Interannual variations of the mass balance of the Antarctica and Greenland ice sheets from GRACE

The prediction of short-term (100 year) changes in the mass balance of ice sheets and longer-term (1000 years) variations in their ice volumes is important for a range of climatic and environmental models. The Antarctic ice sheet contains between 24 M km 3 and 29 M km 3 of ice, equivalent to a eustatic sea level change of between 60m and 72m. The annual surface accumulation is estimated to be of the order of 2200 Gtonnes, equivalent to a sea level change of 6 mm a -1 . Analysis of the present-day accumulation regime of Antarctica indicates that about 25% ( ca. 500 Gt a -1 ) of snowfall occurs in the Antarctic Peninsula region with an area of only 6.8% of the continent. To date most models have focused upon solving predictive algorithms for the climate-sensitivity of the ice sheet, and assume: (i) surface mass balance is equivalent to accumulation (i.e. no melting, evaporation or deflation); (ii) percentage change in accumulation is proportional to change in saturation mixing ratio above the surface inversion layer; and (iii) there is a linear relation between mean annual surface air tem perature and saturation mixing ratio. For the A ntarctic Peninsula with mountainous terrain containing ice caps, outlet glaciers, valley glaciers and ice shelves, where there can be significant ablation at low levels and distinct climatic regimes, models of the climate response must be more complex. In addition, owing to the high accumulation and flow rates, even short- to medium -term predictions must take account of ice dynamics. Relationships are derived for the mass balance sensitivity and, using a model developed by Hindmarsh, the transient effects of ice dynamics are estimated. It is suggested that for a 2°C rise in mean annual surface tem perature over 40 years, ablation in the A ntarctic Peninsula region would contribute at least 1.0 mm to sea level rise, offsetting the fall of 0.5 mm contributed by increased accum ulation.

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Exploring the complex uncertainties in coupled climate-ice simulations of the Last Glacial Maximum

10.5194/egusphere-egu21-6693 ◽

2021 ◽

Author(s):

Lauren Gregoire ◽

Niall Gandy ◽

Lachlan Astfalck ◽

Robin Smith ◽

Ruza Ivanovic ◽

...

Keyword(s):

Mass Balance ◽

Last Glacial Maximum ◽

Ice Sheets ◽

Ice Sheet ◽

Glacial Maximum ◽

Sea Surface ◽

Surface Mass ◽

Last Glacial ◽

The Last Glacial Maximum ◽

The Last Glacial

<p>Simulating the co-evolution of climate and ice-sheets during the Quaternary is key to understanding some of the major abrupt changes in climate, ice and sea level. Indeed, events such as the Meltwater pulse 1a rapid sea level rise and Heinrich, Dansgaard&#8211;Oeschger and the 8.2 kyr climatic events all involve the interplay between ice sheets, the atmosphere and the ocean. Unfortunately, it is challenging to simulate the coupled Climate-Ice sheet system because small biases, errors or uncertainties in parts of the models are strongly amplified by the powerful interactions between the atmosphere and ice (e.g. ice-albedo and height-mass balance feedbacks). This leads to inaccurate or even unrealistic simulations of ice sheet extent and surface climate. To overcome this issue we need some methods to effectively explore the uncertainty in the complex Climate-Ice sheet system and reduce model biases. Here we present our approach to produce ensemble of coupled Climate-Ice sheet simulations of the Last Glacial maximum that explore the uncertainties in climate and ice sheet processes.</p><p>We use the FAMOUS-ICE earth system model, which comprises a coarse-resolution and fast general circulation model coupled to the Glimmer-CISM ice sheet model. We prescribe sea surface temperature and sea ice concentrations in order to control and reduce biases in polar climate, which strongly affect the surface mass balance and simulated extent of the northern hemisphere ice sheets. We develop and apply a method to reconstruct and sample a range of realistic sea surface temperature and sea-ice concentration spatio-temporal field. These are created by merging information from PMIP3/4 climate simulations and proxy-data for sea surface temperatures at the Last Glacial Maximum with Bayes linear analysis. We then use these to generate ensembles of FAMOUS-ice simulations of the Last Glacial maximum following the PMIP4 protocol, with the Greenland and North American ice sheets interactively simulated. In addition to exploring a range of sea surface conditions, we also vary key parameters that control the surface mass balance and flow of ice sheets. We thus produce ensembles of simulations that will later be used to emulate ice sheet surface mass balance. &#160;</p>

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Present and future mass balance of the ice sheets simulated with GCM

Annals of Glaciology ◽

10.1017/s0260305500013434 ◽

1996 ◽

Vol 23 ◽

pp. 187-193 ◽

Cited By ~ 9

Author(s):

Atsumu Ohmura ◽

Martin Wild ◽

Lennart Bengtsson

Keyword(s):

High Resolution ◽

Mass Balance ◽

Sea Level ◽

Sea Water ◽

Ice Sheets ◽

Internal Surface ◽

Surface Fluxes ◽

Specific Mass ◽

Mountain Glaciers ◽

Equivalent Time

A high-resolution GCM ECHAM3 T106 was used to simulate the climates of the present and of the future under doubled CO2The ECHAM3 T106 was integrated for an equivalent time of 5 years (1) with the observed SST of the 1980s and (2) with the SST for the 2 × CO2climate generated from the ECHAM1 T21 coupled transient experiment. The main motivation for using the GCM to simulate the mass balance is the level of skill in simulating precipitation and accumulation recently achieved in the high-resolution GCM experiment. The ablation is computed, based on the GCM internal surface fluxes and the temperature/ablation relationship formulated on the Greenland field data. The two ice sheets show very different reactions towards doubling the CO2. As the decrease in accumulation and the increase in ablation in Greenland cause an annual mean specific mass balance of −225 mm (eq. −390 km3), the increase in accumulation and virtually non-melt conditions in Antarctica result in a mean annual specific mass balance of + 23 mm (eq. + 325 km3). The sum of the mass balance on both ice sheets is equivalent to the annual sea-level rise of 0.2 mm. This experiment shows that other mechanisms for sea-level change, such as the thermal expansion of the sea water and the melt of small mountain glaciers, will remain important in the coming century.

