Simulating Global Terrestrial Carbon and Nitrogen Biogeochemical Cycles With Implicit and Explicit Representations of Soil Microbial Activity

William R. Wieder; Melannie D. Hartman; Emily Kyker‐Snowman; Brooke Eastman; Katerina Georgiou; Derek Pierson; Katherine S. Rocci; A. Stuart Grandy

doi:10.1029/2023MS004156

Journal of Advances in Modeling Earth Systems (Jun 2024)

Simulating Global Terrestrial Carbon and Nitrogen Biogeochemical Cycles With Implicit and Explicit Representations of Soil Microbial Activity

William R. Wieder,
Melannie D. Hartman,
Emily Kyker‐Snowman,
Brooke Eastman,
Katerina Georgiou,
Derek Pierson,
Katherine S. Rocci,
A. Stuart Grandy

Affiliations

William R. Wieder: Climate and Global Dynamics Laboratory National Center for Atmospheric Research Boulder CO USA
Melannie D. Hartman: Climate and Global Dynamics Laboratory National Center for Atmospheric Research Boulder CO USA
Emily Kyker‐Snowman: Carbon Direct New York NY USA
Brooke Eastman: Division of Forestry and Natural Resources West Virginia University Morgantown WV USA
Katerina Georgiou: Physical and Life Sciences Directorate Lawrence Livermore National Laboratory Livermore CA USA
Derek Pierson: Rocky Mountain Research Station United States Forest Service Boise ID USA
Katherine S. Rocci: Institute of Arctic and Alpine Research University of Colorado Boulder CO USA
A. Stuart Grandy: Department of Natural Resources and the Environment University of New Hampshire Durham NH USA

DOI: https://doi.org/10.1029/2023MS004156
Journal volume & issue: Vol. 16, no. 6
pp. n/a – n/a

Abstract

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Abstract Nutrient limitation is widespread in terrestrial ecosystems. Accordingly, representations of nitrogen (N) limitation in land models typically dampen rates of terrestrial carbon (C) accrual, compared with C‐only simulations. These previous findings, however, rely on soil biogeochemical models that implicitly represent microbial activity and physiology. Here we present results from a biogeochemical model testbed that allows us to investigate how an explicit versus implicit representation of soil microbial activity, as represented in the MIcrobial‐MIneral Carbon Stabilization (MIMICS) and Carnegie‐Ames‐Stanford Approach (CASA) soil biogeochemical models, respectively, influence plant productivity, and terrestrial C and N fluxes at initialization and over the historical period. When forced with common boundary conditions, larger soil C pools simulated by the MIMICS model reflect longer inferred soil organic matter (SOM) turnover times than those simulated by CASA. At steady state, terrestrial ecosystems experience greater N limitation when using the MIMICS‐CN model, which also increases the inferred SOM turnover time. Over the historical period, however, warming‐induced acceleration of SOM decomposition over high latitude ecosystems increases rates of N mineralization in MIMICS‐CN. This reduces N limitation and results in faster rates of vegetation C accrual. Moreover, as SOM stoichiometry is an emergent property of MIMICS‐CN, we highlight opportunities to deepen understanding of sources of persistent SOM and explore its potential sensitivity to environmental change. Our findings underscore the need to improve understanding and representation of plant and microbial resource allocation and competition in land models that represent coupled biogeochemical cycles under global change scenarios.

Published in Journal of Advances in Modeling Earth Systems

ISSN: 1942-2466 (Online)
Publisher: American Geophysical Union (AGU)
Country of publisher: United States
LCC subjects: Geography. Anthropology. Recreation: Physical geography; Geography. Anthropology. Recreation: Oceanography
Website: https://agupubs.onlinelibrary.wiley.com/journal/19422466

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