Firn on ice sheets

The Firn Symposium team; Charles Amory; Christo Buizert; Sammie Buzzard; Elizabeth Case; Nicole Clerx; Riley Culberg; Rajashree Tri Datta; Rahul Dey; Reinhard Drews; Devon Dunmire; Clare Eayrs; Nicolaj Hansen; Angelika Humbert; Athul Kaitheri; Kaitlin Keegan; Peter Kuipers Munneke; Jan T. M. Lenaerts; Stef Lhermitte; Doug Mair; Ian McDowell; Jessica Mejia; Colin R. Meyer; Elizabeth Morris; Dorothea Moser; Falk M. Oraschewski; Emma Pearce; Sophie de Roda Husman; Nicole-Jeanne Schlegel; Timm Schultz; Sebastian B. Simonsen; C. Max Stevens; Elizabeth R. Thomas; Megan Thompson-Munson; Nander Wever; Bert Wouters

doi:10.1038/s43017-023-00507-9

Firn on ice sheets

The Firn Symposium team, Charles Amory, Christo Buizert, Sammie Buzzard, Elizabeth Case, Nicole Clerx, Riley Culberg, Rajashree Tri Datta, Rahul Dey, Reinhard Drews, Devon Dunmire, Clare Eayrs, Nicolaj Hansen, Angelika Humbert, Athul Kaitheri, Kaitlin Keegan, Peter Kuipers Munneke, Jan T. M. Lenaerts, Stef Lhermitte, Doug MairIan McDowell, Jessica Mejia, Colin R. Meyer, Elizabeth Morris, Dorothea Moser, Falk M. Oraschewski, Emma Pearce, Sophie de Roda Husman, Nicole-Jeanne Schlegel, Timm Schultz, Sebastian B. Simonsen, C. Max Stevens, Elizabeth R. Thomas, Megan Thompson-Munson, Nander Wever, Bert Wouters

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

Most of the Greenland and Antarctic ice sheets are covered with firn — the transitional material between snow and glacial ice. Firn is vital for understanding ice-sheet mass balance and hydrology, and palaeoclimate. In this Review, we synthesize knowledge of firn, including its formation, observation, modelling and relevance to ice sheets. The refreezing of meltwater in the pore space of firn currently prevents 50% of meltwater in Greenland from running off into the ocean and protects Antarctic ice shelves from catastrophic collapse. Continued atmospheric warming could inhibit future protection against mass loss. For example, warming in Greenland has already contributed to a 5% reduction in firn pore space since 1980. All projections of future firn change suggest that surface meltwater will have an increasing impact on firn, with melt occurring tens to hundreds of kilometres further inland in Greenland, and more extensively on Antarctic ice shelves. Although progress in observation and modelling techniques has led to a well-established understanding of firn, the large uncertainties associated with meltwater percolation processes (refreezing, ice-layer formation and storage) must be reduced further. A tighter integration of modelling components (firn, atmosphere and ice-sheet models) will also be needed to better simulate ice-sheet responses to anthropogenic warming and to quantify future sea-level rise.

Original language	English
Journal	Nature Reviews Earth and Environment
Volume	5
Issue number	2
Pages (from-to)	79-99
ISSN	2662-138X
DOIs	https://doi.org/10.1038/s43017-023-00507-9
Publication status	Published - 2024

Bibliographical note

Please note publisher correction:

In the version of the article initially published, in Fig. 5, under “Radar altimeter”, “O(16–160 m)” previously read “O(16–160 km)”. This has now been corrected in the HTML and PDF versions of the article.

