Community estimate of global glacier mass changes from 2000 to 2023

Michael Zemp; Livia Jakob; Inés Dussaillant; Samuel U. Nussbaumer; Noel Gourmelen; Sophie Dubber; Geruo A; Sahra Abdullahi; Liss Marie Andreassen; Etienne Berthier; Atanu Bhattacharya; Alejandro Blazquez; Laura F. Boehm Vock; Tobias Bolch; Jason Box; Matthias H. Braun; Fanny Brun; Eric Cicero; William Colgan; Nicolas Eckert; Daniel Farinotti; Caitlyn Florentine; Dana Floricioiu; Alex Gardner; Christopher Harig; Javed Hassan; Romain Hugonnet; Matthias Huss; Tómas Jóhannesson; Chia-Chun Angela Liang; Chang-Qing Ke; Shfaqat Abbas Khan; Owen King; Marin Kneib; Lukas Krieger; Fabien Maussion; Enrico Mattea; Robert McNabb; Brian Menounos; Evan Miles; Geir Moholdt; Johan Nilsson; Finnur Pálsson; Julia Pfeffer; Livia Piermattei; Stephen Plummer; Andreas Richter; Ingo Sasgen; Lilian Schuster; Thorsten Seehaus; Xiaoyi Shen; Christian Sommer; Tyler Sutterley; Désirée Treichler; Isabella Velicogna; Bert Wouters; Harry Zekollari; Whyjay Zheng

doi:10.1038/s41586-024-08545-z

Community estimate of global glacier mass changes from 2000 to 2023

Michael Zemp, Livia Jakob, Inés Dussaillant, Samuel U. Nussbaumer, Noel Gourmelen, Sophie Dubber, Geruo A, Sahra Abdullahi, Liss Marie Andreassen, Etienne Berthier, Atanu Bhattacharya, Alejandro Blazquez, Laura F. Boehm Vock, Tobias Bolch, Jason Box, Matthias H. Braun, Fanny Brun, Eric Cicero, William Colgan, Nicolas EckertDaniel Farinotti, Caitlyn Florentine, Dana Floricioiu, Alex Gardner, Christopher Harig, Javed Hassan, Romain Hugonnet, Matthias Huss, Tómas Jóhannesson, Chia-Chun Angela Liang, Chang-Qing Ke, Shfaqat Abbas Khan, Owen King, Marin Kneib, Lukas Krieger, Fabien Maussion, Enrico Mattea, Robert McNabb, Brian Menounos, Evan Miles, Geir Moholdt, Johan Nilsson, Finnur Pálsson, Julia Pfeffer, Livia Piermattei, Stephen Plummer, Andreas Richter, Ingo Sasgen, Lilian Schuster, Thorsten Seehaus, Xiaoyi Shen, Christian Sommer, Tyler Sutterley, Désirée Treichler, Isabella Velicogna, Bert Wouters, Harry Zekollari, Whyjay Zheng

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Abstract

Glaciers are indicators of ongoing anthropogenic climate change1. Their melting leads to increased local geohazards2, and impacts marine3 and terrestrial4,5 ecosystems, regional freshwater resources6, and both global water and energy cycles7,8. Together with the Greenland and Antarctic ice sheets, glaciers are essential drivers of present9,10 and future11,12,13 sea-level rise. Previous assessments of global glacier mass changes have been hampered by spatial and temporal limitations and the heterogeneity of existing data series14,15,16. Here we show in an intercomparison exercise that glaciers worldwide lost 273 ± 16 gigatonnes in mass annually from 2000 to 2023, with an increase of 36 ± 10% from the first (2000–2011) to the second (2012–2023) half of the period. Since 2000, glaciers have lost between 2% and 39% of their ice regionally and about 5% globally. Glacier mass loss is about 18% larger than the loss from the Greenland Ice Sheet and more than twice that from the Antarctic Ice Sheet17. Our results arise from a scientific community effort to collect, homogenize, combine and analyse glacier mass changes from in situ and remote-sensing observations. Although our estimates are in agreement with findings from previous assessments14,15,16 at a global scale, we found some large regional deviations owing to systematic differences among observation methods. Our results provide a refined baseline for better understanding observational differences and for calibrating model ensembles12,16,18, which will help to narrow projection uncertainty for the twenty-first century11,12,18.

Original language	English
Article number	5835
Pages (from-to)	382-388
Number of pages	7
Journal	Nature
Volume	639
Issue number	8054
Early online date	19 Feb 2025
DOIs	https://doi.org/10.1038/s41586-024-08545-z
Publication status	Published (in print/issue) - 13 Mar 2025

Bibliographical note

Publisher Copyright:
© The Author(s) 2025.

Data Access Statement

Regional glacier mass-change estimates from the individual research teams and combined results within and among observation methods are available from the World Glacier Monitoring Service (https://doi.org/10.5904/wgms-glambie-2024-07). Figure 1 and Extended Data Fig. 2 used global background maps from Natural Earth110 and glacier regions defined by the Global Terrestrial Network for Glaciers51. Source data are provided with this paper.

