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Integrating plant-soil interactions into global carbon cycle models

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Integrating plant-soil interactions into global carbon cycle models. / Ostle, Nicholas J.; Smith, Pete; Fisher, Rosie et al.
In: Journal of Ecology, Vol. 97, No. 5, 01.09.2009, p. 851-863.

Research output: Contribution to Journal/MagazineReview articlepeer-review

Harvard

Ostle, NJ, Smith, P, Fisher, R, Ian Woodward, F, Fisher, JB, Smith, JU, Galbraith, D, Levy, P, Meir, P, McNamara, NP & Bardgett, RD 2009, 'Integrating plant-soil interactions into global carbon cycle models', Journal of Ecology, vol. 97, no. 5, pp. 851-863. https://doi.org/10.1111/j.1365-2745.2009.01547.x

APA

Ostle, N. J., Smith, P., Fisher, R., Ian Woodward, F., Fisher, J. B., Smith, J. U., Galbraith, D., Levy, P., Meir, P., McNamara, N. P., & Bardgett, R. D. (2009). Integrating plant-soil interactions into global carbon cycle models. Journal of Ecology, 97(5), 851-863. https://doi.org/10.1111/j.1365-2745.2009.01547.x

Vancouver

Ostle NJ, Smith P, Fisher R, Ian Woodward F, Fisher JB, Smith JU et al. Integrating plant-soil interactions into global carbon cycle models. Journal of Ecology. 2009 Sept 1;97(5):851-863. doi: 10.1111/j.1365-2745.2009.01547.x

Author

Ostle, Nicholas J. ; Smith, Pete ; Fisher, Rosie et al. / Integrating plant-soil interactions into global carbon cycle models. In: Journal of Ecology. 2009 ; Vol. 97, No. 5. pp. 851-863.

Bibtex

@article{f6397033326c40dbbf32723f53703d5d,
title = "Integrating plant-soil interactions into global carbon cycle models",
abstract = "1. Plant-soil interactions play a central role in the biogeochemical carbon (C), nitrogen (N) and hydrological cycles. In the context of global environmental change, they are important both in modulating the impact of climate change and in regulating the feedback of greenhouse gas emissions (CO2, CH4 and N2O) to the climate system. 2. Dynamic global vegetation models (DGVMs) represent the most advanced tools available to predict the impacts of global change on terrestrial ecosystem functions and to examine their feedbacks to climate change. The accurate representation of plant-soil interactions in these models is crucial to improving predictions of the effects of climate change on a global scale. 3. In this paper, we describe the general structure of DGVMs that use plant functional types (PFTs) classifications as a means to integrate plant-soil interactions and illustrate how models have been developed to improve the simulation of: (a) soil carbon dynamics, (b) nitrogen cycling, (c) drought impacts and (d) vegetation dynamics. For each of these, we discuss some recent advances and identify knowledge gaps. 4. We identify three ongoing challenges, requiring collaboration between the global modelling community and process ecologists. First, the need for a critical evaluation of the representation of plant-soil processes in global models; second, the need to supply and integrate knowledge into global models; third, the testing of global model simulations against large-scale multifactor experiments and data from observatory gradients. 5. Synthesis. This paper reviews how plant-soil interactions are represented in DGVMs that use PFTs and illustrates some model developments. We also identify areas of ecological understanding and experimentation needed to reduce uncertainty in future carbon coupled climate change predictions.",
keywords = "Carbon, Climate change, DGVM, Feedbacks, GCM, Models, PFT, Plant, Soil",
author = "Ostle, {Nicholas J.} and Pete Smith and Rosie Fisher and {Ian Woodward}, F. and Fisher, {Joshua B.} and Smith, {Jo U.} and David Galbraith and Peter Levy and Patrick Meir and McNamara, {Niall P.} and Bardgett, {Richard D.}",
year = "2009",
month = sep,
day = "1",
doi = "10.1111/j.1365-2745.2009.01547.x",
language = "English",
volume = "97",
pages = "851--863",
journal = "Journal of Ecology",
issn = "0022-0477",
publisher = "Blackwell-Wiley",
number = "5",

}

RIS

TY - JOUR

T1 - Integrating plant-soil interactions into global carbon cycle models

AU - Ostle, Nicholas J.

