Abstract
Palsas and peat plateaus are climatically sensitive landforms in permafrost peatlands. Climate envelope models have previously related palsa/peat plateau distributions in Europe to modern climate, but similar bioclimatic modelling has not been attempted for North America. Recent climate change has rendered many palsas/peat plateaus in this region, and their valuable carbon stores, vulnerable. We fitted a binary logistic regression model to predict palsa/peat plateau presence for North America by relating the distribution of 352 extant landforms to gridded modern climate data. Our model accurately classified 85.3% of grid cells that contain observed palsas/peat plateaus and 77.1% of grid cells without observed palsas/peat plateaus. The model indicates that modern North American palsas/peat plateaus are supported by cold, dry climates with large seasonal temperature ranges and mild growing seasons. We used palaeoclimate simulations from a general circulation model to simulate Holocene distributions of palsas/peat plateaus at 500-year intervals. We constrained these outputs with timings of peat initiation, deglaciation, and postglacial drainage across the continent. Our palaeoclimate simulations indicate that this climate envelope remained stationary in western North America throughout the Holocene, but further east it migrated northwards during 11.5–6.0 ka BP. However, palsa extents in eastern North America were restricted from following this moving climate envelope by late deglaciation, drainage and peat initiation. We validated our Holocene simulations against available palaeoecological records and whilst they agree that permafrost peatlands aggraded earliest in western North America, our simulations contest previous suggestions that late permafrost aggradation in central Canada was climatically-driven.
Highlights
Peatlands in the northern circumpolar permafrost zone have been estimated to cover more than 3.5 million km2, and to contain 277.3e338 Pg of soil organic carbon (Tarnocai et al, 2009; Hugelius et al, 2014)
Modern distributions of North American palsas/peat plateaus are well described by a logistic regression model driven by mean annual temperature, rainfall, growing degree days and the interaction between rainfall and seasonal temperature range
Our results demonstrate that North American palsas/peat plateaus occupy a climate envelope that is largely similar to that in Fennoscandia, but which exhibits a broader range of temperature regimes
Summary
Peatlands in the northern circumpolar permafrost zone have been estimated to cover more than 3.5 million km, and to contain 277.3e338 Pg of soil organic carbon (Tarnocai et al, 2009; Hugelius et al, 2014). While frozen, this carbon store is rendered largely inert, increasingly widespread observations of permafrost thaw across northern high latitudes have raised concerns as to the future of this vast carbon stock under warming climates (Camill, 2005; Schuur et al, 2008, 2015). Losses of organic carbon from deep, previously frozen peat layers may prevent net accumulation for several decades or even centuries after thaw (O’Donnel et al, 2012; Jones et al, 2017)
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