Journal
FRONTIERS IN EARTH SCIENCE
Volume 5, Issue -, Pages -Publisher
FRONTIERS MEDIA SA
DOI: 10.3389/feart.2017.00002
Keywords
soil carbon; climate change; boreal forests; organic matter biogeochemistry; ecosystem carbon fluxes
Categories
Funding
- NSERC [397494-10]
- Centre for Forest Science and Innovation of the Newfoundland and Labrador Agrifoods Agency
- Canada Research Chairs Programme
- Canadian Forest Service of Natural Resources Canada
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Climate warming enhances multiple ecosystem C fluxes, but the net impact of changing C fluxes on soil organic carbon (SOC) stocks over decadal to centennial time scales remains unclear. We investigated the effects of climate on C fluxes and soil C stocks using space-for-time substitution along a boreal forest climate gradient encompassing spatially replicated sites at each of three latitudes. All regions had similar SOC concentrations and stocks (5.6 to 6.7 kg C m(-2)). The three lowest latitude forests exhibited the highest productivity across the transect, with tree biomass:age ratios and litterfall rates 300 and 125% higher than those in the highest latitude forests, respectively. Likewise, higher soil respiration rates (similar to 55%) and dissolved organic C fluxes (similar to 300%) were observed in the lowest latitude forests compared to those in the highest latitude forests. The mid-latitude forests exhibited intermediate values for these indices and fluxes. The mean radiocarbon content (Delta C-14) of mineral-associated SOC (+9.6) was highest in the lowest latitude forests, indicating a more rapid turnover of soil C compared to the mid- and highest latitude soils (Delta C-14 of -35 and -30, respectively). Indicators of the extent of soil organic matter decomposition, including C:N, d13C, and amino acid and alkyl-C:O-alkyl-C indices, revealed highly decomposed material across all regions. These data indicate that the lowest latitude forests experience accelerated C fluxes that maintain relatively young but highly decomposed SOC. Collectively, these observations of within-biome soil C responses to climate demonstrate that the enhanced rates of SOC loss that typically occur with warming can be balanced on decadal to centennial time scales by enhanced rates of C inputs.
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