Mangrove root biomass and the uncertainty of belowground carbon estimations

•Mangrove root biomass is highest in dense forests with small DBH and high interstitial salinity.•Highest biomass is reported where roots are sampled by digging trenches.•Root biomass from allometric equations are ∼40% larger than values measured in the field.•Uncertainty in root biomass corresponds...

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Published inForest ecology and management Vol. 403; pp. 52 - 60
Main Authors Adame, M. Fernanda, Cherian, Sam, Reef, Ruth, Stewart-Koster, Ben
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.11.2017
Subjects
Allometric equations
allometry
biomass
Blue carbon
carbon
Carbon stocks
climate change
environmental factors
equations
Forested wetlands
mangrove forests
roots
Salinity
soil
statistical models
trees
uncertainty
Carbon stocks
Forested wetlands
Blue carbon
Allometric equations
Salinity
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Abstract •Mangrove root biomass is highest in dense forests with small DBH and high interstitial salinity.•Highest biomass is reported where roots are sampled by digging trenches.•Root biomass from allometric equations are ∼40% larger than values measured in the field.•Uncertainty in root biomass corresponds to ∼4% of the ecosystem C stock. Mangroves sequester large amounts of carbon (C) and they are increasingly recognized for their potential role in climate change mitigation programs. However, there is uncertainty in the C content of many mangrove forests because the amount of C stored in the roots is usually estimated from allometric equations and not from direct field measurements. There are only a handful of allometric equations in mangroves that are used worldwide to estimate root biomass, however, root biomass can vary from the allometric relationship if the environmental conditions are different from those where the equation was developed. In this study, we compiled recent information on how mangrove roots are affected by environmental conditions. Then, we explored the effect of sampling methodology on root biomass estimations. Finally, we compared published values of root biomass from field measurements against our estimations from allometric equations. The goal was to calculate the uncertainty associated with the estimation of root biomass and thus, the belowground C content of mangroves. The results showed that sampling methodology has a significant effect on root biomass estimations. The highest biomass estimations are reported where both live and dead roots are measured and when the roots are sampled by digging trenches. When comparing measured values against estimations from allometric equations, on average the general allometric equation provided root biomass values that were 40±12% larger than those obtained from field measurements with cores. The result suggests that either: (a) sampling with cores largely underestimates root biomass, or (b) allometric equations overestimate root biomass when used outside the region where they were developed. The uncertainty in root biomass estimates from allometric equations corresponds to 4–15% of the ecosystem C stock (trees+soil), with higher uncertainties in forests with low tree density and low interstitial salinity. We provide a statistical model that includes salinity, forest density and root biomass to correct for this systematic bias. The estimated uncertainty is important to consider when quantifying C budgets at large spatial scales and to validate methodological approaches to C stock estimations.
AbstractList Mangroves sequester large amounts of carbon (C) and they are increasingly recognized for their potential role in climate change mitigation programs. However, there is uncertainty in the C content of many mangrove forests because the amount of C stored in the roots is usually estimated from allometric equations and not from direct field measurements. There are only a handful of allometric equations in mangroves that are used worldwide to estimate root biomass, however, root biomass can vary from the allometric relationship if the environmental conditions are different from those where the equation was developed. In this study, we compiled recent information on how mangrove roots are affected by environmental conditions. Then, we explored the effect of sampling methodology on root biomass estimations. Finally, we compared published values of root biomass from field measurements against our estimations from allometric equations. The goal was to calculate the uncertainty associated with the estimation of root biomass and thus, the belowground C content of mangroves. The results showed that sampling methodology has a significant effect on root biomass estimations. The highest biomass estimations are reported where both live and dead roots are measured and when the roots are sampled by digging trenches. When comparing measured values against estimations from allometric equations, on average the general allometric equation provided root biomass values that were 40±12% larger than those obtained from field measurements with cores. The result suggests that either: (a) sampling with cores largely underestimates root biomass, or (b) allometric equations overestimate root biomass when used outside the region where they were developed. The uncertainty in root biomass estimates from allometric equations corresponds to 4–15% of the ecosystem C stock (trees+soil), with higher uncertainties in forests with low tree density and low interstitial salinity. We provide a statistical model that includes salinity, forest density and root biomass to correct for this systematic bias. The estimated uncertainty is important to consider when quantifying C budgets at large spatial scales and to validate methodological approaches to C stock estimations.
