.5 [RCP: Representative Concentration Pathway] (Seroussi and others, Reference Seroussi2020). The limited number of results for the reduced emissions pathway RCP2.6 fall within this range, and so do the results obtained with CMIP6 climate forcings (Payne and others, Reference Payne2021). This rather unclear picture for the AIS is a consequence of the counteracting effects of mass loss due to ocean warming and mass gain from increased snowfall. The main findings for the GrIS, when forced by output from CMIP5 GCMs, were contributions of 90 ± 50 and 32 ± 17 mm SLE for RCP8.5 and RCP2.6, respectively (Goelzer and others, Reference Goelzer2020). The CMIP6 GCMs tend to feature a warmer atmosphere, which results in higher mass loss due to increased surface melt (Payne and others, Reference Payne2021).

The full suite of ISMIP6 experiments with both CMIP5 and CMIP6 forcings was carried out with the ice-sheet model SICOPOLIS (‘SImulation COde for POLythermal Ice Sheets’, www.sicopolis.net), as documented in detail by Greve and others (Reference Greve2020a, Reference Greve, Chambers and Calov2020b). Chambers and others (Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022) extended the ISMIP6 simulations for the AIS with SICOPOLIS until the year 3000, assuming a sustained late-21st-century climate beyond 2100 (atmospheric forcing randomly sampled from the 10-year interval 2091–2100, oceanic forcing kept fixed at 2100 values). Compared to the uncertain response projected by the ISMIP6 ensemble over the 2015–2100 period, a radically different picture emerges, demonstrating that the long-term consequences of the high-emissions scenario RCP8.5/SSP5-8.5 [SSP: Shared Socioeconomic Pathway] are much greater than the 100-year response even if no further climate trend is applied beyond 2100. A similar study for the GrIS was conducted by Greve and Chambers (Reference Greve and Chambers2022).

Other studies on the response of the AIS to longer-term climate change have also been conducted. Schaeffer and others (Reference Schaeffer, Hare, Rahmstorf and Vermeer2012) and Levermann and others (Reference Levermann2013) used statistical relationships between past temperatures and global sea levels to predict future sea-level change from all sources, including the ice sheets. Golledge and others (Reference Golledge2015) used the Parallel Ice-Sheet Model (PISM) to demonstrate that atmospheric warming in excess of 1.5 to 2$^\circ$C above present, triggers ice-shelf collapse and a centennial to millennial-scale response by the AIS. They simulated a contribution to sea-level rise from Antarctica under higher emission scenarios of 0.6 to 3 m by the year 2300. Similarly, Garbe and others (Reference Garbe, Albrecht, Levermann, Donges and Winkelmann2020) found that at greater than 2$^\circ$C of global average warming, the WAIS is committed to long-term partial collapse. They also found distinct regimes in the rates of sea-level rise per degree, with a doubling in the rate if warming becomes greater than 2$^\circ$C. Bulthuis and others (Reference Bulthuis, Arnst, Sun and Pattyn2019) carried out AIS projections until 3000 based on spatially uniform temperature-anomaly time-series and a combination of simulations with the fast Elementary Thermomechanical Ice Sheet (f.ETISh) model, an emulator, probabilistic methods and uncertainty quantification. They found that, irrespective of parametric uncertainty, the WAIS remains stable under RCP2.6, while RCP8.5 triggers its collapse under almost all investigated cases. In the ISMIP6-endorsed Antarctic BUttressing Model Intercomparison Project (ABUMIP; Sun and others, Reference Sun2020), the response of the AIS to sudden and sustained loss of ice shelves was simulated by an ensemble of 15 ice-sheet models. It was found that this leads to a multi-metre (1–12 m) contribution to sea-level rise over the 500-year-long simulations. Lowry and others (Reference Lowry, Krapp, Golledge and Alevropoulos-Borrill2021) used statistical emulation based on simulations with PISM to investigate the evolution of the AIS until 2300 under RCP8.5 and RCP2.6, assuming no further climate change beyond 2100 (similar to Chambers and others, Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022). The contribution to sea-level rise was found to be indistinguishable between the two pathways in the 21st century, while multi-metre differences occur in subsequent centuries. DeConto and others (Reference DeConto2021) used their observationally calibrated ice-sheet–shelf model for simulations until 2100 and extended until 2300, employing extended RCP scenarios (Meinshausen and others, Reference Meinshausen2011). Their results demonstrate the possibility that rapid and unstoppable sea-level rise from the AIS will be triggered if Paris Agreement targets (limiting global mean warming in the 21st century to less than $2^\circ {\rm C}$ above pre-industrial levels) are exceeded. Lipscomb and others (Reference Lipscomb2021) used the Community Ice Sheet Model (CISM) to investigate the response of the AIS to ISMIP6 ocean thermal forcings only, extended to 2500. They found long-term retreat of the WAIS and showed that the Amundsen sector exhibits threshold behaviour with modest retreat or complete collapse, depending on parameter settings in the melt scheme, ocean forcing, and basal friction law. Complete collapse of the WAIS occurred under some combinations of low basal friction and high thermal forcing anomalies. Van Breedam and others (Reference Van Breedam, Goelzer and Huybrechts2020) projected the response of the AIS and GrIS 10 000 years into the future with the Earth system model of intermediate complexity LOVECLIMv1.3 (LOVECLIM: LOch–Vecode–Ecbilt–CLio–agIsm Model), including the ice-sheet model AGISM (Antarctic and Greenland Ice Sheet Model), forced by the extended concentration pathways ECP2.6, 4.5, 6.0 and 8.5 until 2300 and zero emissions thereafter. For the AIS, they report mass losses ranging from about 1.6 m SLE for the lowest forcing scenario until up to 27 m SLE for the higher-forcing scenarios.