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10.1038/s41586-024-08545-zLicence: CC BY

Community estimate of global-Final versionFinal published version, 21.5 MBLicence: CC BY

Cite this

Zemp, M., Jakob, L., Dussaillant, I., Nussbaumer, S. U., Gourmelen, N., Dubber, S., A, G., Abdullahi, S., Andreassen, L. M., Berthier, E., Bhattacharya, A., Blazquez, A., Boehm Vock, L. F., Bolch, T., Box, J., Braun, M. H., Brun, F., Cicero, E., Colgan, W., ... Zheng, W. (2025). Community estimate of global glacier mass changes from 2000 to 2023. Nature, 639(8054), 382-388. Article 5835. https://doi.org/10.1038/s41586-024-08545-z

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title = "Community estimate of global glacier mass changes from 2000 to 2023",

abstract = "Glaciers are indicators of ongoing anthropogenic climate change1. Their melting leads to increased local geohazards2, and impacts marine3 and terrestrial4,5 ecosystems, regional freshwater resources6, and both global water and energy cycles7,8. Together with the Greenland and Antarctic ice sheets, glaciers are essential drivers of present9,10 and future11,12,13 sea-level rise. Previous assessments of global glacier mass changes have been hampered by spatial and temporal limitations and the heterogeneity of existing data series14,15,16. Here we show in an intercomparison exercise that glaciers worldwide lost 273 ± 16 gigatonnes in mass annually from 2000 to 2023, with an increase of 36 ± 10\% from the first (2000–2011) to the second (2012–2023) half of the period. Since 2000, glaciers have lost between 2\% and 39\% of their ice regionally and about 5\% globally. Glacier mass loss is about 18\% larger than the loss from the Greenland Ice Sheet and more than twice that from the Antarctic Ice Sheet17. Our results arise from a scientific community effort to collect, homogenize, combine and analyse glacier mass changes from in situ and remote-sensing observations. Although our estimates are in agreement with findings from previous assessments14,15,16 at a global scale, we found some large regional deviations owing to systematic differences among observation methods. Our results provide a refined baseline for better understanding observational differences and for calibrating model ensembles12,16,18, which will help to narrow projection uncertainty for the twenty-first century11,12,18.",

author = "Michael Zemp and Livia Jakob and In{\'e}s Dussaillant and Nussbaumer, \{Samuel U.\} and Noel Gourmelen and Sophie Dubber and Geruo A and Sahra Abdullahi and Andreassen, \{Liss Marie\} and Etienne Berthier and Atanu Bhattacharya and Alejandro Blazquez and \{Boehm Vock\}, \{Laura F.\} and Tobias Bolch and Jason Box and Braun, \{Matthias H.\} and Fanny Brun and Eric Cicero and William Colgan and Nicolas Eckert and Daniel Farinotti and Caitlyn Florentine and Dana Floricioiu and Alex Gardner and Christopher Harig and Javed Hassan and Romain Hugonnet and Matthias Huss and T{\'o}mas J{\'o}hannesson and Liang, \{Chia-Chun Angela\} and Chang-Qing Ke and Khan, \{Shfaqat Abbas\} and Owen King and Marin Kneib and Lukas Krieger and Fabien Maussion and Enrico Mattea and Robert McNabb and Brian Menounos and Evan Miles and Geir Moholdt and Johan Nilsson and Finnur P{\'a}lsson and Julia Pfeffer and Livia Piermattei and Stephen Plummer and Andreas Richter and Ingo Sasgen and Lilian Schuster and Thorsten Seehaus and Xiaoyi Shen and Christian Sommer and Tyler Sutterley and D{\'e}sir{\'e}e Treichler and Isabella Velicogna and Bert Wouters and Harry Zekollari and Whyjay Zheng",

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Zemp, M, Jakob, L, Dussaillant, I, Nussbaumer, SU, Gourmelen, N, Dubber, S, A, G, Abdullahi, S, Andreassen, LM, Berthier, E, Bhattacharya, A, Blazquez, A, Boehm Vock, LF, Bolch, T, Box, J, Braun, MH, Brun, F, Cicero, E, Colgan, W, Eckert, N, Farinotti, D, Florentine, C, Floricioiu, D, Gardner, A, Harig, C, Hassan, J, Hugonnet, R, Huss, M, Jóhannesson, T, Liang, C-CA, Ke, C-Q, Khan, SA, King, O, Kneib, M, Krieger, L, Maussion, F, Mattea, E, McNabb, R, Menounos, B, Miles, E, Moholdt, G, Nilsson, J, Pálsson, F, Pfeffer, J, Piermattei, L, Plummer, S, Richter, A, Sasgen, I, Schuster, L, Seehaus, T, Shen, X, Sommer, C, Sutterley, T, Treichler, D, Velicogna, I, Wouters, B, Zekollari, H & Zheng, W 2025, 'Community estimate of global glacier mass changes from 2000 to 2023', Nature, vol. 639, no. 8054, 5835, pp. 382-388. https://doi.org/10.1038/s41586-024-08545-z

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T1 - Community estimate of global glacier mass changes from 2000 to 2023

AU - Zemp, Michael

AU - Jakob, Livia

AU - Dussaillant, Inés

AU - Nussbaumer, Samuel U.

