Abstract
Abstract. The development of northern high-latitude peatlands played an important role in the carbon (C) balance of the land biosphere since the Last Glacial Maximum (LGM). At present, carbon storage in northern peatlands is substantial and estimated to be 500 ± 100 Pg C (1 Pg C = 1015 g C). Here, we develop and apply a peatland module embedded in a dynamic global vegetation and land surface process model (LPX-Bern 1.0). The peatland module features a dynamic nitrogen cycle, a dynamic C transfer between peatland acrotelm (upper oxic layer) and catotelm (deep anoxic layer), hydrology- and temperature-dependent respiration rates, and peatland specific plant functional types. Nitrogen limitation down-regulates average modern net primary productivity over peatlands by about half. Decadal acrotelm-to-catotelm C fluxes vary between −20 and +50 g C m−2 yr−1 over the Holocene. Key model parameters are calibrated with reconstructed peat accumulation rates from peat-core data. The model reproduces the major features of the peat core data and of the observation-based modern circumpolar soil carbon distribution. Results from a set of simulations for possible evolutions of northern peat development and areal extent show that soil C stocks in modern peatlands increased by 365–550 Pg C since the LGM, of which 175–272 Pg C accumulated between 11 and 5 kyr BP. Furthermore, our simulations suggest a persistent C sequestration rate of 35–50 Pg C per 1000 yr in present-day peatlands under current climate conditions, and that this C sink could either sustain or turn towards a source by 2100 AD depending on climate trajectories as projected for different representative greenhouse gas concentration pathways.
Highlights
Ocean ScienceNorthern high-latitude peatlands represent a substantial carbon (C) pool of the terrestrial biosphere
The highest rate of increase in thaw depth at 12–7 kyr before present (BP) may be related to the Holocene thermal maximum (HTM) in high northern latitudes (Kaufman et al, 2004), where abundant peatlands exist
The slight decrease in thaw depth over the last 7 kyr, especially in North America, may be caused by the late Holocene climate cooling, after the HTM. Both changes in water table and thaw depth increase the saturation of liquid water in the soil and the amount of water available to plants; this tends to increase net primary productivity (NPP) and net ecosystem production (NEP)
Summary
Ocean ScienceNorthern high-latitude peatlands represent a substantial carbon (C) pool of the terrestrial biosphere. Due to itsTehxteremCelryysoloswpdheceayr,eaccumulated C in present-day peatland dates back to the end of the Last Glacial Maximum (LGM), about 16 500 years (yr) before present (BP) (MacDonald et al, 2006). Over this long period, peatlands can form organic soil layers of several meters in depth. Peatlands can form organic soil layers of several meters in depth This amounts to an exceptionally high soil C density (C storage per unit area) and a total of 500 ± 100 Pg C (1 Pg C = 1015 g C) stored in the northern high-latitude peatlands in spite of their limited extent (Yu, 2012). Peat soils (histosols) can occur in areas of permafrost (histels) and contribute substantially to the total circumpolar soil C inventory (Tarnocai et al, 2009)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