In the present study, we follow an approach similar to Chambers and others (Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022), extending the ISMIP6-Antarctica simulations further into the future. However, we drop the assumption of a sustained climate with no warming or cooling trend beyond 2100. Instead, to account for greenhouse-gas emissions pathways and climate inertia after the 21st century, we construct extensions of all ISMIP6-Antarctica climate forcings until 2300 by a climate-index method explained in Sect. 2. The set-up of SICOPOLIS and the 18 model experiments (1 control, 14 RCP8.5/SSP5-8.5, 3 RCP2.6/SSP1-2.6) are explained in Sect. 3. The results are described in Sect. 4, and a discussion and conclusion is provided in Sect. 5.

2. Climate forcing

We construct an ensemble of climate forcings for Antarctica for the period 2015–2300 by combining results from MIROC4m (MIROC: Model for Interdisciplinary Research On Climate) RCP8.5 and RCP4.5 simulations for 1995–2300 (partially published in Bakker and others, Reference Bakker2016) with the ensemble of ISMIP6 forcings for 2015–2100 (Nowicki and others, Reference Nowicki2020; Seroussi and others, Reference Seroussi2020; Payne and others, Reference Payne2021). To do so, we derive a set of atmospheric and oceanic climate indices from the MIROC4m simulations such that 1995–2014 averages of the considered fields are mapped to zero and 2091–2100 averages to unity (Sect. 2.1). We then use the climate indices to extrapolate the ensemble of ISMIP6 forcings to the period 2101–2300 (Sect. 2.2). Together with the original ISMIP6 forcings, this method provides smooth climate forcings for the entire period 2015–2300. Beyond the needs of this study, the method is applicable in general to extend climate forcings of limited duration further into the future.

2.1. Climate indices

We define five atmospheric and one oceanic climate indices. For the atmosphere, the considered fields are the mean-annual surface temperature (ST), summer (December–January–February, DJF) surface temperature (ST_DJF), precipitation (prec), evaporation (evap) and surface runoff (roff). ST and SMB = prec − evap − roff define the atmospheric forcing, while ST_DJF is required for the parameterization of ice-shelf collapse (see the last part of Sect. 2.2).

All fields are spatially averaged over the AIS land grid (excluding the ice shelves because they are not contained in the MIROC4m set-up), and then mapped linearly on a dimensionless scale such that

(1)$$\matrix{c_{\rm xx}( \hbox{1995-2014 average}) & = \,0,\; \cr c_{\rm xx}( \hbox{2091-2100 average}) & = \,1,\; }$$

where xx ∈ {ST, ST_DJF, prec, evap, roff}. This yields the five atmospheric climate indices c _ST, $c_{\rm ST\_DJF}$, c _prec, c _evap and c _roff.

For the ocean, we use the average temperature south of $62.5^\circ {\rm S}$ and between 200 and 800 metres depth. This domain encompasses the Southern Ocean surrounding the ice-shelf cavities and a range of typical ice-shelf drafts where basal melting takes place. Non-dimensionalization with the same pinning points as defined by Eqn. (1) (xx = oc) provides the oceanic climate index c _oc.

Since the MIROC4m results are available for RCP8.5 and RCP4.5, the above method provides climate indices for these two pathways. However, ISMIP6 covers RCP8.5 and RCP2.6, so that we also require the climate indices for RCP2.6. To obtain these, we extrapolate the atmospheric and oceanic indices for RCP8.5 and RCP4.5, assuming linear relations between the indices and the radiative forcing of the RCP scenarios:

(2)$$c_{\rm xx}^{{\rm RCP2.6}} = c_{\rm xx}^{{\rm RCP4.5}} - {4.5-2.6\over 8.5-4.5} \times ( c_{\rm xx}^{\rm RCP8.5}-c_{\rm xx}^{\rm RCP4.5}) .$$

The resulting climate indices are shown in Fig. 1. For RCP8.5, the change of all six variables during the 22nd and 23rd century goes well beyond late-21st-century levels. The five atmospheric indices evolve into a certain saturation towards the end of the period, whereas the oceanic index increases steadily. This is due to the larger inertia of the ocean compared to the atmosphere. For RCP2.6, the atmospheric indices largely fall below their late-21st-century levels, indicating a partial recovery of the climate change. By contrast, the oceanic index does not show such a recovery and keeps on increasing (albeit at a decreasing rate), which again results from the larger oceanic inertia.

Figure 1. RCP8.5 and RCP2.6 climate indices for the mean-annual surface temperature (c _ST), DJF surface temperature ($c_{\rm ST\_DJF}$), precipitation (c _prec), evaporation (c _evap), surface runoff (c _roff) and ocean temperature (c _oc), derived from MIROC4m simulations until the year 2300. Note that the scaling defined by Eqn. (1) implies that any non-zero value or variability of the indices corresponds to a stronger climate change for RCP8.5 than for RCP2.6.

