Incorporating microbial dormancy dynamics into soil decomposition models to improve quantification of soil carbon dynamics of northern temperate forests

He, Yujie; Yang, Jinyan; Zhuang, Qianlai; Harden, Jennifer W.; McGuire, A. David; Liu, Yaling; Wang, Gangsheng; Gu, Lianhong

doi:10.1002/2015jg003130

Cited by 35 publications

(52 citation statements)

References 46 publications

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“…Dormant microbes still need a minimum of energy for maintenance, albeit at a much lower rate compared that of active microbes (Lennon and 20 Jones, 2011). The maintenance respiration coefficient of dormant microbes is set to be a ratio b (between 0 and 1) of that of active microbes (Wang et al, 2014;He et al, 2015). The maintenance respiration thus can be described by Eq.…”

Section: Maintenance Respirationmentioning

confidence: 99%

“…The maintenance respiration of MFTs (bacteria and fungi) is modelled as a fixed ratio (maintenance respiration coefficient) of their biomass (Schimel & Weintraub, 2003;Lawrence et al, 2009;Allison et al, 2010;Wang et al, 2014;He et al, 2015) modulated by temperature using an Arrhenius equation following Tang and Riley (2015) (Eq. 36).…”

Section: Maintenance Respirationmentioning

confidence: 99%

“…For 10 instance, only active microbes are involved in decomposing SOC (Blagodatskaya and Kuzyakov, 2013) and in producing enzymes (He et al, 2015). However, with 80 % of microbial cells typically being dormant in soils, dormancy is the most common state of microbial communities (Lennon and Jones, 2011).…”

Section: Introductionmentioning

confidence: 99%

“…Recently, new models have included the effects of microbial dynamics on SOC decomposition, but not always with an explicit representation of microbial processes (Schimel and Weintraub, 2003;Moorhead and Sinsabaugh, 2006;Lawrence et al, 2009;Wang et al, 2013;Wieder et al, 2014;Kaiser et al, 2014Kaiser et al, , 2015He et al, 2015). In those models, SOC decomposition is mediated by 30 soil enzymes released by microorganisms (Allison et al, 2010;Schimel and Weintraub, 2003;Lawrence et al, 2009;).…”

Section: Introductionmentioning

confidence: 99%

“…CC BY 4.0 License. the production of enzymes in models is typically modelled as a fixed fraction of total microbial biomass (Allison et al, 2010;He et al, 2015) or as a fixed fraction of the uptake of C or N (Schimel and Weintraub, 2003;Kaiser et al, 2014Kaiser et al, , 2015.…”

Section: Introductionmentioning

confidence: 99%

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ORCHIMIC (v1.0), a microbe-driven model for soil organic matter decomposition designed for large-scale applications

Huang

Guenet

Ciais

et al. 2018

Preprint

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Abstract. The role of soil microorganisms in regulating soil organic matter (SOM) decomposition is of primary importance in the carbon cycle, and in particular in the context of global change. Modelling soil microbial community dynamics to simulate its impact on soil gaseous carbon (C) emissions and nitrogen (N) mineralization at large spatial scales is a recent research field with the potential to improve predictions of SOM responses to global climate change. We here present a SOM 15 model called ORCHIMIC whose input data that are consistent with those of global vegetation models. The model simulates decomposition of SOM by explicitly accounting for enzyme production and distinguishing three different microbial functional groups: fresh organic matter (FOM) specialists, SOM specialists, and generalists, while implicitly also accounting for microbes that do not produce extracellular enzymes, i.e. cheaters. This ORCHIMIC model and two other organic matter decomposition models, CENTURY (based on first order kinetics and representative for the structure of most current global 20 soil carbon models) and PRIM (with FOM accelerating the decomposition rate of SOM) were calibrated to reproduce the observed respiration fluxes from FOM and SOM and their possible interactions from incubation experiments of Blagodatskaya et al. (2014). Among the three models, ORCHIMIC was the only one that captured well both the temporal dynamics of the respiratory fluxes and the magnitude of the priming effect observed during the incubation experiment.ORCHIMIC also reproduced well the temporal dynamics of microbial biomass. We then applied different idealized changes 25 to the model input data, i.e. a 5 K stepwise increase of temperature and/or a doubling of plant litter inputs. Under 5 K warming, ORCHIMIC predicted a 0.002 K -1 decrease in the C use efficiency (defined as the ratio of C allocated to microbial growth to the sum of C allocated to growth and respiration) and a 3 % loss of SOC. Under the double litter input scenario, ORCHIMIC predicted a doubling of microbial biomass, while SOC stock increased by less than 1 % due to the priming effect. This limited increase in SOC stock contrasted with the proportional increase in SOC stock as modelled by the 30 conventional SOC decomposition model (CENTURY), which cannot reproduce the priming effect. If temperature increased by 5 K and litter input is doubled, the model predicted almost the same loss of SOC as when only temperature was increased.These tests suggest that the responses of SOC stock to warming and increasing input may differ a lot from those simulated

