Abstract
Surface energy budgets of high-latitude permafrost systems are poorly represented in Earth system models (ESMs), yet permafrost is rapidly degrading and these dynamics are critical to future carbon-climate feedback predictions. A potentially important factor in permafrost degradation neglected so far by ESMs is heat transfer from precipitation, although increases in soil temperature and thaw depth have been observed following increases in precipitation. Using observations and a mechanistic ecosystem model, we show here that increases in precipitation hasten active layer development beyond that caused by surface air warming across the North Slope of Alaska (NSA) under recent and 21st century climate (RCP8.5). Modeled active layer depth (ALD) in simulations that allow precipitation heat transfer agreed very well with observations from 28 Circumpolar Active Layer Monitoring sites (R2 = 0.63; RMSE = 10 cm). Simulations that ignored precipitation heat transfer resulted in lower spatially-averaged soil temperatures and a 39 cm shallower ALD by 2100 across the NSA. The results from our sensitivity analysis show that projected increases in 21st century precipitation deepen the active layer by enhancing precipitation heat transfer and ground thermal conductivity, suggesting that precipitation is as important an environmental control on permafrost degradation as surface air temperature. We conclude that ESMs that do not account for precipitation heat transfer likely underestimate ALD rates of change, and thus likely predict biased ecosystem responses.
Highlights
The permafrost region stores more than twice as much carbon as currently in the atmosphere (Zimov et al 2006, Ping et al 2008, Schuur et al 2008)
Biases caused by ignoring precipitation heat transfer reduced the soil temperature and the active layer depth (ALD)
We examined the extent of permafrost degradation in response to changes in air temperature and precipitation under current and future climates in a continuous permafrost region on the North Slope of Alaska (NSA)
Summary
The permafrost region stores more than twice as much carbon as currently in the atmosphere (Zimov et al 2006, Ping et al 2008, Schuur et al 2008). Over the past few decades, rapid thawing of the permafrost and increases in the active layer depth (ALD; maximum annual thaw depth) have been reported in response to near-surface air warming and increases in precipitation across the high-latitudes of the northern hemisphere (Brown and Romanovsky 2008, IPCC 2013). These rapid permafrost changes could affect the atmosphere and climate system through effects on the carbon cycle (Davidson and Janssens 2006, Schuur et al 2008, Nowinski et al 2010, Commane et al 2017, Turetsky et al 2020), surface water, and energy balances (Schuur et al, 2015, Stiegler et al 2016). Increases in snow accumulation during winter may insulate the soil, increasing soil temperatures (Schimel et al 2004, Lafreniere et al 2013)
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