2.2. Scaling of the ISMIP forcings

The ISMIP6 forcings for the AIS consist of anomalies for the surface temperature [ΔST(x, y, t)] and the SMB [ΔSMB(x, y, t)] relative to 1995–2014, and absolute values for the oceanic thermal forcing [TF(x, y, z, t)], all for the period 2015–2100. These were derived from a systematic sampling of CMIP5 GCMs that reflects their spread in future projections (Barthel and others, Reference Barthel2020), while CMIP6 GCMs were added mostly on the basis of availability (Payne and others, Reference Payne2021). The atmospheric forcings ΔST and ΔSMB enter the ice-sheet simulations directly as upper boundary conditions. By contrast, TF is used to compute sub-ice-shelf melt rates via a non-local quadratic parameterization (‘ISMIP6 standard approach’) calibrated by observations (Jourdain and others, Reference Jourdain2020).

To extend the ISMIP6 forcings until 2300, the oceanic thermal forcing is converted to an anomaly as well by subtracting the 1995–2014 mean:

(3)$$\begin{align*} {\Delta{\rm TF}( x,\; y,\; z,\; t) = {\rm TF}( x,\; y,\; z,\; t) - {\rm TF}_{1995-2014}( x,\; y,\; z) ,\; \\ \quad t \le 2100\, {\rm CE}.}\end{align*}$$

We then scale the anomalies by using the MIROC4m-derived climate indices as follows:

(4)$$\begin{align*} &{\matrix{ \Delta{\rm ST}( x,\; y,\; t) & = & c_{\rm ST}( t) & \times & \Delta{\rm ST}_{2091-2100}( x,\; y) ,\; \cr \Delta{\rm prec}( x,\; y,\; t) & = & c_{\rm prec}( t) & \times & \Delta{\rm prec}_{2091-2100}( x,\; y) ,\; \cr \Delta{\rm evap}( x,\; y,\; t) & = & c_{\rm evap}( t) & \times & \Delta{\rm evap}_{2091-2100}( x,\; y) ,\; \cr \Delta{\rm roff}( x,\; y,\; t) & = & c_{\rm roff}( t) & \times & \Delta{\rm roff}_{2091-2100}( x,\; y) ,\; \cr \Delta{\rm TF}( x,\; y,\; z,\; t) & = & c_{\rm oc}( t) & \times & \Delta{\rm TF}_{2091-2100}( x,\; y,\; z) ,\; }} \\& \quad t > 2100\, {\rm CE},\; \end{align*} $$

where Δprec, Δevap and Δroff are the anomalies of precipitation, evaporation and runoff, respectively, and the subscripts ‘2091–2100’ denote the mean values over this decade. The anomaly ΔSMB results from

(5)$$\begin{align*} & \Delta{\rm SMB}( x,\; y,\; t) = \Delta{\rm prec}( x,\; y,\; t) - \Delta{\rm evap}( x,\; y,\; t) \\& \quad\quad\quad\quad\quad\quad\quad \quad - \Delta{\rm roff}( x,\; y,\; t) ,\; \\& \quad t > 2100\, {\rm CE},\; \end{align*} $$

and ΔTF is converted back to absolute values:

(6)$$\begin{align*} & {\rm TF}( x,\; y,\; z,\; t) = {\rm TF}_{1995-2014}( x,\; y,\; z) + \Delta{\rm TF}( x,\; y,\; z,\; t) ,\; \\& \quad t > 2100\, {\rm CE}.\end{align*}$$

Thus, this method provides extended ISMIP6 forcings for the AIS [ΔST(x, y, t), ΔSMB(x, y, t), TF(x, y, z, t)] until the year 2300. Table 1 shows the magnitude of the atmospheric and oceanic forcing for all GCMs considered here. A noteworthy aspect is that the cumulative SMB anomaly can be both positive and negative. This is a consequence of the counteracting effects of increasing loss (runoff, evaporation), but also increasing precipitation due to larger moisture transport by the warmer air. The different GCMs predict a different net effect on the SMB, ranging from distinctly positive to distinctly negative.

Table 1. Mean surface temperature anomaly ($\overline {\Delta {\rm ST}}$), cumulative SMB anomaly (cΔSMB) and mean oceanic thermal forcing ($\overline {{\rm TF}}$) for the period 2015–2300 and all climate forcings of this study

$\overline {\Delta {\rm ST}}$ and cΔSMB spatially averaged over the present-day AIS (including ice shelves), $\overline {{\rm TF}}$ spatially averaged over the ice-shelf areas and the depth interval 200–800 m. Anomalies relative to 1995–2014 means of the reference climatology.

While the climate indices are based on results from a single GCM (MIROC4m), a strength of our method is that it does not depend much on the sensitivity of this particular model to changed external forcing (‘climate sensitivity’). This is so because of the normalization carried out by Eqn. (1), which eliminates at least the linear part of the climate sensitivity: computing the indices with a different GCM that is, for instance, twice as sensitive as MIROC4m (produces a climate signal twice as strong) would produce exactly the same result. Differences can only arise from nonlinear effects (different responses of other GCMs to longer-term radiative forcing relative to 2100 anomalies) and different internal variabilities. The extrapolation of Eqn. (2) makes sure that the normalization also holds for RCP2.6, even though we do not have MIROC4m results for this pathway. Therefore, the extrapolation, even though ad hoc, is not too critical. It mainly affects the long-term behaviour, for which it produces the plausible result that, while for RCP8.5 climate change continues beyond 2100, for RCP2.6 a partial recovery occurs.

In the supplementary document, we apply for RCP8.5 the MIROC4m-derived climate indices on the MIROC4m climate fields (surface temperature, ocean temperature at 450 m depth, precipitation) themselves, which allows a direct comparison of originally computed and extrapolated results. This exercise shows that, overall, the climate-index method performs reasonably well, but also identifies a source of uncertainty from regional, nonlinear effects that cannot be captured by the method.

