A Novel Low-Cost, High-Resolution Camera System for Measuring Peat Subsidence and Water Table Dynamics

A Novel Low-Cost, High-Resolution Camera System for Measuring Peat Subsidence and Water Table Dynamics

Peatlands are highly dynamic systems, able to accumulate carbon over millennia under natural conditions, but susceptible to rapid subsidence and carbon loss when drained. Short-term, seasonal and long-term peat surface elevation changes are closely linked to key peatland attributes such as water tab...

Full description

Bibliographic Details
Main Authors: Chris D. Evans, Nathan Callaghan, Adi Jaya, Alistair Grinham, Sofie Sjogersten, Susan E. Page, Mark E. Harrison, Kitso Kusin, Lip Khoon Kho, Martha Ledger, Stephanie Evers, Zak Mitchell, Jennifer Williamson, Alan D. Radbourne, A. Jonay Jovani-Sancho
Format: Article
Language:English
Published: Frontiers Media S.A. 2021-03-01
Series:Frontiers in Environmental Science
Subjects:
peatlands
subsidence
water table
carbon
indonesia
oil palm
Online Access:https://www.frontiersin.org/articles/10.3389/fenvs.2021.630752/full
id doaj-e0489166a0594b16bed5f5e91f59075e
record_format Article
collection DOAJ
language English
format Article
sources DOAJ
author Chris D. Evans
Nathan Callaghan
Adi Jaya
Alistair Grinham
Sofie Sjogersten
Susan E. Page
Mark E. Harrison
Mark E. Harrison
Kitso Kusin
Lip Khoon Kho
Martha Ledger
Stephanie Evers
Stephanie Evers
Zak Mitchell
Jennifer Williamson
Alan D. Radbourne
A. Jonay Jovani-Sancho
A. Jonay Jovani-Sancho
spellingShingle Chris D. Evans
Nathan Callaghan
Adi Jaya
Alistair Grinham
Sofie Sjogersten
Susan E. Page
Mark E. Harrison
Mark E. Harrison
Kitso Kusin
Lip Khoon Kho
Martha Ledger
Stephanie Evers
Stephanie Evers
Zak Mitchell
Jennifer Williamson
Alan D. Radbourne
A. Jonay Jovani-Sancho
A. Jonay Jovani-Sancho
A Novel Low-Cost, High-Resolution Camera System for Measuring Peat Subsidence and Water Table Dynamics
Frontiers in Environmental Science
peatlands
subsidence
water table
carbon
indonesia
oil palm
author_facet Chris D. Evans
Nathan Callaghan
Adi Jaya
Alistair Grinham
Sofie Sjogersten
Susan E. Page
Mark E. Harrison
Mark E. Harrison
Kitso Kusin
Lip Khoon Kho
Martha Ledger
Stephanie Evers
Stephanie Evers
Zak Mitchell
Jennifer Williamson
Alan D. Radbourne
A. Jonay Jovani-Sancho
A. Jonay Jovani-Sancho
author_sort Chris D. Evans
title A Novel Low-Cost, High-Resolution Camera System for Measuring Peat Subsidence and Water Table Dynamics
title_short A Novel Low-Cost, High-Resolution Camera System for Measuring Peat Subsidence and Water Table Dynamics
title_full A Novel Low-Cost, High-Resolution Camera System for Measuring Peat Subsidence and Water Table Dynamics
title_fullStr A Novel Low-Cost, High-Resolution Camera System for Measuring Peat Subsidence and Water Table Dynamics
title_full_unstemmed A Novel Low-Cost, High-Resolution Camera System for Measuring Peat Subsidence and Water Table Dynamics
title_sort novel low-cost, high-resolution camera system for measuring peat subsidence and water table dynamics
publisher Frontiers Media S.A.
series Frontiers in Environmental Science
issn 2296-665X
publishDate 2021-03-01
description Peatlands are highly dynamic systems, able to accumulate carbon over millennia under natural conditions, but susceptible to rapid subsidence and carbon loss when drained. Short-term, seasonal and long-term peat surface elevation changes are closely linked to key peatland attributes such as water table depth (WTD) and carbon balance, and may be measured remotely using satellite radar and LiDAR methods. However, field measurements of peat elevation change are spatially and temporally sparse, reliant on low-resolution manual subsidence pole measurements, or expensive sensor systems. Here we describe a novel, simple and low-cost image-based method for measuring peat surface motion and WTD using commercially available time-lapse cameras and image processing methods. Based on almost two years’ deployment of peat cameras across contrasting forested, burned, agricultural and oil palm plantation sites in Central Kalimantan, Indonesia, we show that the method can capture extremely high resolution (sub-mm) and high-frequency (sub-daily) changes in peat surface elevation over extended periods and under challenging environmental conditions. WTD measurements were of similar quality to commercially available pressure transducers. Results reveal dynamic peat elevation response to individual