Improved wetland soil organic carbon stocks of the conterminous U.S. through data harmonization.

Bergit Uhran,Camille L Stagg,Amanda M Nahlik,Lisamarie Windham-Myers,Eric T Sundquist,Norman Bliss

doi:10.3389/fsoil.2021.706701

Bergit Uhran, Camille L Stagg + Show 4 more

Open Access

https://doi.org/10.3389/fsoil.2021.706701

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Abstract

Wetland soil stocks are important global repositories of carbon (C) but are difficult to quantify and model due to varying sampling protocols, and geomorphic/spatio-temporal discontinuity. Merging scales of soil-survey spatial extents with wetland-specific point-based data offers an explicit, empirical and updatable improvement for regional and continental scale soil C stock assessments. Agency-collected and community-contributed soil datasets were compared for representativeness and bias, with the goal of producing a harmonized national map of wetland soil C stocks with error quantification for wetland areas of the conterminous United States (CONUS) identified by the USGS National Landcover Change Dataset. This allowed an empirical predictive model of SOC density to be applied across the entire CONUS using relational %OC distribution alone. A broken-stick quantile-regression model identified %OC with its relatively high analytical confidence as a key predictor of SOC density in soil segments; soils less than 6% OC (hereafter, mineral wetland soils, 85% of the dataset) had a strong linear relationship of %OC to SOC density (RMSE = 0.0059, ~4% mean RMSE) and soils greater than 6% OC (organic wetland soils, 15% of the dataset) had virtually no predictive relationship of %OC to SOC density (RMSE = 0.0348 g C cm-3, ~56% mean RMSE). Disaggregation by vegetation type, or region did not alter the breakpoint significantly (6% OC) nor improve model accuracies for inland and tidal wetlands. Similarly, SOC stocks in tidal wetlands were related to %OC, but without a mappable product for disaggregation to improve accuracy by soil class, region or depth. Our layered, harmonized CONUS wetland soil maps revised wetland SOC stock estimates downward by 24% (9.5 vs. 12.5Pg C) with the overestimation being entirely an issue of inland, organic wetland soils, (35% lower than SSURGO-derived SOC stocks). Further, SSURGO underestimated soil carbon stocks at depth, as modeled wetland SOC stocks for organic-rich soils showed significant preservation downcore in the NWCA dataset (<3% loss between 0-30 cm and 30-100 cm depths) in contrast to mineral-rich soils (37% downcore stock loss). Future CONUS wetland soil C assessments will benefit from focused attention on improved organic wetland soil measurements, land history, and spatial representativeness.

Highlights

Wetland soils represent approximately one third of soil organic carbon (SOC) stored globally [∼500 Pg C, [1]], and one quarter of total carbon stored in terrestrial ecosystems, despite covering only 3% of global land area (∼5–10 M km2)
conterminous US (CONUS) wetland soils were mapped at 30 m resolution in layers for each 10 cm depth increment down to 100 cm
The most parsimonious model split CONUS wetlands into only two geographic zones: “inland” wetlands and “tidal” wetlands based on physical location associated with a spatial inland/tidal boundary identified by Holmquist et al [35]

Summary

Introduction

Wetland soils represent approximately one third of soil organic carbon (SOC) stored globally [∼500 Pg C, [1]], and one quarter of total carbon stored in terrestrial ecosystems, despite covering only 3% of global land area (∼5–10 M km). Despite the importance and vulnerability of terrestrial wetland carbon as a resource, confidence in wetland SOC profiles and stocks remains low due to inconsistencies among data quality and representativeness. We assess the distributions and uncertainties in national scale-products to produce a harmonized CONUS map of wetland SOC stocks. We do this using percent organic carbon by weight (%OC) alone, because it is a widely measured, analytically confident parameter with strong predictive value for a large majority of soil samples e.g. We do this using percent organic carbon by weight (%OC) alone, because it is a widely measured, analytically confident parameter with strong predictive value for a large majority of soil samples e.g. [16]

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Discussion

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