Peatland dynamics: A review of process-based models and approaches

Despite peatlands' important feedbacks on the climate and global biogeochemical cycles, predicting their dynamics involves many uncertainties and an overwhelming variety of available models. This paper reviews the most widely used process-based models for simulating peatlands' dynamics, i....

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Published in:The Science of the total environment Vol. 877; p. 162890
Main Authors: Mozafari, Behzad, Bruen, Michael, Donohue, Shane, Renou-Wilson, Florence, O'Loughlin, Fiachra
Format: Journal Article
Language:English
Published: Netherlands Elsevier B.V 15.06.2023
Subjects:
carbon
climate
Community modelling platform
computer software
energy
environment
fens
FOSS and FAIR
hydrologic cycle
nitrogen
peat
Peatland
peatlands
Physics-based models
Systematic review
terrestrial ecosystems
vegetation
NO
N/A
FAIR
Community modelling platform
LRM
GPP
WTD
CO2
GHG
FOSS
I/O
Physics-based models
Systematic review
PBIAS
NPP
MBE
NO3
FOSS and FAIR
DOC
WoS
ESM
MSE
PFT
CCA
CD
NSE
SW
POC
IPCC
LSM
KGE
N2O
RMSE
CN
CH4
RA
MAE
GW
SEB
RRMSE
RH
NH3
NH4
TEM
Peatland
ISSN:0048-9697, 1879-1026, 1879-1026
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Abstract Despite peatlands' important feedbacks on the climate and global biogeochemical cycles, predicting their dynamics involves many uncertainties and an overwhelming variety of available models. This paper reviews the most widely used process-based models for simulating peatlands' dynamics, i.e., the exchanges of energy and mass (water, carbon, and nitrogen). ‘Peatlands’ here refers to mires, fens, bogs, and peat swamps both intact and degraded. Using a systematic search (involving 4900 articles), 45 models were selected that appeared at least twice in the literature. The models were classified into four categories: terrestrial ecosystem models (biogeochemical and global dynamic vegetation models, n = 21), hydrological models (n = 14), land surface models (n = 7), and eco-hydrological models (n = 3), 18 of which featured “peatland-specific” modules. By analysing their corresponding publications (n = 231), we identified their proven applicability domains (hydrology and carbon cycles dominated) for different peatland types and climate zones (northern bogs and fens dominated). The studies range in scale from small plots to global, and from single events to millennia. Following a FOSS (Free Open-Source Software) and FAIR (Findable, Accessible, Interoperable, Reusable) assessment, the number of models was reduced to 12. Then, we conducted a technical review of the approaches and associated challenges, as well as the basic aspects of each model, e.g., spatiotemporal resolution, input/output data format and modularity. Our review streamlines the process of model selection and highlights: (i) standardization and coordination are required for both data exchange and model calibration/validation to facilitate intercomparison studies; and (ii) there are overlaps in the models' scopes and approaches, making it imperative to fully optimize the strengths of existing models rather than creating redundant ones. In this regard, we provide a futuristic outlook for a ‘peatland community modelling platform’ and suggest an international peatland modelling intercomparison project. [Display omitted] •An extensive systematic search identified many process-based models being used for peatland dynamics.•Only about a quarter of the models meet the FOSS and FAIR criteria for an open-source and active community.•It is essential to standardize model calibration/validation and data sharing.•No one-size-fits-all model exists, but the models overlap in scope and approach.•A peatland community modelling platform can optimally exploit the strengths of existing models.
