Quantifying spatial and temporal Holocene carbon accumulation in ombrotrophic peatlands of the Eastmain region, Quebec, Canada

Fiche du document

Date

25 mai 2011

Type de document
Périmètre
Langue
Identifiants
  • handle:  10670/1.gy2eds
  • van Bellen, Simon; Dallaire, Pierre-Luc; Garneau, Michelle et Bergeron, Yves (2011). « Quantifying spatial and temporal Holocene carbon accumulation in ombrotrophic peatlands of the Eastmain region, Quebec, Canada ». Global Biogeochemical Cycles, 25(2), n/a-n/a.
Licence


Mots-clés

carbon accumulation chronology peat bog boreal LORCA northeastern Canada


Citer ce document

Simon van Bellen et al., « Quantifying spatial and temporal Holocene carbon accumulation in ombrotrophic peatlands of the Eastmain region, Quebec, Canada », UQAM Archipel : articles scientifiques, ID : 10670/1.gy2eds


Métriques


Partage / Export

Résumé 0

Northern peatlands represent important stocks of organic carbon (C). Peatland C dynamics have the potential to influence atmospheric greenhouse gas concentrations and are therefore of interest concerning future climate change. Quantification of Holocene variations in peat C accumulation rates is often based on a single, deep core. However, deep cores may overestimate accumulation rates when extrapolated to the ecosystem scale. We propose a reconstruction of C sequestration patterns based on multiple cores from three ombrotrophic peatlands in boreal Quebec, Canada. Both total C accumulation and temporal variations herein were quantified. Radiocarbon-dated stratigraphies from different sections resulted in peatland-specific age-depth models. Peatland initiation started rapidly after deglaciation around 7500 cal BP. Vertical accumulation slowed down in the course of the Holocene, whereas lateral expansion was rapid in the early stages but slowed down near mid-Holocene. Total C accumulation showed maximum rates between 5250 and 3500 cal BP with a regional mean Holocene apparent rate of 16.2 g m-2 yr-1. The Eastmain peatlands have been modest sinks of organic C compared to those of Alaska, western Canada and western Siberia, although differences in calculation methods hamper direct comparisons. Considering within-peatland dynamics, maximum total C sequestration coincided with a period of slowing down in both lateral expansion and vertical accumulation. Late-Holocene diminishing peatland C sink functions have been attributed to autogenic as well as allogenic factors. Height-induced surface drying and/or Neoglacial cooling effects may have forced the slowing down of C sequestration in the studied bogs. Results further show that, in order to obtain an accurate quantification of past C sequestration, reconstructions of peatland expansion are essential.

document thumbnail

Par les mêmes auteurs

Sur les mêmes sujets

Sur les mêmes disciplines

Exporter en