Access to Document

10.1038/s43017-023-00507-9

OpenUrl availability

Full text

Cite this

The Firn Symposium team, Amory, C., Buizert, C., Buzzard, S., Case, E., Clerx, N., Culberg, R., Datta, R. T., Dey, R., Drews, R., Dunmire, D., Eayrs, C., Hansen, N., Humbert, A., Kaitheri, A., Keegan, K., Kuipers Munneke, P., Lenaerts, J. T. M., Lhermitte, S., ... Wouters, B. (2024). Firn on ice sheets. Nature Reviews Earth and Environment, 5(2), 79-99. https://doi.org/10.1038/s43017-023-00507-9

@article{464f62b7cc4d4fb9b9b57023c85ec6fd,

title = "Firn on ice sheets",

abstract = "Most of the Greenland and Antarctic ice sheets are covered with firn — the transitional material between snow and glacial ice. Firn is vital for understanding ice-sheet mass balance and hydrology, and palaeoclimate. In this Review, we synthesize knowledge of firn, including its formation, observation, modelling and relevance to ice sheets. The refreezing of meltwater in the pore space of firn currently prevents 50% of meltwater in Greenland from running off into the ocean and protects Antarctic ice shelves from catastrophic collapse. Continued atmospheric warming could inhibit future protection against mass loss. For example, warming in Greenland has already contributed to a 5% reduction in firn pore space since 1980. All projections of future firn change suggest that surface meltwater will have an increasing impact on firn, with melt occurring tens to hundreds of kilometres further inland in Greenland, and more extensively on Antarctic ice shelves. Although progress in observation and modelling techniques has led to a well-established understanding of firn, the large uncertainties associated with meltwater percolation processes (refreezing, ice-layer formation and storage) must be reduced further. A tighter integration of modelling components (firn, atmosphere and ice-sheet models) will also be needed to better simulate ice-sheet responses to anthropogenic warming and to quantify future sea-level rise.",

author = "{The Firn Symposium team} and Charles Amory and Christo Buizert and Sammie Buzzard and Elizabeth Case and Nicole Clerx and Riley Culberg and Datta, {Rajashree Tri} and Rahul Dey and Reinhard Drews and Devon Dunmire and Clare Eayrs and Nicolaj Hansen and Angelika Humbert and Athul Kaitheri and Kaitlin Keegan and {Kuipers Munneke}, Peter and Lenaerts, {Jan T. M.} and Stef Lhermitte and Doug Mair and Ian McDowell and Jessica Mejia and Meyer, {Colin R.} and Elizabeth Morris and Dorothea Moser and Oraschewski, {Falk M.} and Emma Pearce and {de Roda Husman}, Sophie and Nicole-Jeanne Schlegel and Timm Schultz and Simonsen, {Sebastian B.} and Stevens, {C. Max} and Thomas, {Elizabeth R.} and Megan Thompson-Munson and Nander Wever and Bert Wouters",

note = "Please note publisher correction: In the version of the article initially published, in Fig. 5, under “Radar altimeter”, “O(16–160 m)” previously read “O(16–160 km)”. This has now been corrected in the HTML and PDF versions of the article.",

year = "2024",

doi = "10.1038/s43017-023-00507-9",

language = "English",

volume = "5",

pages = "79--99",

journal = "Nature Reviews Earth and Environment",

issn = "2662-138X",

publisher = "Springer Nature Switzerland AG",

number = "2",

}

The Firn Symposium team, Amory, C, Buizert, C, Buzzard, S, Case, E, Clerx, N, Culberg, R, Datta, RT, Dey, R, Drews, R, Dunmire, D, Eayrs, C, Hansen, N, Humbert, A, Kaitheri, A, Keegan, K, Kuipers Munneke, P, Lenaerts, JTM, Lhermitte, S, Mair, D, McDowell, I, Mejia, J, Meyer, CR, Morris, E, Moser, D, Oraschewski, FM, Pearce, E, de Roda Husman, S, Schlegel, N-J, Schultz, T, Simonsen, SB, Stevens, CM, Thomas, ER, Thompson-Munson, M, Wever, N & Wouters, B 2024, 'Firn on ice sheets', Nature Reviews Earth and Environment, vol. 5, no. 2, pp. 79-99. https://doi.org/10.1038/s43017-023-00507-9

TY - JOUR

T1 - Firn on ice sheets

AU - The Firn Symposium team

AU - Amory, Charles

AU - Buizert, Christo

AU - Buzzard, Sammie

AU - Case, Elizabeth

AU - Clerx, Nicole

AU - Culberg, Riley

AU - Datta, Rajashree Tri

AU - Dey, Rahul

AU - Drews, Reinhard

AU - Dunmire, Devon

AU - Eayrs, Clare

AU - Hansen, Nicolaj

AU - Humbert, Angelika

AU - Kaitheri, Athul

AU - Keegan, Kaitlin

AU - Kuipers Munneke, Peter

AU - Lenaerts, Jan T. M.

