Deriving mass balance and calving variations from reanalysis data and sparse observations, Glaciar San Rafael, northern Patagonia, 1950–2005

Koppes, Michèle; Conway, H.; Rasmussen, L. A.; Chernos, M.

doi:10.5194/tcd-5-1123-2011

Cited by 5 publications

(9 citation statements)

References 47 publications

(49 reference statements)

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“…Previous studies suggest that the general retreat and thinning of glaciers in Patagonia is a response to higher air temperatures (Rasmussen et al, 2007;Masiokas et al, 2008;Koppes et al, 2011) and/or ice flow acceleration due to the growth of proglacial lakes and increased calving rates (e.g., Harrison and Winchester, 2000;Rignot et al, 2003;Rivera et al, 2007;Willis et al, 2012). Despite Benito's proglacial lake increasing in area since 1973 (Figure 1), we discount the latter due to the lack of evidence for any significant increase in ice flow speed.…”

Section: Discussionmentioning

confidence: 99%

“…Air temperature at 850 hPa (∼1,400 m a.s.l.) was chosen because it represents both large-scale atmospheric circulation patterns and local climate at interannual timescales and is therefore a useful indicator of not only the energy fluxes received by the glacier surface but also the fraction of precipitation falling as snow (Rasmussen et al, 2007;Garreaud et al, 2011;Koppes et al, 2011).…”

Section: Reanalysis Climate Datamentioning

confidence: 99%

“…The high accumulation rates sustain the NPI even though air temperatures are positive over much of the icefield for large parts of the year (Rasmussen et al, 2007;Koppes et al, 2011). However, the low elevation termini and rapid mass turnover rates make the west side of the NPI sensitive to air temperature, which determines not only surface melt but also the fraction of precipitation that falls as snow (Warren and Sugden, 1993;Rasmussen et al, 2007;Koppes et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

“…The west side of the NPI is characterized by high accumulation rates due to a combination of moisture-laden westerlies from the Pacific Ocean and orographic precipitation over the central Andean ridge (Warren and Sugden, 1993;Harrison and Winchester, 2000;Hubbard et al, 2005). The high accumulation rates sustain the NPI even though air temperatures are positive over much of the icefield for large parts of the year (Rasmussen et al, 2007;Koppes et al, 2011). However, the low elevation termini and rapid mass turnover rates make the west side of the NPI sensitive to air temperature, which determines not only surface melt but also the fraction of precipitation that falls as snow (Warren and Sugden, 1993;Rasmussen et al, 2007;Koppes et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

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Rapid Surface Lowering of Benito Glacier, Northern Patagonian Icefield

et al. 2018

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The Patagonian Icefields, which straddle the Andes below 46 • S, are two of the most sensitive ice masses on Earth to climate change. However, recent mass loss from the icefields along with its spatial and temporal variability is not well-constrained. Here we determine surface elevation changes of Benito Glacier, a 163 km 2 outlet glacier draining the western flank of the North Patagonian Icefield, using a combination of field and satellite-derived elevation data acquired between 1973 and 2017. Our results demonstrate that just below the equilibrium line the glacier dramatically thinned by 133 m in the past 44 years, equivalent to a mean rate of 3.0 ± 0.2 m a −1 . We also find that surface lowering was temporally variable, characterized by a hiatus between 2000 and 2013, and a subsequent increase up to 7.7 ± 3.0 m a −1 between 2013 and 2017. Analysis of Benito Glacier's flow regime throughout the period indicates that the observed surface lowering was caused by negative surface mass balance, rather than dynamic thinning. The high rate of surface lowering observed over the past half a decade highlights the extreme sensitivity of mid-latitude glaciers to recent atmospheric forcing.

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Section: Discussionmentioning

confidence: 99%

Section: Reanalysis Climate Datamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Rapid Surface Lowering of Benito Glacier, Northern Patagonian Icefield

et al. 2018

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“…Recent analysis of southern South America glaciers has yielded data regarding glacier area, areal and 63 volume change since the Little Ice Age (LIA) (Davies and Glasser, 2012; Glasser et al 2011), ice 64 surface velocity (Rivera et al, 2012; Jaber et al, 2013; Mouginot and Rignot, 2015), surface mass 65 balance (Koppes et al, 2011; Mernild et al, 2015; Schaefer et al, 2015; Willis et al, 2011) and 66 surface thinning and elevation changes (dh/dt) (Rivera et al, 2007; Willis et al, 2012 warming has caused a decreased in the amount of precipitation falling as snow and increased 100 ablation, exacerbating glacier recession (Rasmussen et al, 2007).…”