rain events, consistent with variations in WTD. Over the course of the relatively severe 2019 dry season, cameras in deep-drained peatlands recorded maximum peat shrinkage of over 8 cm, followed by partial rebound, leading to net annual subsidence of up to 5 cm. Sites with higher water tables, and where borehole irrigation was used to maintain soil moisture, had lower subsidence, suggesting potential to reduce subsidence through altered land-management. Given the established link between subsidence and CO2 emissions, these results have direct implications for the management of peatlands to reduce high current greenhouse gas (GHG) emissions. Camera-based sensors provide a simple, low-cost alternative to commercial elevation, WTD and GHG flux monitoring systems, suitable for deployment at scale, and in areas where existing approaches are impractical or unaffordable. If ground-based observations of peat motion can be linked to measured GHG fluxes and with satellite-based monitoring tools, this approach offers the potential for a large-scale peatland monitoring tool, suitable for identifying areas of active carbon loss, targeting climate change mitigation interventions, and evaluating intervention outcomes.
topic peatlands
subsidence
water table
carbon
indonesia
oil palm
url https://www.frontiersin.org/articles/10.3389/fenvs.2021.630752/full
work_keys_str_mv AT chrisdevans anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT nathancallaghan anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT adijaya anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT alistairgrinham anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT sofiesjogersten anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT susanepage anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT markeharrison anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT markeharrison anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT kitsokusin anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT lipkhoonkho anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT marthaledger anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT stephanieevers anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT stephanieevers anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT zakmitchell anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT jenniferwilliamson anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT alandradbourne anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT ajonayjovanisancho anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT ajonayjovanisancho anovellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT chrisdevans novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT nathancallaghan novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT adijaya novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT alistairgrinham novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT sofiesjogersten novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT susanepage novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT markeharrison novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT markeharrison novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT kitsokusin novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT lipkhoonkho novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT marthaledger novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT stephanieevers novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT stephanieevers novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT zakmitchell novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT jenniferwilliamson novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT alandradbourne novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT ajonayjovanisancho novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
AT ajonayjovanisancho novellowcosthighresolutioncamerasystemformeasuringpeatsubsidenceandwatertabledynamics
_version_ 1724208860484337664