AU - Lhermitte, Stef

AU - Mair, Doug

AU - McDowell, Ian

AU - Mejia, Jessica

AU - Meyer, Colin R.

AU - Morris, Elizabeth

AU - Moser, Dorothea

AU - Oraschewski, Falk M.

AU - Pearce, Emma

AU - de Roda Husman, Sophie

AU - Schlegel, Nicole-Jeanne

AU - Schultz, Timm

AU - Simonsen, Sebastian B.

AU - Stevens, C. Max

AU - Thomas, Elizabeth R.

AU - Thompson-Munson, Megan

AU - Wever, Nander

AU - Wouters, Bert

N1 - Please note publisher correction: In the version of the article initially published, in Fig. 5, under “Radar altimeter”, “O(16–160 m)” previously read “O(16–160 km)”. This has now been corrected in the HTML and PDF versions of the article.

PY - 2024

Y1 - 2024

N2 - Most of the Greenland and Antarctic ice sheets are covered with firn — the transitional material between snow and glacial ice. Firn is vital for understanding ice-sheet mass balance and hydrology, and palaeoclimate. In this Review, we synthesize knowledge of firn, including its formation, observation, modelling and relevance to ice sheets. The refreezing of meltwater in the pore space of firn currently prevents 50% of meltwater in Greenland from running off into the ocean and protects Antarctic ice shelves from catastrophic collapse. Continued atmospheric warming could inhibit future protection against mass loss. For example, warming in Greenland has already contributed to a 5% reduction in firn pore space since 1980. All projections of future firn change suggest that surface meltwater will have an increasing impact on firn, with melt occurring tens to hundreds of kilometres further inland in Greenland, and more extensively on Antarctic ice shelves. Although progress in observation and modelling techniques has led to a well-established understanding of firn, the large uncertainties associated with meltwater percolation processes (refreezing, ice-layer formation and storage) must be reduced further. A tighter integration of modelling components (firn, atmosphere and ice-sheet models) will also be needed to better simulate ice-sheet responses to anthropogenic warming and to quantify future sea-level rise.

AB - Most of the Greenland and Antarctic ice sheets are covered with firn — the transitional material between snow and glacial ice. Firn is vital for understanding ice-sheet mass balance and hydrology, and palaeoclimate. In this Review, we synthesize knowledge of firn, including its formation, observation, modelling and relevance to ice sheets. The refreezing of meltwater in the pore space of firn currently prevents 50% of meltwater in Greenland from running off into the ocean and protects Antarctic ice shelves from catastrophic collapse. Continued atmospheric warming could inhibit future protection against mass loss. For example, warming in Greenland has already contributed to a 5% reduction in firn pore space since 1980. All projections of future firn change suggest that surface meltwater will have an increasing impact on firn, with melt occurring tens to hundreds of kilometres further inland in Greenland, and more extensively on Antarctic ice shelves. Although progress in observation and modelling techniques has led to a well-established understanding of firn, the large uncertainties associated with meltwater percolation processes (refreezing, ice-layer formation and storage) must be reduced further. A tighter integration of modelling components (firn, atmosphere and ice-sheet models) will also be needed to better simulate ice-sheet responses to anthropogenic warming and to quantify future sea-level rise.

U2 - 10.1038/s43017-023-00507-9

DO - 10.1038/s43017-023-00507-9

M3 - Journal article

SN - 2662-138X

VL - 5

SP - 79

EP - 99

JO - Nature Reviews Earth and Environment

JF - Nature Reviews Earth and Environment

IS - 2

ER -

Firn on ice sheets

Abstract

Bibliographical note

Access to Document

OpenUrl availability

Fingerprint

Cite this