Abstract
The deposition of suspended sediment is an important process that helps wetlands accrete surface material and maintain elevation in the face of sea level rise. Optical remote sensing is often employed to map total suspended solids (TSS), though algorithms typically have limited transferability in space and time due to variability in water constituent compositions, mixtures, and inherent optical properties. This study used in situ spectral reflectances and their first derivatives to compare empirical algorithms for estimating TSS using hyperspectral and multispectral data. These algorithms were applied to imagery collected by NASA’s Airborne Visible/Infrared Imaging Spectrometer-Next Generation (AVIRIS-NG) over coastal Louisiana, USA, and validated with a multiyear in situ dataset. The best performing models were then applied to independent spectroscopic data collected in the Peace–Athabasca Delta, Canada, and the San Francisco Bay–Delta Estuary, USA, to assess their robustness and transferability. A derivative-based partial least squares regression (PLSR) model applied to simulated AVIRIS-NG data showed the most accurate TSS retrievals (R2 = 0.83) in these contrasting deltaic environments. These results highlight the potential for a more broadly applicable generalized algorithm employing imaging spectroscopy for estimating suspended solids.
Highlights
Coastal wetlands provide many ecosystem services that are compromised when relative sea level rise (RSLR) rates, resulting from the combination of eustatic sea level rise and land subsidence, exceed accretion rates [1]
Our results suggest that this approach may be broadly applicable for a variety of turbid deltaic and estuarine water bodies with total suspended solids (TSS) values up to approximately 110 mg/L
This study successfully developed and validated an imaging spectroscopy method to estimate
Summary
Coastal wetlands provide many ecosystem services that are compromised when relative sea level rise (RSLR) rates, resulting from the combination of eustatic sea level rise and land subsidence, exceed accretion rates [1]. Wetland accretion in dynamic coastal settings is controlled by a combination of organic matter production and sediment capture, together producing accretion rates matching. While vegetation biomass and productivity contribute to accretion via organic matter accumulation, exogenic mineral suspended sediment is delivered to wetlands from external sources. Subsidence rates in alluvial wetlands are often exacerbated by local groundwater withdrawal, hydrocarbon extraction, surficial sediment dewatering, and tectonic activity, they are most impacted by a reduced mineral sediment input [3,4]. Louisiana’s coastal wetlands provide an example of how alterations in sediment supply can impact a marsh’s ability to maintain surface elevation that can keep pace with RSLR.
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