For one of the ISMIP6 simulations (CCSM4/RCP8.5), an additional ice-shelf-collapse forcing is employed. It stipulates that ice-shelf collapse occurs when the mean surface melting over the past decade exceeds a threshold value of 725 mm water equiv. a^-1 (Trusel and others, Reference Trusel2015; Seroussi and others, Reference Seroussi2020). Hereby, the mean surface melting is parameterized by an exponential function of the DJF (austral summer) near-surface air temperature, ${\rm ST\_DJF}$. For t ≤ 2100 CE, ${\rm ST\_DJF}$ is taken from bias-adjusted, GCM-forced simulations with the regional climate model RACMO2 (Trusel and others, Reference Trusel2015). For t > 2100 CE, we construct ${\rm ST\_DJF}$ via its anomaly, $\Delta {\rm ST\_DJF}$, as follows:

(7)$$\begin{align*} &{\matrix{ \Delta{\rm ST\_DJF}( x,\; y,\; t) & = & c_{\rm ST\_DJF}( t) \times \Delta{\rm ST}_{2091-2100}( x,\; y) \, ,\; \cr {\rm ST\_DJF}( x,\; y,\; t) & = & {\rm ST}_{1995-2014}( x,\; y) \cr & & + [ {\rm ST\_DJF}_{\rm param}( x,\; y) - {\rm ST}_{\rm param}( x,\; y) ] \cr & & + \Delta{\rm ST\_DJF}( x,\; y,\; t) ,\; }} \\ & \quad t > 2100\, {\rm CE}.\end{align*}$$

Note that ΔST_2091−2100 and ST_1995−2014 are mean-annual rather than DJF values because only these are available in the ISMIP6 forcing. To convert to DJF, we use the parameterized difference $[ {\rm ST\_DJF}_{\rm param}-{\rm ST}_{\rm param}]$ of present-day DJF and mean-annual temperatures, respectively, by Fortuin and Oerlemans (Reference Fortuin and Oerlemans1990) (see also Greve and others, Reference Greve2020a, their Eqs. (10) and (11)).

This method provides annual ice-shelf-collapse masks for the years 2101–2300. To guarantee a smooth transition to the pre-2100 masks provided by ISMIP6, we define a 10-year interval 2101–2110, during which the final masks are computed as weighted averages between the original ISMIP6 masks and our extended ones.

3. Model experiments

We apply the ice-sheet model SICOPOLIS (SICOPOLIS Authors, 2021) to the AIS with hybrid shallow-ice–shelfy-stream dynamics (Bernales and others, Reference Bernales, Rogozhina, Greve and Thomas2017) for grounded ice, shallow-shelf dynamics for floating ice, a Weertman-Budd-type sliding law tuned separately for 18 different regions (Greve and others, Reference Greve2020a), and ice thermodynamics treated by the one-layer melting-CTS enthalpy scheme (CTS: cold-temperate transition surface; Blatter and Greve, Reference Blatter and Greve2015; Greve and Blatter, Reference Greve and Blatter2016). The horizontal resolution is 8 km, which, in combination with the sliding law that features a continuous basal drag across the grounding line, is sufficient to produced good results for the grounding line migration in both advance and retreat scenarios (Gladstone and others, Reference Gladstone2017; Chambers and others, Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022). In the vertical, we use terrain-following coordinates (sigma transformation) with 81 layers in the ice domain and 41 layers in the thermal lithosphere layer below. For details on the set-up, the initialization procedure by a paleoclimatic spin-up, comparisons between the simulated and observed ice thickness and surface velocity for our initialization year 1990, as well as the historical run (‘hist’) that bridges the gap between 1990 and the start date of the projections in January 2015 by employing NorESM1-M/RCP8.5 SMB, surface temperature (ST) and oceanic thermal forcing (TF), we refer to Greve and others (Reference Greve2020a). From the last 20 years of the historical run, we extract the 1995–2014 climatology (SMB, ST) required as a reference for the future climate experiments.

An overview of our extended ISMIP6 experiments is given in Table 2. The method of extending the ISMIP6 climate forcing until 2300 is described above (Sect. 2). 14 experiments are for the 21st-century unabated warming pathway RCP8.5 (CMIP5) / SSP5-8.5 (CMIP6), and three are for the reduced emissions pathway RCP2.6 (CMIP5) / SSP1-2.6 (CMIP6) that is largely in line with the commitments of the Paris Agreement (maintaining the global mean temperature well below a $2^\circ {\rm C}$ increase above pre-industrial levels). In two of the RCP8.5 experiments, the impact of different calibrations of the parameterization for sub-ice-shelf melting (‘high’ and ‘low’ vs. the normal, ‘medium’ calibration, thereby exploring the uncertainty of the parameterization) is tested, and one experiment employs a calibration in which only observed basal-melt values near the grounding line of the Pine Island ice shelf are used (‘PIGL-medium’) (Jourdain and others, Reference Jourdain2020). As already mentioned in Sect. 2.2, in one experiment, ice-shelf fracture triggered by surface melting is accounted for. In addition, a projection control simulation (‘ctrl_proj’) employs constant climate conditions based on the 1995–2014 reference climatology.

Table 2. Extended ISMIP6-Antarctica Tier-1 and 2 future climate experiments for the period 2015–2300 discussed in this study

See Nowicki and others (Reference Nowicki2020) for references for the GCMs.