AU - Gourmelen, Noel

AU - Dubber, Sophie

AU - A, Geruo

AU - Abdullahi, Sahra

AU - Andreassen, Liss Marie

AU - Berthier, Etienne

AU - Bhattacharya, Atanu

AU - Blazquez, Alejandro

AU - Boehm Vock, Laura F.

AU - Bolch, Tobias

AU - Box, Jason

AU - Braun, Matthias H.

AU - Brun, Fanny

AU - Cicero, Eric

AU - Colgan, William

AU - Eckert, Nicolas

AU - Farinotti, Daniel

AU - Florentine, Caitlyn

AU - Floricioiu, Dana

AU - Gardner, Alex

AU - Harig, Christopher

AU - Hassan, Javed

AU - Hugonnet, Romain

AU - Huss, Matthias

AU - Jóhannesson, Tómas

AU - Liang, Chia-Chun Angela

AU - Ke, Chang-Qing

AU - Khan, Shfaqat Abbas

AU - King, Owen

AU - Kneib, Marin

AU - Krieger, Lukas

AU - Maussion, Fabien

AU - Mattea, Enrico

AU - McNabb, Robert

AU - Menounos, Brian

AU - Miles, Evan

AU - Moholdt, Geir

AU - Nilsson, Johan

AU - Pálsson, Finnur

AU - Pfeffer, Julia

AU - Piermattei, Livia

AU - Plummer, Stephen

AU - Richter, Andreas

AU - Sasgen, Ingo

AU - Schuster, Lilian

AU - Seehaus, Thorsten

AU - Shen, Xiaoyi

AU - Sommer, Christian

AU - Sutterley, Tyler

AU - Treichler, Désirée

AU - Velicogna, Isabella

AU - Wouters, Bert

AU - Zekollari, Harry

AU - Zheng, Whyjay

PY - 2025/3/13

Y1 - 2025/3/13

N2 - Glaciers are indicators of ongoing anthropogenic climate change1. Their melting leads to increased local geohazards2, and impacts marine3 and terrestrial4,5 ecosystems, regional freshwater resources6, and both global water and energy cycles7,8. Together with the Greenland and Antarctic ice sheets, glaciers are essential drivers of present9,10 and future11,12,13 sea-level rise. Previous assessments of global glacier mass changes have been hampered by spatial and temporal limitations and the heterogeneity of existing data series14,15,16. Here we show in an intercomparison exercise that glaciers worldwide lost 273 ± 16 gigatonnes in mass annually from 2000 to 2023, with an increase of 36 ± 10% from the first (2000–2011) to the second (2012–2023) half of the period. Since 2000, glaciers have lost between 2% and 39% of their ice regionally and about 5% globally. Glacier mass loss is about 18% larger than the loss from the Greenland Ice Sheet and more than twice that from the Antarctic Ice Sheet17. Our results arise from a scientific community effort to collect, homogenize, combine and analyse glacier mass changes from in situ and remote-sensing observations. Although our estimates are in agreement with findings from previous assessments14,15,16 at a global scale, we found some large regional deviations owing to systematic differences among observation methods. Our results provide a refined baseline for better understanding observational differences and for calibrating model ensembles12,16,18, which will help to narrow projection uncertainty for the twenty-first century11,12,18.

AB - Glaciers are indicators of ongoing anthropogenic climate change1. Their melting leads to increased local geohazards2, and impacts marine3 and terrestrial4,5 ecosystems, regional freshwater resources6, and both global water and energy cycles7,8. Together with the Greenland and Antarctic ice sheets, glaciers are essential drivers of present9,10 and future11,12,13 sea-level rise. Previous assessments of global glacier mass changes have been hampered by spatial and temporal limitations and the heterogeneity of existing data series14,15,16. Here we show in an intercomparison exercise that glaciers worldwide lost 273 ± 16 gigatonnes in mass annually from 2000 to 2023, with an increase of 36 ± 10% from the first (2000–2011) to the second (2012–2023) half of the period. Since 2000, glaciers have lost between 2% and 39% of their ice regionally and about 5% globally. Glacier mass loss is about 18% larger than the loss from the Greenland Ice Sheet and more than twice that from the Antarctic Ice Sheet17. Our results arise from a scientific community effort to collect, homogenize, combine and analyse glacier mass changes from in situ and remote-sensing observations. Although our estimates are in agreement with findings from previous assessments14,15,16 at a global scale, we found some large regional deviations owing to systematic differences among observation methods. Our results provide a refined baseline for better understanding observational differences and for calibrating model ensembles12,16,18, which will help to narrow projection uncertainty for the twenty-first century11,12,18.

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DO - 10.1038/s41586-024-08545-z

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SN - 0028-0836

VL - 639

SP - 382

EP - 388

JO - Nature

JF - Nature

IS - 8054

M1 - 5835

ER -

Community estimate of global glacier mass changes from 2000 to 2023

Abstract

Bibliographical note

Data Access Statement

UN SDGs

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