Downscaling CESM2 in CLM5 to Hindcast Pre-Industrial Equilibrium Line Altitudes for Tropical Mountain Glaciers

doi:10.1029/2021GL094071

Tropical mountain glaciers are an important water resource and highly impacted by recent climate change. Tropical mountain glaciation also occurred in the recent and deep past, which presents opportunities for better validating paleoclimate simulations in continental interiors and mountainous regions but requires bridging global model scales (100s of km) with the $urn:x-wiley:00948276:media:grl62925:grl62925-math-0001$ 1–10 km scale of glaciers when paleotopography is poorly known. Here we hindcast tropical mountain glaciation in pre-industrial time by using global climate model meteorology to force standalone simulations in its land component that use high resolution topography to resolve selected tropical mountain glaciers. These simulations underestimate observed equilibrium line altitudes (ELA) by 249 $urn:x-wiley:00948276:media:grl62925:grl62925-math-0002$ 330 m, but the simulated ELA and snow lines capture observed inter-mountain ELA variability. Error in large-scale model precipitation and ELA reconstruction uncertainty are the main contributors to this bias.

DOI	10.1029/2021GL094071
	Downscaling CESM2 in CLM5 to Hindcast Pre-Industrial Equilibrium Line Altitudes for Tropical Mountain Glaciers
	Nicholas G. Heavens
	2021-08-25
发表期刊	Geophysical Research Letters
出版年	2021
英文摘要	Tropical mountain glaciers are an important water resource and highly impacted by recent climate change. Tropical mountain glaciation also occurred in the recent and deep past, which presents opportunities for better validating paleoclimate simulations in continental interiors and mountainous regions but requires bridging global model scales (100s of km) with the $urn:x-wiley:00948276:media:grl62925:grl62925-math-0001$ 1–10 km scale of glaciers when paleotopography is poorly known. Here we hindcast tropical mountain glaciation in pre-industrial time by using global climate model meteorology to force standalone simulations in its land component that use high resolution topography to resolve selected tropical mountain glaciers. These simulations underestimate observed equilibrium line altitudes (ELA) by 249 $urn:x-wiley:00948276:media:grl62925:grl62925-math-0002$ 330 m, but the simulated ELA and snow lines capture observed inter-mountain ELA variability. Error in large-scale model precipitation and ELA reconstruction uncertainty are the main contributors to this bias.
领域	气候变化
URL	查看原文
引用统计
文献类型	期刊论文
条目标识符	http://119.78.100.173/C666/handle/2XK7JSWQ/336652
专题	气候变化
推荐引用方式 GB/T 7714	Nicholas G. Heavens. Downscaling CESM2 in CLM5 to Hindcast Pre-Industrial Equilibrium Line Altitudes for Tropical Mountain Glaciers[J]. Geophysical Research Letters,2021.
APA	Nicholas G. Heavens.(2021).Downscaling CESM2 in CLM5 to Hindcast Pre-Industrial Equilibrium Line Altitudes for Tropical Mountain Glaciers.Geophysical Research Letters.
MLA	Nicholas G. Heavens."Downscaling CESM2 in CLM5 to Hindcast Pre-Industrial Equilibrium Line Altitudes for Tropical Mountain Glaciers".Geophysical Research Letters (2021).

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