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Section: Maintenance Respirationmentioning

confidence: 99%

Section: Maintenance Respirationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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ORCHIMIC (v1.0), a microbe-driven model for soil organic matter decomposition designed for large-scale applications

Huang

Guenet

Ciais

et al. 2018

Preprint

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A parsimonious modular approach to building a mechanistic belowground carbon and nitrogen model

2017

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Soil decomposition models range from simple empirical functions to those that represent physical, chemical, and biological processes. Here we develop a parsimonious, modular C and N cycle model, the Dual Arrhenius Michaelis-Menten-Microbial Carbon and Nitrogen Phyisology (DAMM-MCNiP), that generates testable hypotheses regarding the effect of temperature, moisture, and substrate supply on C and N cycling. We compared this model to DAMM alone and an empirical model of heterotrophic respiration based on Harvard Forest data. We show that while different model structures explain similar amounts of variation in respiration, they differ in their ability to infer processes that affect C flux. We applied DAMM-MCNiP to explain an observed seasonal hysteresis in the relationship between respiration and temperature and show using an exudation simulation that the strength of the priming effect depended on the stoichiometry of the inputs. Low C:N inputs stimulated priming of soil organic matter decomposition, but high C:N inputs were preferentially utilized by microbes as a C source with limited priming. The simplicity of DAMM-MCNiP's simultaneous representations of temperature, moisture, substrate supply, enzyme activity, and microbial growth processes is unique among microbial physiology models and is sufficiently parsimonious that it could be incorporated into larger-scale models of C and N cycling.Plain Language Summary Microorganisms that grow in the soil, like bacteria and fungi, affect how much carbon resides in the soil and how much is released to the atmosphere as CO 2 . Mathematical models used to make climate change predictions often struggle to capture the activity of soil microbes in realistic ways. This study uses well-established descriptions of water and temperature effects on soil microbes to predict rate of carbon and nitrogen cycling in the soil. Our new model reproduces the changing relationship between temperature and microbial respiration during the growing season. We also show using a theoretical addition of root secretions that the microbial response depends on the nitrogen content of the added plant material. This model is simple and based on well defined physical and biological properties, and could be developed to model microbial activity at larger scales.

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Modeling Microbial Dynamics and Heterotrophic Soil Respiration

Abs

Ferrière

2020

Geophysical Monograph Series

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Incorporating microbial dormancy dynamics into soil decomposition models to improve quantification of soil carbon dynamics of northern temperate forests

Cited by 35 publications

References 46 publications

ORCHIMIC (v1.0), a microbe-driven model for soil organic matter decomposition designed for large-scale applications

ORCHIMIC (v1.0), a microbe-driven model for soil organic matter decomposition designed for large-scale applications

A parsimonious modular approach to building a mechanistic belowground carbon and nitrogen model

Modeling Microbial Dynamics and Heterotrophic Soil Respiration

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