Capturing spatiotemporal variation in salt marsh belowground biomass, a key resilience metric, through geoinformatics

Abstract The Belowground Ecosystem Resiliency Model (BERM) is a geoinformatics tool that was developed to predict belowground biomass (BGB) of Spartina alterniflora in salt marshes based on remote sensing of aboveground characteristics and other readily available hydrologic, climatic, and physical d...

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Main Authors: Kyle D. Runion, Deepak R. Mishra, Merryl Alber, Mark A. Lever, Jessica L. O'Connell
Format: Article
Language:English
Published: Wiley 2024-12-01
Series:Ecosphere
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Online Access:https://doi.org/10.1002/ecs2.70110
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author Kyle D. Runion
Deepak R. Mishra
Merryl Alber
Mark A. Lever
Jessica L. O'Connell
author_facet Kyle D. Runion
Deepak R. Mishra
Merryl Alber
Mark A. Lever
Jessica L. O'Connell
author_sort Kyle D. Runion
collection DOAJ
description Abstract The Belowground Ecosystem Resiliency Model (BERM) is a geoinformatics tool that was developed to predict belowground biomass (BGB) of Spartina alterniflora in salt marshes based on remote sensing of aboveground characteristics and other readily available hydrologic, climatic, and physical data. We sought to characterize variation in S. alterniflora BGB over both temporal and spatial gradients through extensive marsh field observations in coastal Georgia, USA, to quantify their relationship with a suite of predictor variables, and to use these results to improve performance and expand the parameter space of BERM. We conducted pairwise comparisons of S. alterniflora growth metrics measured at nine sites over 3–8 years and found that BGB grouped by site differed in 69% of comparisons, while only in 21% when grouped by year. This suggests that BGB varies more spatially than temporally. We used the BERM machine learning algorithms to evaluate how variables relating to biological, climatic, hydrologic, and physical attributes covaried with these BGB observations. Flooding frequency and intensity were most influential in predicting BGB, with predictor variables related to hydrology composing 61% of the total feature importance in the BERM framework. When we used this expanded calibration dataset and associated predictors to advance BERM, model error was reduced from a normalized root‐mean‐square error of 13.0%–9.4% in comparison with the original BERM formulation. This reflects both an improvement in predictive performance and an expansion in conditions for potential model application. Finally, we used regression commonality analysis to show that model estimates reflected the spatiotemporal structure of BGB variation observed in field measurements. These results can help guide future data collection efforts to describe landscape‐scale BGB trends. The advanced BERM is a robust tool that can characterize S. alterniflora productivity and resilience over broad spatial and temporal scales.
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spelling doaj-art-535096bb72aa41f2b96781cb455cf0992025-01-27T14:51:33ZengWileyEcosphere2150-89252024-12-011512n/an/a10.1002/ecs2.70110Capturing spatiotemporal variation in salt marsh belowground biomass, a key resilience metric, through geoinformaticsKyle D. Runion0Deepak R. Mishra1Merryl Alber2Mark A. Lever3Jessica L. O'Connell4Department of Marine Science University of Texas at Austin Port Aransas Texas USADepartment of Geography University of Georgia Athens Georgia USADepartment of Marine Sciences University of Georgia Athens Georgia USADepartment of Marine Science University of Texas at Austin Port Aransas Texas USADepartment of Ecosystem Science & Sustainability Colorado State University Fort Collins Colorado USAAbstract The Belowground Ecosystem Resiliency Model (BERM) is a geoinformatics tool that was developed to predict belowground biomass (BGB) of Spartina alterniflora in salt marshes based on remote sensing of aboveground characteristics and other readily available hydrologic, climatic, and physical data. We sought to characterize variation in S. alterniflora BGB over both temporal and spatial gradients through extensive marsh field observations in coastal Georgia, USA, to quantify their relationship with a suite of predictor variables, and to use these results to improve performance and expand the parameter space of BERM. We conducted pairwise comparisons of S. alterniflora growth metrics measured at nine sites over 3–8 years and found that BGB grouped by site differed in 69% of comparisons, while only in 21% when grouped by year. This suggests that BGB varies more spatially than temporally. We used the BERM machine learning algorithms to evaluate how variables relating to biological, climatic, hydrologic, and physical attributes covaried with these BGB observations. Flooding frequency and intensity were most influential in predicting BGB, with predictor variables related to hydrology composing 61% of the total feature importance in the BERM framework. When we used this expanded calibration dataset and associated predictors to advance BERM, model error was reduced from a normalized root‐mean‐square error of 13.0%–9.4% in comparison with the original BERM formulation. This reflects both an improvement in predictive performance and an expansion in conditions for potential model application. Finally, we used regression commonality analysis to show that model estimates reflected the spatiotemporal structure of BGB variation observed in field measurements. These results can help guide future data collection efforts to describe landscape‐scale BGB trends. The advanced BERM is a robust tool that can characterize S. alterniflora productivity and resilience over broad spatial and temporal scales.https://doi.org/10.1002/ecs2.70110Belowground Ecosystem Resiliency Modelclimate changeGeorgia coastmachine learningproductivityremote sensing
spellingShingle Kyle D. Runion
Deepak R. Mishra
Merryl Alber
Mark A. Lever
Jessica L. O'Connell
Capturing spatiotemporal variation in salt marsh belowground biomass, a key resilience metric, through geoinformatics
Ecosphere
Belowground Ecosystem Resiliency Model
climate change
Georgia coast
machine learning
productivity
remote sensing
title Capturing spatiotemporal variation in salt marsh belowground biomass, a key resilience metric, through geoinformatics
title_full Capturing spatiotemporal variation in salt marsh belowground biomass, a key resilience metric, through geoinformatics
title_fullStr Capturing spatiotemporal variation in salt marsh belowground biomass, a key resilience metric, through geoinformatics
title_full_unstemmed Capturing spatiotemporal variation in salt marsh belowground biomass, a key resilience metric, through geoinformatics
title_short Capturing spatiotemporal variation in salt marsh belowground biomass, a key resilience metric, through geoinformatics
title_sort capturing spatiotemporal variation in salt marsh belowground biomass a key resilience metric through geoinformatics
topic Belowground Ecosystem Resiliency Model
climate change
Georgia coast
machine learning
productivity
remote sensing
url https://doi.org/10.1002/ecs2.70110
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