4. Results

The simulated mass change of the AIS, expressed as a sea-level contribution, is shown in Fig. 2. For the control run ctrl_proj, the ice sheet remains stable, showing only a minimal mass loss of 3.49 mm SLE during the 286 years model time. This stability also holds for the longer control run over a 986-years period until the year 3000 reported by Chambers and others (Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022).

Figure 2. (a) ISMIP6-Antarctica historical run (hist), projection control run (ctrl_proj) and Tier-1 and 2 future climate experiments extended until 2300: Simulated ice mass change, counted positively for loss and expressed as a sea-level contribution. Experiments in the legend grouped such that RCP8.5/SSP5-8.5 comes first and RCP2.6/SSP1-2.6 thereafter, otherwise like in Table 2. The red and blue boxes to the right show the 2300 means for RCP8.5/SSP5-8.5 and RCP2.6/SSP1-2.6, respectively (RCP8.5/SSP5-8.5: also ${}\pm \!1\hbox {-sigma}$); the whiskers show the corresponding full ranges. (b) Same 2300 statistics, but for the results by Chambers and others (Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022) without a further warming trend beyond 2100.

Until 2100, the future projections are equivalent to the original ISMIP6-Antarctica simulations carried out with SICOPOLIS (Seroussi and others, Reference Seroussi2020; Greve and others, Reference Greve2020a; Payne and others, Reference Payne2021), characterized by a range of uncertainties from a notable mass loss to a slight mass gain and no clear separation between RCP8.5/SSP5-8.5 (mean ± 1-sigma range: 32.6 ± 67.2 mm SLE) and RCP2.6/SSP1-2.6 (8.4 ± 15.9 mm SLE). [Note: The values for RCP8.5/SSP5-8.5 differ from those given by Greve and others (Reference Greve2020a) because that study excluded Exp. 13 (NorESM1-M/RCP8.5 with ‘PIGL-medium’ calibration) for the computation, which we have included here.] However, a different picture emerges in the longer term. By 2300, the ice sheet ends up losing mass for all cases, and it responds much more strongly to the ensemble of RCP8.5/SSP5-8.5 simulations than to the RCP2.6/SSP1-2.6 simulations. The final mass loss amounts to 1.54 ± 0.84 m SLE for RCP8.5/SSP5-8.5, while it is limited to 0.164 ± 0.049 m SLE for RCP2.6/SSP1-2.6. The mean values for both pathways are approximately twice as large as those found by Chambers and others (Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022) for a sustained late-21st-century climate (no further warming trend) beyond 2100 (Fig. 2b).

The influence of the ice mass loss due to oceanic forcing is explored by Exps. 5, 9, 10 (NorESM1-M/RCP8.5 with ‘medium’, ‘high’ and ‘low’ calibration, respectively). The results are shown by the olive lines and olive-shaded regions in Fig. 2. By 2300, the simulated mass loss is $1.43^{ + 0.31}_{ - 0.20}\, {\rm m\, SLE}$. Thus, the uncertainty due to these three calibrations is significant, but smaller than the uncertainty due to the GCM forcings. A more extreme test is Exp. 13, which is NorESM1-M/RCP8.5 with the ‘PIGL-medium’ calibration. Until the mid-22nd century, this leads to an, on average, ~2 times larger total ice-shelf basal melting than for Exp. 5 (later on, the difference becomes smaller due to ice-shelf decay). It has a pronounced effect on the mass loss of the ice sheet: By 2300, it is 2.97 m SLE compared to the initial 1990 state, more than doubling that of Exp.5. This highlights the great sensitivity of the AIS to oceanic forcing.

Exps. 8 and 12 (CCSM4/RCP8.5) investigate the influence of ice-shelf hydrofracture as described above (included in Exp. 12). Exp. 8 is actually one of the cases that produce a mass gain of the ice sheet during the 21st century. Adding ice-shelf hydrofracture via the time-dependent collapse mask in Exp. 12 reverts this behaviour to a mass loss. By 2300, both experiments produce a loss, which is 1.27 m SLE for Exp. 8, but 2.00 m SLE for Exp. 12. Thus, the process can act as a significant amplifier of the mass loss of the AIS.

In Fig. 3, the sea-level contributions by 2300 are shown separately for the regions of the EAIS, the WAIS and the Antarctic Peninsula (AP). Averaged across all the high-emission cases (panel a), the WAIS contributes 1.28 m SLE, compared with just 0.24 m SLE from the EAIS and 0.019 m SLE from the AP. This contrasts with the low-emission cases (panel b) which have average SLE contributions from the WAIS and EAIS of 0.064 and 0.097 m, respectively, with the AP contribution being very slightly negative at −0.00078 m. These findings agree with those by Chambers and others (Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022) (simulations until 3000, no further warming or cooling trend beyond 2100), and the reason for the predominant contribution from the WAIS for RCP8.5/SSP5-8.5 is that it undergoes a collapse in the areas of the Amundsen Sea Embayment and the Siple Coast where the bedrock bathymetry deepens inward. We cannot decide whether this modelled collapse is a ‘classical’ MISI (unstable and irreversible retreat driven by an internal instability mechanism), or whether it is a more direct response to the loss of ice-shelf buttressing (Haseloff and Sergienko, Reference Haseloff and Sergienko2018; Gudmundsson and others, Reference Gudmundsson, Paolo, Adusumilli and Fricker2019). However, either way, the result is a rapid mass loss from the WAIS. By contrast, the weaker climatic forcings of RCP2.6/SSP1-2.6 do not trigger a WAIS collapse in our simulations.