AbstractList Despite peatlands' important feedbacks on the climate and global biogeochemical cycles, predicting their dynamics involves many uncertainties and an overwhelming variety of available models. This paper reviews the most widely used process-based models for simulating peatlands' dynamics, i.e., the exchanges of energy and mass (water, carbon, and nitrogen). 'Peatlands' here refers to mires, fens, bogs, and peat swamps both intact and degraded. Using a systematic search (involving 4900 articles), 45 models were selected that appeared at least twice in the literature. The models were classified into four categories: terrestrial ecosystem models (biogeochemical and global dynamic vegetation models, n = 21), hydrological models (n = 14), land surface models (n = 7), and eco-hydrological models (n = 3), 18 of which featured "peatland-specific" modules. By analysing their corresponding publications (n = 231), we identified their proven applicability domains (hydrology and carbon cycles dominated) for different peatland types and climate zones (northern bogs and fens dominated). The studies range in scale from small plots to global, and from single events to millennia. Following a FOSS (Free Open-Source Software) and FAIR (Findable, Accessible, Interoperable, Reusable) assessment, the number of models was reduced to 12. Then, we conducted a technical review of the approaches and associated challenges, as well as the basic aspects of each model, e.g., spatiotemporal resolution, input/output data format and modularity. Our review streamlines the process of model selection and highlights: (i) standardization and coordination are required for both data exchange and model calibration/validation to facilitate intercomparison studies; and (ii) there are overlaps in the models' scopes and approaches, making it imperative to fully optimize the strengths of existing models rather than creating redundant ones. In this regard, we provide a futuristic outlook for a 'peatland community modelling platform' and suggest an international peatland modelling intercomparison project.Despite peatlands' important feedbacks on the climate and global biogeochemical cycles, predicting their dynamics involves many uncertainties and an overwhelming variety of available models. This paper reviews the most widely used process-based models for simulating peatlands' dynamics, i.e., the exchanges of energy and mass (water, carbon, and nitrogen). 'Peatlands' here refers to mires, fens, bogs, and peat swamps both intact and degraded. Using a systematic search (involving 4900 articles), 45 models were selected that appeared at least twice in the literature. The models were classified into four categories: terrestrial ecosystem models (biogeochemical and global dynamic vegetation models, n = 21), hydrological models (n = 14), land surface models (n = 7), and eco-hydrological models (n = 3), 18 of which featured "peatland-specific" modules. By analysing their corresponding publications (n = 231), we identified their proven applicability domains (hydrology and carbon cycles dominated) for different peatland types and climate zones (northern bogs and fens dominated). The studies range in scale from small plots to global, and from single events to millennia. Following a FOSS (Free Open-Source Software) and FAIR (Findable, Accessible, Interoperable, Reusable) assessment, the number of models was reduced to 12. Then, we conducted a technical review of the approaches and associated challenges, as well as the basic aspects of each model, e.g., spatiotemporal resolution, input/output data format and modularity. Our review streamlines the process of model selection and highlights: (i) standardization and coordination are required for both data exchange and model calibration/validation to facilitate intercomparison studies; and (ii) there are overlaps in the models' scopes and approaches, making it imperative to fully optimize the strengths of existing models rather than creating redundant ones. In this regard, we provide a futuristic outlook for a 'peatland community modelling platform' and suggest an international peatland modelling intercomparison project.
Despite peatlands' important feedbacks on the climate and global biogeochemical cycles, predicting their dynamics involves many uncertainties and an overwhelming variety of available models. This paper reviews the most widely used process-based models for simulating peatlands' dynamics, i.e., the exchanges of energy and mass (water, carbon, and nitrogen). ‘Peatlands’ here refers to mires, fens, bogs, and peat swamps both intact and degraded. Using a systematic search (involving 4900 articles), 45 models were selected that appeared at least twice in the literature. The models were classified into four categories: terrestrial ecosystem models (biogeochemical and global dynamic vegetation models, n = 21), hydrological models (n = 14), land surface models (n = 7), and eco-hydrological models (n = 3), 18 of which featured “peatland-specific” modules. By analysing their corresponding publications (n = 231), we identified their proven applicability domains (hydrology and carbon cycles dominated) for different peatland types and climate zones (northern bogs and fens dominated). The studies range in scale from small plots to global, and from single events to millennia. Following a FOSS (Free Open-Source Software) and FAIR (Findable, Accessible, Interoperable, Reusable) assessment, the number of models was reduced to 12. Then, we conducted a technical review of the approaches and associated challenges, as well as the basic aspects of each model, e.g., spatiotemporal resolution, input/output data format and modularity. Our review streamlines the process of model selection and highlights: (i) standardization and coordination are required for both data exchange and model calibration/validation to facilitate intercomparison studies; and (ii) there are overlaps in the models' scopes and approaches, making it imperative to fully optimize the strengths of existing models rather than creating redundant ones. In this regard, we provide a futuristic outlook for a ‘peatland community modelling platform’ and suggest an international peatland modelling intercomparison project.
