Correlation of Remotely Sensed Surface Reflectance With Forcing Variables in Six Different Estuaries

Tao, Jing; Hill, Paul S.

doi:10.1029/2019jc015336

Cited by 4 publications

(3 citation statements)

References 106 publications

(204 reference statements)

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“…Since the launch of the coastal zone color scanner in 1978, satellite observations of R rs (λ) have been used to derive biogeochemical variables (e.g., chlorophyll ([chl], mg m −3 ), spectral particulate backscattering (b bp (λ), m −1 ), spectral particulate absorption (a p (λ) m −1 ), spectral phytoplankton absorption (a ph (λ), m −1 ), and spectral dissolved organic matter absorption [a dg (λ)m −1 )]. These products have subsequently been used to quantify global net primary production [1,2], global carbon export and associated pathways for sinking (e.g., [3]), particulate organic carbon stocks [4,5], suspended particle sizes [6,7], metrics of phytoplankton community composition [8][9][10][11][12], harmful algal blooms [13][14][15], phytoplankton carbon and physiology [16,17], nitrogen fixation [18], river plumes and suspended sediment concentrations [19][20][21], dissolved organic matter concentrations [22,23], metrics of general ecological dynamics [24], and references therein, and metrics associated with climate change [25][26][27].…”

Section: Introductionmentioning

confidence: 99%

Seasonal bias in global ocean color observations

et al. 2021

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In this study, we identify a seasonal bias in the ocean color satellite-derived remote sensing reflectances ( R r s ( λ ) ; s r − 1 ) at the ocean color validation site, Marine Optical BuoY. The seasonal bias in R r s ( λ ) is present to varying degrees in all ocean color satellites examined, including the Visible Infrared Imaging Radiometer Suite, Sea-Viewing Wide Field-of-View Sensor, and Moderate Resolution Imaging Spectrometer. The relative bias in R r s has spectral dependence. Products derived from R r s ( λ ) are affected by the bias to varying degrees, with particulate backscattering varying up to 50% over a year, chlorophyll varying up to 25% over a year, and absorption from phytoplankton or dissolved material varying by up to 15%. The propagation of R r s ( λ ) bias into derived products is broadly confirmed on regional and global scales using Argo floats and data from the cloud-aerosol lidar with orthogonal polarization instrument aboard the cloud-aerosol lidar and infrared pathfinder satellite. The artifactual seasonality in ocean color is prominent in areas of low biomass (i.e., subtropical gyres) and is not easily discerned in areas of high biomass. While we have eliminated several candidates that could cause the biases in R r s ( λ ) , there are still outstanding questions regarding potential contributions from atmospheric corrections. Specifically, we provide evidence that the aquatic bidirectional reflectance distribution function may in part cause the observed seasonal bias, but this does not preclude an additional effect of the aerosol estimation. Our investigation highlights the contributions that atmospheric correction schemes can make in introducing biases in R r s ( λ ) , and we recommend more simulations to discern these influence R r s ( λ ) biases. Community efforts are needed to find the root cause of the seasonal bias because all past, present, and future data are, or will be, affected until a solution is implemented.

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Section: Introductionmentioning

confidence: 99%

Seasonal bias in global ocean color observations

et al. 2021

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“…Remote sensing techniques, such as satellite ocean color remote sensing, provide spatial distributions of surface SPM concentration in natural waters not possible with in-situ tools, with spatial resolution as high as 10 m (e.g., as with the spatial resolution of the Sentinel 2a and 2b satellites) and temporal resolution as high as one hour (e.g., Geostationary Ocean Color Imager, GOCI). Both approaches, however, are most useful when done in synergy, as remote sensing estimates of SPM require ground-truth data to insure they are unbiased, and their estimates are confined to surface water (though sub-surface dynamic may be inferred [1]).…”

Section: Introductionmentioning

confidence: 99%

An Algorithm to Estimate Suspended Particulate Matter Concentrations and Associated Uncertainties from Remote Sensing Reflectance in Coastal Environments

et al. 2020

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Suspended Particulate Matter (SPM) is a major constituent in coastal waters, involved in processes such as light attenuation, pollutant propagation, and waterways blockage. The spatial distribution of SPM is an indicator of deposition and erosion patterns in estuaries and coastal zones and a necessary input to estimate the material fluxes from the land through rivers to the sea. In-situ methods to estimate SPM provide limited spatial data in comparison to the coverage that can be obtained remotely. Ocean color remote sensing complements field measurements by providing estimates of the spatial distributions of surface SPM concentration in natural waters, with high spatial and temporal resolution. Existing methods to obtain SPM from remote sensing vary between purely empirical ones to those that are based on radiative transfer theory together with empirical inputs regarding the optical properties of SPM. Most algorithms use a single satellite band that is switched to other bands for different ranges of turbidity. The necessity to switch bands is due to the saturation of reflectance as SPM concentration increases. Here we propose a multi-band approach for SPM retrievals that also provides an estimate of uncertainty, where the latter is based on both uncertainties in reflectance and in the assumed optical properties of SPM. The approach proposed is general and can be applied to any ocean color sensor or in-situ radiometer system with red and near-infra-red bands. We apply it to six globally distributed in-situ datasets of spectral water reflectance and SPM measurements over a wide range of SPM concentrations collected in estuaries and coastal environments (the focus regions of our study). Results show good performance for SPM retrieval at all ranges of concentration. As with all algorithms, better performance may be achieved by constraining empirical assumptions to specific environments. To demonstrate the flexibility of the algorithm we apply it to a remote sensing scene from an environment with highly variable sediment concentrations.

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“…While most past studies focused on derived variables, uncertainties were high, as the use of derived variables may mask important particulate, planktonic, and dissolved contributions to long-term trends (Zheng & DiGiacomo, 2017). Rrs values themselves have been used in other estuaries to study general patterns (Tao & Hill, 2019), and ratios are the underlying metric of a major amount of ocean color algorithms (Dierssen, 2010). Thus, the Rrs approach is used in the present study for Chesapeake Bay to further discern change over time.…”

mentioning

confidence: 99%

Long‐Term Trends in Chesapeake Bay Remote Sensing Reflectance: Implications for Water Clarity

Turner

Friedrichs

2021

JGR Oceans

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Studying long-term change in water clarity in estuaries is an integral part of assessing improvements from historically polluted conditions. Light availability in estuaries is a critical driver of primary production and ecosystem health, shaping important nursery habitats such as seagrass meadows, coral reefs, and oyster reefs. Low water clarity is often concurrent with pathogens and harmful algal blooms, impacting fisheries and human health. Some of the world's estuaries have experienced widespread eutrophication and degraded water clarity, such as the Ches-

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Correlation of Remotely Sensed Surface Reflectance With Forcing Variables in Six Different Estuaries

Cited by 4 publications

References 106 publications

Seasonal bias in global ocean color observations

Seasonal bias in global ocean color observations

An Algorithm to Estimate Suspended Particulate Matter Concentrations and Associated Uncertainties from Remote Sensing Reflectance in Coastal Environments

Long‐Term Trends in Chesapeake Bay Remote Sensing Reflectance: Implications for Water Clarity

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