Figure 3. Simulated sea-level contribution for the entire ice sheet and three regions (EAIS, WAIS, AP; shown in the inset) by the year 2300 relative to ctrl_proj, for (a) the RCP8.5/SSP5-8.5 and (b) the RCP2.6/SSP1-2.6 ensemble. The whiskers show the full range of sea-level contributions across the simulations that make up the means, and the circles on the whiskers show the result for each simulation. Note that the y-axis ranges are different by a factor of 10.

Figure 4 shows the components of the global mass balance (integrated over the ice sheet, all counted as positive for mass gain): SMB, basal mass balance (BMB), calving and ice volume change (dV/dt). For the RCP8.5/SSP5-8.5 means (thick lines in the figure), the ice sheet keeps losing volume (∝ mass) over the entire period and at an accelerating rate of change. The SMB, driven by the counteracting effects of increasing precipitation and increasing runoff, remains positive throughout the model time, even with a slight increase. The BMB, predominantly produced by sub-ice-shelf melting, strongly increases in magnitude over time, which is the main reason for the accelerated volume loss of the ice sheet. The essentially monotonic increase (except for short-term fluctuations) of the BMB contrasts with the study by Chambers and others (Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022) where it peaks around 2100, but then falls back to values around −4 × 10¹² m³ a^-1 between 2150 and 2300. Calving into the surrounding ocean (that results from a 50-m ice-thickness threshold; Greve and others, Reference Greve2020a) is also a significant component of the mass balance. However, it changes only moderately over time. The inter-annual variability of the volume change is mainly due to that of the SMB and, to a lesser extent, the BMB, which reflects the variability of the atmospheric and oceanic forcings.

Figure 4. Main components of the global mass balance for the RCP8.5/SSP5-8.5 and RCP2.6/SSP1-2.6 experiments: Surface mass balance (SMB, purple), basal mass balance (BMB, blue), calving (yellow) and ice volume change (dV/dt, green). Thick lines are the respective means, thin lines the individual results for the fourteen RCP8.5/SSP5-8.5 and three RCP2.6/SSP1-2.6 experiments.

The mass balance components feature significant variabilities across the individual experiments. In some cases, the SMB falls below its initial level, episodically even becoming negative. This can happen if the stabilizing effect of increasing precipitation is less pronounced in the respective climate forcing. The greatest outlier for BMB, with strongly elevated negative values during the late 21st and the 22nd century, is Exp. 13 (NorESM1-M/RCP8.5). This is a consequence of the ‘PIGL’ calibration of ice-shelf basal melting based on observations close to the grounding line of Pine Island Glacier, which is used for this experiment only, whereas for all other experiments, the calibration is based on circum-Antarctic observations (Jourdain and others, Reference Jourdain2020; Seroussi and others, Reference Seroussi2020). A similar outlier for calving is Exp. 12 (CCSM4/RCP8.5), the only experiment for which an explicit parameterization for ice-shelf fracture (assumed to be caused by large amounts of liquid water ponding at the surface of ice shelves) is employed (Trusel and others, Reference Trusel2015; Seroussi and others, Reference Seroussi2020).

Regarding the RCP2.6/SSP1-2.6 means, no significant trend in any of the mass balance components can be seen during the model period. Apart from short-term fluctuations, the initial imbalance (negative dV/dt) remains essentially constant. In contrast to RCP8.5/SSP5-8.5, where BMB clearly dominates, the losses due to BMB and calving are of similar size. Approximately 85% of the combined loss is compensated by the positive SMB, so that only a limited residual imbalance remains. The variability across the RCP2.6/SSP1-2.6 experiments is less pronounced than what we have seen for RCP8.5/SSP5-8.5. The significance of this statement is limited, though, because of the smaller number of experiments. However, one interesting observation is that the CMIP6-forced Exp. B7 (CNRM-CM6-1/SSP1-2.6) produces a notably larger BMB, and thus dV/dt, than the two CMIP5-forced Exps. 7 and A8.

We now discuss in more detail the results of Exp. 6 (MIROC-ESM-CHEM/RCP8.5), which was already focused on in the previous study by Chambers and others (Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022). It features high atmospheric changes and median ocean warming compared to the other CMIP5 GCMs (Barthel and others, Reference Barthel2020), and it produces a $\sim {}29\%$ above average mass loss of 1.99 m SLE (WAIS 1.69 m, EAIS 0.16 m, AP 0.13 m) for our combined CMIP5/CMIP6 ensemble. The residual of the global mass balance, Res = |SMB + BMB + Calving − dV/dt|, has a mean value of 2.14 × 10⁴ m³ a^-1 over the 286 years simulation time. This is eight orders of magnitude smaller than the typical range of values of the individual components [${\cal O}( 10^{12}\, {\rm m^3\, a^{-1}})$, see Fig. 4], so that the model conserves mass very well (see also Calov and others, Reference Calov2018).