Despite peatlands' important feedbacks on the climate and global biogeochemical cycles, predicting their dynamics involves many uncertainties and an overwhelming variety of available models. This paper reviews the most widely used process-based models for simulating peatlands' dynamics, i.e., the exchanges of energy and mass (water, carbon, and nitrogen). 'Peatlands' here refers to mires, fens, bogs, and peat swamps both intact and degraded. Using a systematic search (involving 4900 articles), 45 models were selected that appeared at least twice in the literature. The models were classified into four categories: terrestrial ecosystem models (biogeochemical and global dynamic vegetation models, n = 21), hydrological models (n = 14), land surface models (n = 7), and eco-hydrological models (n = 3), 18 of which featured "peatland-specific" modules. By analysing their corresponding publications (n = 231), we identified their proven applicability domains (hydrology and carbon cycles dominated) for different peatland types and climate zones (northern bogs and fens dominated). The studies range in scale from small plots to global, and from single events to millennia. Following a FOSS (Free Open-Source Software) and FAIR (Findable, Accessible, Interoperable, Reusable) assessment, the number of models was reduced to 12. Then, we conducted a technical review of the approaches and associated challenges, as well as the basic aspects of each model, e.g., spatiotemporal resolution, input/output data format and modularity. Our review streamlines the process of model selection and highlights: (i) standardization and coordination are required for both data exchange and model calibration/validation to facilitate intercomparison studies; and (ii) there are overlaps in the models' scopes and approaches, making it imperative to fully optimize the strengths of existing models rather than creating redundant ones. In this regard, we provide a futuristic outlook for a 'peatland community modelling platform' and suggest an international peatland modelling intercomparison project.
Despite peatlands' important feedbacks on the climate and global biogeochemical cycles, predicting their dynamics involves many uncertainties and an overwhelming variety of available models. This paper reviews the most widely used process-based models for simulating peatlands' dynamics, i.e., the exchanges of energy and mass (water, carbon, and nitrogen). ‘Peatlands’ here refers to mires, fens, bogs, and peat swamps both intact and degraded. Using a systematic search (involving 4900 articles), 45 models were selected that appeared at least twice in the literature. The models were classified into four categories: terrestrial ecosystem models (biogeochemical and global dynamic vegetation models, n = 21), hydrological models (n = 14), land surface models (n = 7), and eco-hydrological models (n = 3), 18 of which featured “peatland-specific” modules. By analysing their corresponding publications (n = 231), we identified their proven applicability domains (hydrology and carbon cycles dominated) for different peatland types and climate zones (northern bogs and fens dominated). The studies range in scale from small plots to global, and from single events to millennia. Following a FOSS (Free Open-Source Software) and FAIR (Findable, Accessible, Interoperable, Reusable) assessment, the number of models was reduced to 12. Then, we conducted a technical review of the approaches and associated challenges, as well as the basic aspects of each model, e.g., spatiotemporal resolution, input/output data format and modularity. Our review streamlines the process of model selection and highlights: (i) standardization and coordination are required for both data exchange and model calibration/validation to facilitate intercomparison studies; and (ii) there are overlaps in the models' scopes and approaches, making it imperative to fully optimize the strengths of existing models rather than creating redundant ones. In this regard, we provide a futuristic outlook for a ‘peatland community modelling platform’ and suggest an international peatland modelling intercomparison project. [Display omitted] •An extensive systematic search identified many process-based models being used for peatland dynamics.•Only about a quarter of the models meet the FOSS and FAIR criteria for an open-source and active community.•It is essential to standardize model calibration/validation and data sharing.•No one-size-fits-all model exists, but the models overlap in scope and approach.•A peatland community modelling platform can optimally exploit the strengths of existing models.