•Mangrove root biomass is highest in dense forests with small DBH and high interstitial salinity.•Highest biomass is reported where roots are sampled by digging trenches.•Root biomass from allometric equations are ∼40% larger than values measured in the field.•Uncertainty in root biomass corresponds to ∼4% of the ecosystem C stock. Mangroves sequester large amounts of carbon (C) and they are increasingly recognized for their potential role in climate change mitigation programs. However, there is uncertainty in the C content of many mangrove forests because the amount of C stored in the roots is usually estimated from allometric equations and not from direct field measurements. There are only a handful of allometric equations in mangroves that are used worldwide to estimate root biomass, however, root biomass can vary from the allometric relationship if the environmental conditions are different from those where the equation was developed. In this study, we compiled recent information on how mangrove roots are affected by environmental conditions. Then, we explored the effect of sampling methodology on root biomass estimations. Finally, we compared published values of root biomass from field measurements against our estimations from allometric equations. The goal was to calculate the uncertainty associated with the estimation of root biomass and thus, the belowground C content of mangroves. The results showed that sampling methodology has a significant effect on root biomass estimations. The highest biomass estimations are reported where both live and dead roots are measured and when the roots are sampled by digging trenches. When comparing measured values against estimations from allometric equations, on average the general allometric equation provided root biomass values that were 40±12% larger than those obtained from field measurements with cores. The result suggests that either: (a) sampling with cores largely underestimates root biomass, or (b) allometric equations overestimate root biomass when used outside the region where they were developed. The uncertainty in root biomass estimates from allometric equations corresponds to 4–15% of the ecosystem C stock (trees+soil), with higher uncertainties in forests with low tree density and low interstitial salinity. We provide a statistical model that includes salinity, forest density and root biomass to correct for this systematic bias. The estimated uncertainty is important to consider when quantifying C budgets at large spatial scales and to validate methodological approaches to C stock estimations.
Author Reef, Ruth
Stewart-Koster, Ben
Adame, M. Fernanda
Cherian, Sam
Author_xml – sequence: 1
  givenname: M. Fernanda
  surname: Adame
  fullname: Adame, M. Fernanda
  email: f.adame@griffith.edu.au
  organization: Australian Rivers Institute, Griffith University, Nathan 4111, QLD, Australia
– sequence: 2
  givenname: Sam
  orcidid: 0000-0002-3910-278X
  surname: Cherian
  fullname: Cherian, Sam
  organization: Plant Systems Engineering Research Centre, Korea Research Institute of Bioscience and Biotechnology, Daejeon 34141, South Korea
– sequence: 3
  givenname: Ruth
  surname: Reef
  fullname: Reef, Ruth
  organization: School of Earth, Atmosphere and Environment, Monash University, Clayton 3800, VIC, Australia
– sequence: 4
  givenname: Ben
  orcidid: 0000-0001-8334-0825
  surname: Stewart-Koster
  fullname: Stewart-Koster, Ben
  organization: Australian Rivers Institute, Griffith University, Nathan 4111, QLD, Australia
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Blue carbon
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Snippet •Mangrove root biomass is highest in dense forests with small DBH and high interstitial salinity.•Highest biomass is reported where roots are sampled by...
Mangroves sequester large amounts of carbon (C) and they are increasingly recognized for their potential role in climate change mitigation programs. However,...
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SubjectTerms Allometric equations
allometry
biomass
Blue carbon
carbon
Carbon stocks
climate change
environmental factors
equations
Forested wetlands
mangrove forests
roots
Salinity
soil
statistical models
trees
uncertainty
Title Mangrove root biomass and the uncertainty of belowground carbon estimations
URI https://dx.doi.org/10.1016/j.foreco.2017.08.016
https://www.proquest.com/docview/2000536670
Volume 403
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