Snapshots of the simulated ice thickness and surface velocity for Exp. 6 are shown in Fig. 5. By 2095, the ice sheet has overall undergone only minor changes compared to the initial year 2015, corresponding to a mass loss of 0.0070 m SLE. By 2195, which is just after the calving event mentioned above, the changes are more notable (mass loss 0.40 m SLE). A large part of the present-day Ross Ice Shelf has disappeared, and the grounding lines in the areas of the Pine Island and Thwaites glaciers and the Siple Coast have migrated inland, along with a speed-up of the ice streams. A similar, yet less pronounced grounding line retreat and speed-up has occurred in the area of Totten Glacier, and the northern part of the Amery Ice Shelf has disintegrated. By the end of 2300 (mass loss 1.99 m SLE), the collapse of the WAIS is progressing in full force, with dramatic retreats of the Pine Island/Thwaites and Siple Coast grounding lines, accompanied by additional retreats of the grounding line of the Filchner–Ronne Ice Shelf. In the EAIS, the Amery Ice Shelf has disappeared almost entirely, and the area of Totten Glacier shows some more grounding line retreat; however, with limited impact on the ice sheet further inland.

Figure 5. Snapshots of (a) the simulated ice thickness and (b) the surface velocity for Exp. 6 (MIROC-ESM-CHEM/RCP8.5) for the years 2015, 2095, 2195 and 2301 (i.e., the end of 2300). Spacing of the latitude circles is $10^\circ$, spacing of the longitude rays is $45^\circ$. RIS: Ross Ice Shelf, FRIS: Filchner–Ronne Ice Shelf, AmIS: Amery Ice Shelf, PIG: Pine Island Glacier, ThwG: Thwaites Glacier, TotG: Totten Glacier.

5. Discussion and conclusion

The future climate simulations for the AIS until the year 2300 carried out in the present study reveal a different picture compared to the original ISMIP6-Antarctica simulations for the 21st century (Seroussi and others, Reference Seroussi2020; Greve and others, Reference Greve2020a; Payne and others, Reference Payne2021). The latter produced a range of mass changes from a small gain (due to precipitation increases) to a moderate loss, and no clear distinction between the unabated warming (RCP8.5/SSP5-8.5) and reduced emissions pathways (RCP2.6/SSP1-2.6). By contrast, in our extended simulations, by 2300 mass gains of the AIS do not occur any more, and the mass loss under RCP8.5/SSP5-8.5 is substantially larger than that under RCP2.6/SSP1-2.6 (mean values of ~1.5 m SLE vs. only ~0.16 m SLE). In terms of the $\hbox {mean}\pm {}\hbox {1-sigma}$ mass loss range, RCP8.5/SSP5-8.5 becomes disjoint from RCP2.6/SSP1-2.6 around the year 2208. For comparison, Lowry and others (Reference Lowry, Krapp, Golledge and Alevropoulos-Borrill2021) report for their projections, based on a statistical emulator, ‘likely’ and ‘very likely’ times of emergence (significant separation between the RCP8.5 and RCP2.6 ensembles) of 2116 and 2189, respectively. Most of the mass loss under RCP8.5/SSP5-8.5 originates from the WAIS, which suffers a collapse in almost all simulations.

Compared to the previous study by Chambers and others (Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022) in which a sustained late-21st-century climate beyond 2100 was assumed, the response of the AIS to our extrapolated climate-change scenarios is about two times larger by 2300 for both pathways. For RCP8.5/SSP5-8.5, this stronger response is immediately to be expected because, as detailed in Sect. 2.1, all climate indices are well above unity during the 22nd and 23rd century, which means that climate change becomes ever more serious. For RCP2.6/SSP1-2.6, the situation is different because the atmospheric climate recovers to below late-21st-century levels (all five indices), while only the oceanic climate index stays above unity after 2100. Evidently, the impact of the increasing oceanic forcing outweighs that of the recovering atmospheric forcing, so that mass loss due to sub-ice-shelf melt and subsequently enhanced drainage of grounded ice is the dominant process.

The threat of a WAIS instability under future climate change has already been expressed by a number of previous studies (see Sect. 1 for more details). A particular feature of the ISMIP6-Antarctica set-up for SICOPOLIS is that it applies an SMB correction to keep the ice sheet stable and close to observed conditions in the recent past (Greve and others, Reference Greve2020a). This SMB correction has significant additional accumulation in the area of the Pine Island and Thwaites glaciers to prevent them from becoming unstable even before the end of the spin-up simulations. It is possible that this procedure over-stabilizes the area, so that the onset of the instability originating from there could be delayed. On the other hand, SICOPOLIS is quite sensitive to sub-ice-shelf melting compared to other ice-sheet models (Edwards and others, Reference Edwards2021). This factor facilitates the development of an instability because it makes the ice sheet more sensitive to grounding-line migration.

As already discussed by Chambers and others (Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022), a weakness of the ISMIP6-type simulations is that the atmospheric forcing is not affected by the changing geometry of the ice sheet. While the ocean thermal forcing, TF, is three-dimensional and thus changes as the ice shelves become thicker or thinner, the atmospheric forcing fields, ΔST and ΔSMB, are 2D fields that were derived by GCMs under the assumption of a static, present-day ice sheet. Therefore, they do not change as the ice-surface elevation rises or falls. A possible improvement, also beneficial for the resolution of the forcing fields, is to reprocess the GCM output by a regional climate model and compute vertical gradients of ST and SMB, so that at least a linearized feedback can be implemented (Franco and others, Reference Franco, Fettweis, Lang and Erpicum2012). Such a method was employed for the ISMIP6-Greenland simulations and derived work (Goelzer and others, Reference Goelzer2020; Nowicki and others, Reference Nowicki2020; Greve and Chambers, Reference Greve and Chambers2022). Short of very demanding and computationally expensive fully coupled climate–ice-sheet simulations, a further possibility is to involve snapshots of climate-model results combined with more refined parameterizations for the climatic forcing, similar to the approach by Abe-Ouchi and others (Reference Abe-Ouchi2013) for the paleoglaciation of the Northern Hemisphere.