ArticleNumber 162890
Author Donohue, Shane
Mozafari, Behzad
Bruen, Michael
O'Loughlin, Fiachra
Renou-Wilson, Florence
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  givenname: Behzad
  surname: Mozafari
  fullname: Mozafari, Behzad
  email: behzad.mozafari@ucdconnect.ie
  organization: School of Civil Engineering, UCD Earth Institute and UCD Dooge Centre for Water Resources Research, University College Dublin, Dublin 4, Ireland
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  surname: Bruen
  fullname: Bruen, Michael
  organization: School of Civil Engineering, UCD Earth Institute and UCD Dooge Centre for Water Resources Research, University College Dublin, Dublin 4, Ireland
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  givenname: Shane
  surname: Donohue
  fullname: Donohue, Shane
  organization: School of Civil Engineering and UCD Earth Institute, University College Dublin, Dublin 4, Ireland
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  givenname: Florence
  surname: Renou-Wilson
  fullname: Renou-Wilson, Florence
  organization: School of Biology and Environmental Science, Science Centre-West, University College Dublin, Dublin 4, Ireland
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  givenname: Fiachra
  surname: O'Loughlin
  fullname: O'Loughlin, Fiachra
  organization: School of Civil Engineering, UCD Earth Institute and UCD Dooge Centre for Water Resources Research, University College Dublin, Dublin 4, Ireland
BackLink https://www.ncbi.nlm.nih.gov/pubmed/36933711$$D View this record in MEDLINE/PubMed
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ISICitedReferencesURI http://www.webofscience.com/api/gateway?GWVersion=2&SrcApp=Summon&SrcAuth=ProQuest&DestLinkType=CitingArticles&DestApp=WOS_CPL&KeyUT=001019838700001&url=https%3A%2F%2Fcvtisr.summon.serialssolutions.com%2F%23%21%2Fsearch%3Fho%3Df%26include.ft.matches%3Dt%26l%3Dnull%26q%3D
ISSN 0048-9697
1879-1026
IngestDate Mon Sep 29 02:28:35 EDT 2025
Thu Oct 02 09:50:25 EDT 2025
Thu Apr 03 07:10:38 EDT 2025
Sat Nov 29 07:23:01 EST 2025
Tue Nov 18 22:22:57 EST 2025
Fri Feb 23 02:35:39 EST 2024
IsDoiOpenAccess true
IsOpenAccess true
IsPeerReviewed true
IsScholarly true
Keywords NO
N/A
FAIR
Community modelling platform
LRM
GPP
WTD
CO2
GHG
FOSS
I/O
Physics-based models
Systematic review
PBIAS
NPP
MBE
NO3
FOSS and FAIR
DOC
WoS
ESM
MSE
PFT
CCA
CD
NSE
SW
POC
IPCC
LSM
KGE
N2O
RMSE
CN
CH4
RA
MAE
GW
SEB
RRMSE
RH
NH3
NH4
TEM
Peatland
Language English
License This is an open access article under the CC BY license.
Copyright © 2023 The Authors. Published by Elsevier B.V. All rights reserved.
LinkModel OpenURL
MergedId FETCHMERGED-LOGICAL-c453t-c83dbd58eeb887f13c3905f059e2de622cb9f633c547dbd115878e0d3e9a36b13
Notes ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
ObjectType-Review-3
content type line 23
OpenAccessLink https://dx.doi.org/10.1016/j.scitotenv.2023.162890
PMID 36933711
PQID 2810914255
PQPubID 23479
ParticipantIDs proquest_miscellaneous_3040428058
proquest_miscellaneous_2810914255
pubmed_primary_36933711
crossref_citationtrail_10_1016_j_scitotenv_2023_162890
crossref_primary_10_1016_j_scitotenv_2023_162890
elsevier_sciencedirect_doi_10_1016_j_scitotenv_2023_162890
PublicationCentury 2000
PublicationDate 2023-06-15
PublicationDateYYYYMMDD 2023-06-15
PublicationDate_xml – month: 06
  year: 2023
  text: 2023-06-15
  day: 15
PublicationDecade 2020
PublicationPlace Netherlands
PublicationPlace_xml – name: Netherlands
PublicationTitle The Science of the total environment
PublicationTitleAlternate Sci Total Environ
PublicationYear 2023
Publisher Elsevier B.V
Publisher_xml – name: Elsevier B.V
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Snippet Despite peatlands' important feedbacks on the climate and global biogeochemical cycles, predicting their dynamics involves many uncertainties and an...
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SubjectTerms carbon
climate
Community modelling platform
computer software
energy
environment
fens
FOSS and FAIR
hydrologic cycle
nitrogen
peat
Peatland
peatlands
Physics-based models
Systematic review
terrestrial ecosystems
vegetation
Title Peatland dynamics: A review of process-based models and approaches
URI https://dx.doi.org/10.1016/j.scitotenv.2023.162890
https://www.ncbi.nlm.nih.gov/pubmed/36933711
https://www.proquest.com/docview/2810914255
https://www.proquest.com/docview/3040428058
Volume 877
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