Biogeosciences (Aug 2024)

Implications of climate and litter quality for simulations of litterbag decomposition at high latitudes

  • E. R. Aas,
  • E. R. Aas,
  • E. R. Aas,
  • I. Althuizen,
  • H. Tang,
  • H. Tang,
  • S. Geange,
  • E. Lieungh,
  • V. Vandvik,
  • T. K. Berntsen,
  • T. K. Berntsen

DOI
https://doi.org/10.5194/bg-21-3789-2024
Journal volume & issue
Vol. 21
pp. 3789 – 3817

Abstract

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Litter decomposition is a vital part of the carbon cycle and is thoroughly studied both in the field and with models. Although temporally and spatially limited, litterbag decomposition experiments are often used to calibrate and evaluate soil models, coupled to land models, that are intended for use on large scales. We used the microbially explicit soil decomposition model MIMICS+ to replicate two high-latitude litterbag decomposition experiments of different spatial and temporal scales. We investigated how well the model represented observed mass loss in terms of the controlling factors of climate and litter quality and their relative importance with time. In addition to default model forcing, we used measured and site-specific model-derived microclimatic variables (soil moisture and temperature), hypothesizing that this would improve model results. We found that MIMICS+ represented mass loss after 1, 3, and 6 years well across a climatic gradient of Canadian sites but had more variable results for 1-year mass loss across a climate grid in southern Norway. In terms of litter quality, the litter metabolic fraction had more influence on modeled mass loss than the carbon-to-nitrogen ratio of the litter. Using alternative microclimate sources led to up to 23 % more mass remaining and down to 22 % less mass remaining compared to the simulations using default model inputs. None of the input alternatives significantly improved results compared to using the default model setup. We discuss possible causes for our findings and suggest measures to better utilize short-term field experiments to inform microbially explicit decomposition models.