A weakness of the climate indices we used to extrapolate the ISMIP6 forcings until 2300 is that the method relies on the projections of a single GCM (MIROC4m) which will influence the forcings after 2100. However, as explained in Sect. 2.2, we do not consider this limitation too critical due to the normalization carried out by Eqn. (1), which eliminates the linear part of the climate sensitivity. Nevertheless, it would be worthwhile to investigate this issue quantitatively based on results from other GCMs for which extended projections until 2300 are available. For the ISMIP6 follow-up initiative ‘ISMIP6 Projections 2300 Antarctica’ (see below), climate forcings until 2300 are provided from four GCMs for RCP8.5/SSP5-8.5, and from one GCM for SSP1-2.6. These could be used for the purpose, including checking the validity of our extrapolation from RCP8.5 and RCP4.5 to RCP2.6 specified by Eqn. (2). We consider such a detailed investigation of the climate-index method to be beyond the scope of this work; however, the issue may be taken up in a future study by using other climate models to calculate the climate indices, carry out the extrapolation of the climate forcings with these alternative indices and assess the impact on future ice-sheet evolution.

Furthermore, future work in the direction of long-term simulations of ice-sheet response to climate change should aim at employing more direct, rather than extrapolated, GCM projections beyond 2100 and involving an ensemble of ice-sheet models to allow an improved assessment of uncertainties. Within ISMIP6, this is currently planned within the ISMIP6 Projections 2300 Antarctica initiative for the AIS (https://theghub.org/groups/ismip6/wiki/ISMIP6-Projections2300-Antarctica, last access: 2023-05-11). In detail, this initiative focuses on projections extended until 2300 (as in the present study) based on CMIP5 and CMIP6 GCM outputs. Some experiments will use repeated climate forcing from the late 21st century, sampled randomly between 2100 and 2300 (similar to the approach by Chambers and others, Reference Chambers, Greve, Obase, Saito and Abe-Ouchi2022), while others will be based on output from GCMs directly run until 2300 under CMIP forcing pathways. We will contribute to these projections with the SICOPOLIS model.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/jog.2023.41.

Code and data availability

SICOPOLIS (SICOPOLIS Authors, 2021) is free and open-source software, published on a persistent Git repository hosted by the Alfred Wegener Institute for Polar and Marine Research (AWI) in Bremerhaven, Germany (https://gitlab.awi.de/sicopolis/sicopolis/). The output data produced for this study are available at Zenodo, https://doi.org/10.5281/zenodo.7773727.

Acknowledgements

We thank the Scientific Editor Frank Pattyn and two reviewers for constructive remarks and suggestions that helped to improve the manuscript. We thank Jorge Bernales (Utrecht University) and Reinhard Calov (PIK Potsdam) for their recent contributions to the development of the SICOPOLIS model, and Tom Dangleterre (Hokkaido University) for postprocessing our output data for the Zenodo archive. Some colour schemes of our figures were taken from Paul Tol's (SRON Netherlands Institute for Space Research) online resource at https://personal.sron.nl/~pault (last access: 2023-05-11). We thank the Climate and Cryosphere (CliC) effort, which provided support for ISMIP6 through sponsoring of workshops, hosting the ISMIP6 website and wiki and promoting ISMIP6. We acknowledge the World Climate Research Programme, which, through its Working Group on Coupled Modelling, coordinated and promoted CMIP5 and CMIP6. We thank the climate modelling groups for producing their model output and making it available; the Earth System Grid Federation (ESGF) for archiving the CMIP data and providing access to it; the University at Buffalo for ISMIP6 data distribution and upload; and the multiple funding agencies who support CMIP5, CMIP6 and ESGF. We thank the ISMIP6 steering committee, the ISMIP6 model selection group and ISMIP6 dataset preparation group for their continuous engagement in defining ISMIP6. This is ISMIP6 contribution No. 28.

Authors’ contributions

Ralf Greve, Christopher Chambers and Ayako Abe-Ouchi designed the study. Takashi Obase, Fuyuki Saito, Wing-Le Chan and Ayako Abe-Ouchi ran the MIROC simulations. Ralf Greve, Christopher Chambers and Takashi Obase computed the climate indices and the extrapolated ISMIP6 climate forcing. Ralf Greve ran the SICOPOLIS simulations with support from Christopher Chambers. All authors discussed and interpreted the results. Ralf Greve wrote the manuscript with contributions from all authors.

Financial support

Ralf Greve, Christopher Chambers, Wing-Le Chan and Ayako Abe-Ouchi were supported by Japan Society for the Promotion of Science (JSPS) KAKENHI Grant No. JP17H06323. Ralf Greve, Wing-Le Chan and Ayako Abe-Ouchi were supported by JSPS KAKENHI Grant No. JP17H06104. Takashi Obase, Fuyuki Saito and Ayako Abe-Ouchi were supported by JSPS Grant-in-Aid for Japan–France Integrated Action Program (SAKURA Program) No. JPJSBP120213203.

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Figure 1. RCP8.5 and RCP2.6 climate indices for the mean-annual surface temperature (cST), DJF surface temperature ($c_{\rm ST\_DJF}$), precipitation (cprec), evaporation (cevap), surface runoff (croff) and ocean temperature (coc), derived from MIROC4m simulations until the year 2300. Note that the scaling defined by Eqn. (1) implies that any non-zero value or variability of the indices corresponds to a stronger climate change for RCP8.5 than for RCP2.6.