Open Access Te Herenga Waka-Victoria University of Wellington
Browse
DOCUMENT
manuscript.pdf (824.4 kB)
DOCUMENT
supplemental.pdf (3.06 MB)
1/0
2 files

Anthropogenic warming forces extreme annual glacier mass loss

journal contribution
posted on 2021-05-24, 00:04 authored by Lauren VargoLauren Vargo, Brian AndersonBrian Anderson, R Dadić, Huw HorganHuw Horgan, AN Mackintosh, AD King, AM Lorrey
Glaciers are unique indicators of climate change. While recent global-scale glacier decline has been attributed to anthropogenic forcing, direct links between human-induced climate warming and extreme glacier mass-loss years have not been documented. Here we apply event attribution methods to document this at the regional scale, targeting the highest mass-loss years (2011 and 2018) across New Zealand’s Southern Alps. Glacier mass balance is simulated using temperature and precipitation from multiple climate model ensembles. We estimate extreme mass loss was at least six times (2011) and ten times (2018) (>90% confidence) more likely to occur with anthropogenic forcing than without. This increased likelihood is driven by present-day temperatures ~1.0 °C above the pre-industrial average, confirming a connection between anthropogenic emissions and high annual ice loss. These results suggest that as warming and extreme heat events continue and intensify, there will be an increasingly visible human fingerprint on extreme glacier mass-loss years in the coming decades.

History

Preferred citation

Vargo, L. J., Anderson, B. M., Dadić, R., Horgan, H. J., Mackintosh, A. N., King, A. D. & Lorrey, A. M. (2020). Anthropogenic warming forces extreme annual glacier mass loss. Nature Climate Change, 10(9), 856-861. https://doi.org/10.1038/s41558-020-0849-2

Journal title

Nature Climate Change

Volume

10

Issue

9

Publication date

2020-09-01

Pagination

856-861

Publisher

Springer Science and Business Media LLC

Publication status

Published

Online publication date

2020-08-03

ISSN

1758-678X

eISSN

1758-6798

Language

en

Usage metrics

    Journal articles

    Exports

    RefWorks
    BibTeX
    Ref. manager
    Endnote
    DataCite
    NLM
    DC