spelling doaj-e0489166a0594b16bed5f5e91f59075e2021-03-22T11:53:41ZengFrontiers Media S.A.Frontiers in Environmental Science2296-665X2021-03-01910.3389/fenvs.2021.630752630752A Novel Low-Cost, High-Resolution Camera System for Measuring Peat Subsidence and Water Table DynamicsChris D. Evans0Nathan Callaghan1Adi Jaya2Alistair Grinham3Sofie Sjogersten4Susan E. Page5Mark E. Harrison6Mark E. Harrison7Kitso Kusin8Lip Khoon Kho9Martha Ledger10Stephanie Evers11Stephanie Evers12Zak Mitchell13Jennifer Williamson14Alan D. Radbourne15A. Jonay Jovani-Sancho16A. Jonay Jovani-Sancho17United Kingdom Centre for Ecology and Hydrology, Bangor, United KingdomUnited Kingdom Centre for Ecology and Hydrology, Bangor, United KingdomFaculty of Agriculture, University of Palangka Raya, Palangkaraya, IndonesiaSchool of Civil Engineering, The University of Queensland, Brisbane, QLD, AustraliaSchool of Biosciences, University of Nottingham, Loughborough, United KingdomSchool of Geography, Geology and the Environment, University of Leicester, Leicester, United KingdomSchool of Geography, Geology and the Environment, University of Leicester, Leicester, United KingdomCentre for Ecology and Conservation, College of Life and Environmental Sciences, University of Exeter, Penryn, United KingdomCenter for International Cooperation in Sustainable Management of Tropical Peatland (CIMTROP), University of Palangka Raya, Palangkaraya, IndonesiaPeat Ecosystem and Biodiversity Unit, Biology and Sustainability Research Division, Malaysian Palm Oil Board, Kuala Lumpur, MalaysiaSchool of Biosciences, University of Nottingham, Loughborough, United KingdomSchool of Biological and Environmental Sciences, Liverpool John Moores University, Liverpool, United Kingdom0School of Environmental and Geographical Sciences, University of Nottingham Malaysia Campus, Selangor, MalaysiaUnited Kingdom Centre for Ecology and Hydrology, Bangor, United KingdomUnited Kingdom Centre for Ecology and Hydrology, Bangor, United KingdomUnited Kingdom Centre for Ecology and Hydrology, Bangor, United KingdomUnited Kingdom Centre for Ecology and Hydrology, Bangor, United KingdomSchool of Biosciences, University of Nottingham, Loughborough, United KingdomPeatlands are highly dynamic systems, able to accumulate carbon over millennia under natural conditions, but susceptible to rapid subsidence and carbon loss when drained. Short-term, seasonal and long-term peat surface elevation changes are closely linked to key peatland attributes such as water table depth (WTD) and carbon balance, and may be measured remotely using satellite radar and LiDAR methods. However, field measurements of peat elevation change are spatially and temporally sparse, reliant on low-resolution manual subsidence pole measurements, or expensive sensor systems. Here we describe a novel, simple and low-cost image-based method for measuring peat surface motion and WTD using commercially available time-lapse cameras and image processing methods. Based on almost two years’ deployment of peat cameras across contrasting forested, burned, agricultural and oil palm plantation sites in Central Kalimantan, Indonesia, we show that the method can capture extremely high resolution (sub-mm) and high-frequency (sub-daily) changes in peat surface elevation over extended periods and under challenging environmental conditions. WTD measurements were of similar quality to commercially available pressure transducers. Results reveal dynamic peat elevation response to individual rain events, consistent with variations in WTD. Over the course of the relatively severe 2019 dry season, cameras in deep-drained peatlands recorded maximum peat shrinkage of over 8 cm, followed by partial rebound, leading to net annual subsidence of up to 5 cm. Sites with higher water tables, and where borehole irrigation was used to maintain soil moisture, had lower subsidence, suggesting potential to reduce subsidence through altered land-management. Given the established link between subsidence and CO2 emissions, these results have direct implications for the management of peatlands to reduce high current greenhouse gas (GHG) emissions. Camera-based sensors provide a simple, low-cost alternative to commercial elevation, WTD and GHG flux monitoring systems, suitable for deployment at scale, and in areas where existing approaches are impractical or unaffordable. If ground-based observations of peat motion can be linked to measured GHG fluxes and with satellite-based monitoring tools, this approach offers the potential for a large-scale peatland monitoring tool, suitable for identifying areas of active carbon loss, targeting climate change mitigation interventions, and evaluating intervention outcomes.https://www.frontiersin.org/articles/10.3389/fenvs.2021.630752/fullpeatlandssubsidencewater tablecarbonindonesiaoil palm

Similar Items