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Erosion by Continental Ice Sheets

Journal of Glaciology ◽

10.1017/s0022143000029981 ◽

1979 ◽

Vol 23 (89) ◽

pp. 401-402

Author(s):

I. M. Whillans

Keyword(s):

Mass Balance ◽

Short Distance ◽

Ice Sheets ◽

Ice Sheet ◽

Present Theory ◽

Frictional Heat ◽

Break Up ◽

Basal Melting ◽

Continental Ice Sheets

Abstract Some of the problems with earlier theories for erosion and transport by ice sheets are discussed, and it is noted that those theories cannot simply account for the often-reported finding that most till is derived from bedrock only a few tens of kilometers up-glacier. Considerations of the mass balance of debris in transport lead to the conclusion that ice sheets are capable of transporting most debris only a short distance. The theory that the break-up of bedrock is mostly a preglacial process is developed. The advancing ice sheet collects the debris and then deposits it after a short travel. As the ice sheet first advances over the regolith, debris is frozen onto the base and is carried until basal melting due to geothermal and frictional heat causes lodgment till deposition. Most debris is deposited during the advance of the ice sheet and is carried only a short distance. A generally small amount of debris is carried at higher levels and is deposited during ice standstill and retreat as melt-out and ablation tills. The present theory makes many predictions, among them, that most till units are not traceable over long distances, that thick till sequences represent unstable glacier margins and not necessarily long periods of glacier occupation, and that lodgment tills are to be interpreted in terms of ice advances and ablation tills in terms of ice retreats. This paper is published in full in Journal of Geology, Vol. 86, No. 4, 1978, p. 516–24.

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Modeling Mass-Balance Changes During a Glaciation Cycle

Annals of Glaciology ◽

10.1017/s0260305500008661 ◽

1990 ◽

Vol 14 ◽

pp. 238-241 ◽

Cited By ~ 24

Author(s):

M.S. Pelto ◽

S.M. Higgins ◽

T.J. Hughes ◽

J.L. Fastook

Keyword(s):

Mass Balance ◽

Ice Sheets ◽

Climatic Conditions ◽

Alpine Glacier ◽

Alpine Glaciers

Identification of present-day climate setting and alpine glacier-balance gradients indicates that the balance gradient of alpine glaciers is primarily determined by climatic conditions. Determination of balance gradients for specific climatic settings on present-day ice sheets provides an analog for determining the mass balance on paleo and future ice sheets.

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Mass balance of the ice sheets and glaciers – Progress since AR5 and challenges

Earth-Science Reviews ◽

10.1016/j.earscirev.2019.102976 ◽

2020 ◽

Vol 201 ◽

pp. 102976 ◽

Cited By ~ 10

Author(s):

Edward Hanna ◽

Frank Pattyn ◽

Francisco Navarro ◽

Vincent Favier ◽

Heiko Goelzer ◽

...

Keyword(s):

Mass Balance ◽

Ice Sheets

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The Reconstruction of Former Ice Sheets and their Mass Balance Characteristics using a Non-Linearly Viscous Flow Model

Journal of Glaciology ◽

10.1017/s0022143000005876 ◽

1984 ◽

Vol 30 (105) ◽

pp. 140-152 ◽

Cited By ~ 32

Author(s):

G. S. Boulton ◽

G. D. Smith ◽

L. W. Morland

Keyword(s):

Boundary Condition ◽

Mass Balance ◽

Ice Sheets ◽

Ice Sheet ◽

Equilibrium Line Altitude ◽

Isostatic Compensation ◽

Geological Evidence ◽

Wide Range ◽

Terminal Zone ◽

Subglacial Topography

AbstractA model of a non-linearly viscous ice sheet is used to investigate the influence of net mass-balance pattern, basal boundary condition, and subglacial topography on the size and shape of ice sheets. The aim is to enable geological evidence of the extent of former ice sheets to be used as indicators of palaeoclimate. A series of curves are presented showing the relationships between ice-sheet span, net mass balance, and equilibrium-line altitude (ELA) for zero and complete isostatic compensation. These are applicable to a very wide range of basal boundary conditions. The way in which they can be used to reconstruct net mass-balance gradients for former ice sheets is demonstrated. Changes in the basal boundary condition only have a strong influence on glacier span when they occur in the terminal zone. Ice-sheet expansion and contraction is not merely accompanied by changes in snow-line elevation, but also by changes in the net mass-balance gradient. The combinations of these required to cause ice-sheet expansion and contraction are analysed. A non-linearly viscous model for ice suggests that ice-sheet volume changes may not be a simple function of their change in areal extent.

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