AU - Smith, Pete

AU - Fisher, Rosie

AU - Ian Woodward, F.

AU - Fisher, Joshua B.

AU - Smith, Jo U.

AU - Galbraith, David

AU - Levy, Peter

AU - Meir, Patrick

AU - McNamara, Niall P.

AU - Bardgett, Richard D.

PY - 2009/9/1

Y1 - 2009/9/1

N2 - 1. Plant-soil interactions play a central role in the biogeochemical carbon (C), nitrogen (N) and hydrological cycles. In the context of global environmental change, they are important both in modulating the impact of climate change and in regulating the feedback of greenhouse gas emissions (CO2, CH4 and N2O) to the climate system. 2. Dynamic global vegetation models (DGVMs) represent the most advanced tools available to predict the impacts of global change on terrestrial ecosystem functions and to examine their feedbacks to climate change. The accurate representation of plant-soil interactions in these models is crucial to improving predictions of the effects of climate change on a global scale. 3. In this paper, we describe the general structure of DGVMs that use plant functional types (PFTs) classifications as a means to integrate plant-soil interactions and illustrate how models have been developed to improve the simulation of: (a) soil carbon dynamics, (b) nitrogen cycling, (c) drought impacts and (d) vegetation dynamics. For each of these, we discuss some recent advances and identify knowledge gaps. 4. We identify three ongoing challenges, requiring collaboration between the global modelling community and process ecologists. First, the need for a critical evaluation of the representation of plant-soil processes in global models; second, the need to supply and integrate knowledge into global models; third, the testing of global model simulations against large-scale multifactor experiments and data from observatory gradients. 5. Synthesis. This paper reviews how plant-soil interactions are represented in DGVMs that use PFTs and illustrates some model developments. We also identify areas of ecological understanding and experimentation needed to reduce uncertainty in future carbon coupled climate change predictions.

AB - 1. Plant-soil interactions play a central role in the biogeochemical carbon (C), nitrogen (N) and hydrological cycles. In the context of global environmental change, they are important both in modulating the impact of climate change and in regulating the feedback of greenhouse gas emissions (CO2, CH4 and N2O) to the climate system. 2. Dynamic global vegetation models (DGVMs) represent the most advanced tools available to predict the impacts of global change on terrestrial ecosystem functions and to examine their feedbacks to climate change. The accurate representation of plant-soil interactions in these models is crucial to improving predictions of the effects of climate change on a global scale. 3. In this paper, we describe the general structure of DGVMs that use plant functional types (PFTs) classifications as a means to integrate plant-soil interactions and illustrate how models have been developed to improve the simulation of: (a) soil carbon dynamics, (b) nitrogen cycling, (c) drought impacts and (d) vegetation dynamics. For each of these, we discuss some recent advances and identify knowledge gaps. 4. We identify three ongoing challenges, requiring collaboration between the global modelling community and process ecologists. First, the need for a critical evaluation of the representation of plant-soil processes in global models; second, the need to supply and integrate knowledge into global models; third, the testing of global model simulations against large-scale multifactor experiments and data from observatory gradients. 5. Synthesis. This paper reviews how plant-soil interactions are represented in DGVMs that use PFTs and illustrates some model developments. We also identify areas of ecological understanding and experimentation needed to reduce uncertainty in future carbon coupled climate change predictions.

KW - Carbon

KW - Climate change

KW - DGVM

KW - Feedbacks

KW - GCM

KW - Models

KW - PFT

KW - Plant

KW - Soil

U2 - 10.1111/j.1365-2745.2009.01547.x

DO - 10.1111/j.1365-2745.2009.01547.x

M3 - Review article

AN - SCOPUS:68849093435

VL - 97

SP - 851

EP - 863

JO - Journal of Ecology

JF - Journal of Ecology

SN - 0022-0477

IS - 5

ER -