Accelerated global glacier mass loss in the early twenty-first century

Hugonnet, Romain; McNabb, Robert; Berthier, Étienne; Menounos, Brian; Nuth, Christopher; Girod, Luc; Farinotti, Daniel; Huss, Matthias; Dussaillant, Inés; Brun, Fanny; Kääb, Andreas

doi:10.1038/s41586-021-03436-z

Cited by 926 publications

(984 citation statements)

References 89 publications

(127 reference statements)

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“…Negative trends of change of small glaciers can be seen also in NZ (Ciracì et al, 2018) and FJ (Zheng et al, 2018). The recently published global atlas of glacier elevation changes at 100 m resolution by Hugonnet et al (2021) shows a comparable spatial pattern of ℎ ⁄ across the regions investigated here.…”

Section: Comparison With Other Studiessupporting

confidence: 57%

“…However, within the glacier boundaries used in this study, the changes calculated by Hugonnet et al (2021) for the period 2010-2019 were on average less negative by ca. 0.4 m a -1 for sites experiencing ℎ ⁄ < -1.0 m a -1 and by ca.…”

Section: Comparison With Other Studiesmentioning

confidence: 71%

“…These facts suggest that the mass gain reported in this paper resulted from a post-1990 climate forcing, acting on a shorter timescale than the reaction time of glaciers. A recent global study of glacier elevation changes by Hugonnet et al (2021) suggests that mountain glaciers in north Spitsbergen have been 335 relatively close to balance since at least the early-2000's.…”

Section: The North Spitsbergen Anomaly 325mentioning

confidence: 99%

“…Recent progress in large-scale glacier mass balance studies, utilizing climate modelling, satellite altimetry, gravimetry and photogrammetry, fundamentally improved our knowledge on the general trends of glacier decay in the Arctic and the contribution of its ice masses to the global sea-level rise (e.g. Moholdt et al, 2012;Box et al, 2018;Noël et al, 2018;Wouters et al, 2019;Hugonnet et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

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Recent contrasting behaviour of mountain glaciers across the European High Arctic revealed by ArcticDEM data

Małecki

2021

Preprint

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Abstract. Small land-terminating mountain glaciers are a widespread and important element of Arctic ecosystems, influencing local hydrology, microclimate, and ecology, among others. Due to little ice volumes, this class of ice masses is very sensitive to climate warming, the latter of which is extremely well manifested in the European sector of the Arctic, i.e. in the Barents Sea area. Archipelagos surrounding the Barents Sea, i.e. Svalbard (SV), Novaya Zemlya (NZ), and Franz Josef Land (FJ), host numerous populations of mountain glaciers, but their response to recent strong warming remains understudied in most locations. This paper aims to obtain a snapshot of their state by utilizing high-resolution elevation data (ArcticDEM) to investigate the recent (ca. 2011–2017) elevation and volume changes of 382 small glaciers across SV, NZ, and FJ. The study concludes that many mountain glacier sites across the Barents Sea have been in a critical imbalance with the recent climate and might melt away within the coming several decades. However, deviations from the general trend exist, e.g. a cluster of small glaciers in north SV experiencing thickening. The findings reveal that near-stagnant glaciers might exhibit contrasting behaviours (fast thinning vs. thickening) over relatively short distances, being a challenge for climate models, but also an opportunity to test their reliability.

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Section: Comparison With Other Studiessupporting

confidence: 57%

Section: Comparison With Other Studiesmentioning

confidence: 71%

Section: The North Spitsbergen Anomaly 325mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Recent contrasting behaviour of mountain glaciers across the European High Arctic revealed by ArcticDEM data

Małecki

2021

Preprint

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“…Driven by climate change, glaciers in most high mountain ranges around the globe are receding and losing mass rapidly (Jomelli et al, 2011;Davies and Glasser, 2012;Zekollari et al, 2019;Davaze et al, 2020;Hugonnet et al, 2021). Whilst glaciers steadily thin and contribute to sea level rise through increased melting (Zemp et al, 2019), another aspect of glacier change and adjustment to drier conditions is the progressive accumulation of surface debris stemming from the surrounding valley walls and lateral moraines (Scherler et al, 2011;Kirkbride and Deline, 2013;Sasaki et al, 2016;Tielidze et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Evolution of Surface Characteristics of Three Debris-Covered Glaciers in the Patagonian Andes From 1958 to 2020

et al. 2021

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A number of glaciological observations on debris-covered glaciers around the globe have shown a delayed length and mass adjustment in relation to climate variability, a behavior normally attributed to the ice insulation effect of thick debris layers. Dynamic interactions between debris cover, geometry and surface topography of debris-covered glaciers can nevertheless govern glacier velocities and mass changes over time, with many glaciers exhibiting high thinning rates in spite of thick debris cover. Such interactions are progressively being incorporated into glacier evolution research. In this paper we reconstruct changes in debris-covered area, surface velocities and surface features of three glaciers in the Patagonian Andes over the 1958–2020 period, based on satellite and aerial imagery and Digital Elevation Models. Our results show that debris cover has increased from 40 ± 0.6 to 50 ± 6.7% of the total glacier area since 1958, whilst glacier slope has slightly decreased. The gently sloping tongues have allowed surface flow velocities to remain relatively low (<60 m a−1) for the last two decades, preventing evacuation of surface debris, and contributing to the formation and rise of the ice cliff zone upper boundary. In addition, mapping of end of summer snowline altitudes for the last two decades suggests an increase in the Equilibrium Line Altitudes, which promotes earlier melt out of englacial debris and further increases debris-covered ice area. The strongly negative mass budget of the three investigated glaciers throughout the study period, together with the increases in debris cover extent and ice cliff zones up-glacier, and the low velocities, shows a strong linkage between debris cover, mass balance evolution, surface velocities and topography. Interestingly, the presence of thicker debris layers on the lowermost portions of the glaciers has not lowered thinning rates in these ice areas, indicating that the mass budget is mainly driven by climate variability and calving processes, to which the influence of enhanced thinning at ice cliff location can be added.

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