Landscapes nearby glaciers are disproportionally affected by climate change, but we lack detailed information on microclimate variations that can modulate the impacts of global warming on proglacial ecosystems and their biodiversity. Here, we use near-subsurface soil temperatures in 175 stations from polar, equatorial and alpine glacier forelands to generate high-resolution temperature reconstructions, assess spatial variability in microclimate change from 2001 to 2020, and estimate whether microclimate heterogeneity might buffer the severity of warming trends. Temporal changes in microclimate are tightly linked to broad-scale conditions, but the rate of local warming shows great spatial heterogeneity, with faster warming nearby glaciers and during the warm season, and an extension of the snow-free season. Still, most of the fine-scale spatial variability of microclimate is one-to-ten times larger than the temporal change experienced during the past 20 years, indicating the potential for microclimate to buffer climate change, possibly allowing organisms to withstand, at least temporarily, the effects of warming.The high-resolution global model of soil temperature and snow cover change in mountain ecosystems developed here shows that areas nearby glaciers are warming faster than other mountain regions, and these effects are particularly rapid in tropical mountains.
Heterogeneous changes of soil microclimate in high mountains and glacier forelands / S. Marta, A. Zimmer, M. Caccianiga, M. Gobbi, R. Ambrosini, R.S. Azzoni, F. Gili, F. Pittino, W. Thuiller, A. Provenzale, G.F. Ficetola. - In: NATURE COMMUNICATIONS. - ISSN 2041-1723. - 14:1(2023), pp. 5306.1-5306.11. [10.1038/s41467-023-41063-6]
Heterogeneous changes of soil microclimate in high mountains and glacier forelands
M. Caccianiga;R. Ambrosini;R.S. Azzoni;G.F. FicetolaUltimo
2023
Abstract
Landscapes nearby glaciers are disproportionally affected by climate change, but we lack detailed information on microclimate variations that can modulate the impacts of global warming on proglacial ecosystems and their biodiversity. Here, we use near-subsurface soil temperatures in 175 stations from polar, equatorial and alpine glacier forelands to generate high-resolution temperature reconstructions, assess spatial variability in microclimate change from 2001 to 2020, and estimate whether microclimate heterogeneity might buffer the severity of warming trends. Temporal changes in microclimate are tightly linked to broad-scale conditions, but the rate of local warming shows great spatial heterogeneity, with faster warming nearby glaciers and during the warm season, and an extension of the snow-free season. Still, most of the fine-scale spatial variability of microclimate is one-to-ten times larger than the temporal change experienced during the past 20 years, indicating the potential for microclimate to buffer climate change, possibly allowing organisms to withstand, at least temporarily, the effects of warming.The high-resolution global model of soil temperature and snow cover change in mountain ecosystems developed here shows that areas nearby glaciers are warming faster than other mountain regions, and these effects are particularly rapid in tropical mountains.
| File | Dimensione | Formato | |
|---|---|---|---|
|
s41467-023-41063-6.pdf
accesso aperto
Tipologia:
Publisher's version/PDF
Dimensione
27.88 MB
Formato
Adobe PDF
|
27.88 MB | Adobe PDF | Visualizza/Apri |
Pubblicazioni consigliate
I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