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confidence: 99%

Distributed ice thickness and glacier volume in southern South America

Carrivick

Davies

James

et al. 2016

Global and Planetary Change

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14South American glaciers, including those in Patagonia, presently contribute the largest amount of by this study will facilitate future studies of ice dynamics and glacier isostatic adjustment, and will 34 be important for projecting water resources and glacier hazards. Garibaldi, are presently displaying a positive mass balance (Schaefer et al., 2015). The general and 53 dominant trend of ice mass loss is manifest in pronounced glacier recession (Davies and Glasser, 54 2012) and the largest contribution to sea level rise per unit area in the world (Ivins et al., 2011; 55 Mouginot and Rignot, 2015; Willis et al., 2012). Indeed this sea level contribution is ~ 10 % of that 56 from all glaciers and ice caps worldwide (Rignot et al., 2003). Over the next two centuries, mass loss 57 from these glaciers has implications for sea level rise (Braithwaite and Raper, 2002; Gardner et al., 58 2013; Glasser et al., 2011;Levermann et al., 2013), for increased hazards from glacial lake outburst 59 floods (Anacona et al., 2014; Dussaillant et al., 2009;Harrison et al., 2006; Loriaux and Casassa, 60 2013), and for water resources. 62Recent analysis of southern South America glaciers has yielded data regarding glacier area, areal and 63 volume change since the Little Ice Age (LIA) (Davies and Glasser, 2012; Glasser et al. 2011), ice 64 surface velocity (Rivera et al., 2012; Jaber et al., 2013; Mouginot and Rignot, 2015), surface mass 65 balance (Koppes et al., 2011; Mernild et al., 2015; Schaefer et al., 2015; Willis et al., 2011) and 66 surface thinning and elevation changes (dh/dt) (Rivera et al., 2007; Willis et al., 2012 warming has caused a decreased in the amount of precipitation falling as snow and increased 100 ablation, exacerbating glacier recession (Rasmussen et al., 2007). 102Some of these changes in precipitation have been related to variations in the strength of the 103 prevailing Southern Hemisphere Westerlies, with stronger westerlies augmenting local precipitation. 104Stronger westerlies will also result in a decreased amplitude of the local air temperature annual cycle, 105Manuscript published in Global and Planetary Change, 2016 4 while weaker westerlies result in a colder winter and warmer summer, increasing temperature 106 seasonality (Garreaud et al., 2013). The core of the Southern Hemisphere Westerlies is currently 50 107 to 55°S, but through the Holocene latitudinal variations in these winds periodically brought increased 108 precipitation to the area, driving glacier advance and recession (Boex et al., 2013;Lamy et al., 2010; 109 Moreno et al., 2012) but with a pronounced east-west shift (Ackert et al., 2008). The drainage basins were edited to include nunataks and this new dataset we refer to herein as 176'glacier outlines'. Nunataks, or areas of ice-free terrain, were identified in this study using Landsat 8 177Operational Land Imager (OLI) scenes and a mask derived from the Normalised Difference Snow 178Index (NDSI = (Green -SWIR)/(Green + SWIR)). OLI scenes w...

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Recent ice dynamics and mass balance of Jorge Montt Glacier, Southern Patagonia Icefield

et al. 2019

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The Southern Patagonia Icefield (SPI) withdrawal in recent decades shows contrasting behaviours between adjacent basins. One of the basins with highest volumetric losses is located at northernmost SPI. We refer to Jorge Montt tidewater glacier (48° 30′S/73° 30′W, 445 km2 in 2018), which retreated 2.7 km between 2011 and 2018 and thinned at rates of up to 21 m a−1 over this period. Based on the retreat record, remote-sensing imagery, field data, a mass-balance model and a calving parameterisation, we attempted to differentiate climatic-induced changes (i.e. surface mass balance) and dynamic responses (i.e. calving fluxes). The surface mass balance reached −4.15 km3 w.e. a−1 between 2012 and 2017. When frontal ablation is included, the net mass balance is −17.79 km3 w.e. a−1. This represents a change of trend compared with modelling estimations of positive surface mass balance prior to 2010. This shift is attributed to higher ablation rates given that accumulation is known to have increased between 1980 and 2015. The available evidence, therefore, indicates that frontal ablation is the main factor, supported by observed rates at Jorge Montt as high as 3.81 km3 w.e. a−1 in 2015, with ice velocities peaking at 11 km a−1.

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Deriving mass balance and calving variations from reanalysis data and sparse observations, Glaciar San Rafael, northern Patagonia, 1950–2005

Cited by 5 publications

References 47 publications

Rapid Surface Lowering of Benito Glacier, Northern Patagonian Icefield

Rapid Surface Lowering of Benito Glacier, Northern Patagonian Icefield

Distributed ice thickness and glacier volume in southern South America

Recent ice dynamics and mass balance of Jorge Montt Glacier, Southern Patagonia Icefield

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