Satellites for long-term monitoring of inland U.S. lakes: The MERIS time series and application for chlorophyll-a

Lakes and other surface fresh waterbodies provide drinking water, recreational and economic opportunities, food, and other critical support for humans, aquatic life, and ecosystem health. Lakes are also productive ecosystems that provide habitats and influence global cycles. Chlorophyll concentratio...

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Vydáno v:	Remote sensing of environment Ročník 266; s. 112685 - 14
Hlavní autoři:	Seegers, Bridget N., Werdell, P. Jeremy, Vandermeulen, Ryan A., Salls, Wilson, Stumpf, Richard P., Schaeffer, Blake A., Owens, Tommy J., Bailey, Sean W., Scott, Joel P., Loftin, Keith A.
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	Goddard Space Flight Center Elsevier Inc 01.12.2021 Elsevier Elsevier BV
Témata:	Abbreviations Alaska Algorithm validation Algorithms Aquatic ecosystems Aquatic organisms Case studies Chlorophyll Chlorophylla Cyanobacteria Drinking water Earth Resources And Remote Sensing environment environmental health Imaging spectrometers Inland waters Lakes MERIS timeseries Phytoplankton radiometry Remote sensing Satellites spectrometers stakeholders surface water Time series time series analysis Water monitoring Water quality Water quality management Water quality monitoring United States > US Alaska MERIS timeseries Algorithm validation Chlorophylla Remote sensing Water quality Inland waters Algorithm Validation Remote Sensing Inland Waters Meris Timeseries Water Quality
ISSN:	0034-4257, 1879-0704
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Abstract	Lakes and other surface fresh waterbodies provide drinking water, recreational and economic opportunities, food, and other critical support for humans, aquatic life, and ecosystem health. Lakes are also productive ecosystems that provide habitats and influence global cycles. Chlorophyll concentration provides a common metric of water quality, and is frequently used as a proxy for lake trophic state. Here, we document the generation and distribution of the complete MEdium Resolution Imaging Spectrometer (MERIS; Appendix A provides a complete list of abbreviations) radiometric time series for over 2300 satellite resolvable inland bodies of water across the contiguous United States (CONUS) and more than 5,000 in Alaska. This contribution greatly increases the ease of use of satellite remote sensing data for inland water quality monitoring, as well as highlights new horizons in inland water remote sensing algorithm development. We evaluate the performance of satellite remote sensing Cyanobacteria Index (CI)-based chlorophyll algorithms, the retrievals for which provide surrogate estimates of phytoplankton concentrations in cyanobacteria dominated lakes. Our analysis quantifies the algorithms' abilities to assess lake trophic state across the CONUS. As a case study, we apply a bootstrapping approach to derive a new CI-to-chlorophyll relationship, ChlBS, which performs relatively well with a multiplicative bias of 1.11 (11%) and mean absolute error of 1.60 (60%). While the primary contribution of this work is the distribution of the MERIS radiometric timeseries, we provide this case study as a roadmap for future stakeholders' algorithm development activities, as well as a tool to assess the strengths and weaknesses of applying a single algorithm across CONUS. •Timeseries data set was developed of satellite remote sensing of US inland waters.•The dataset includes radiometry and an estimation of cyanobacteria abundance.•The dataset is public and easily modifiable for a variety of end-user applications.•A case study on algorithm development to estimate cyanoHAB chlorophyll is presented.•This case study provides steps for end-user algorithm development.
AbstractList	Lakes and other surface fresh waterbodies provide drinking water, recreational and economic opportunities, food, and other critical support for humans, aquatic life, and ecosystem health. Lakes are also productive ecosystems that provide habitats and influence global cycles. Chlorophyll concentration provides a common metric of water quality, and is frequently used as a proxy for lake trophic state. Here, we document the generation and distribution of the complete MEdium Resolution Imaging Spectrometer (MERIS; Appendix A provides a complete list of abbreviations) radiometric time series for over 2300 satellite resolvable inland bodies of water across the contiguous United States (CONUS) and more than 5,000 in Alaska. This contribution greatly increases the ease of use of satellite remote sensing data for inland water quality monitoring, as well as highlights new horizons in inland water remote sensing algorithm development. We evaluate the performance of satellite remote sensing Cyanobacteria Index (CI)-based chlorophyll algorithms, the retrievals for which provide surrogate estimates of phytoplankton concentrations in cyanobacteria dominated lakes. Our analysis quantifies the algorithms' abilities to assess lake trophic state across the CONUS. As a case study, we apply a bootstrapping approach to derive a new CI-to-chlorophyll relationship, ChlBS, which performs relatively well with a multiplicative bias of 1.11 (11%) and mean absolute error of 1.60 (60%). While the primary contribution of this work is the distribution of the MERIS radiometric timeseries, we provide this case study as a roadmap for future stakeholders' algorithm development activities, as well as a tool to assess the strengths and weaknesses of applying a single algorithm across CONUS. Lakes and other surface fresh waterbodies provide drinking water, recreational and economic opportunities, food, and other critical support for humans, aquatic life, and ecosystem health. Lakes are also productive ecosystems that provide habitats and influence global cycles. Chlorophyll concentration provides a common metric of water quality, and is frequently used as a proxy for lake trophic state. Here, we document the generation and distribution of the complete MEdium Resolution Imaging Spectrometer (MERIS; Appendix A provides a complete list of abbreviations) radiometric time series for over 2300 satellite resolvable inland bodies of water across the contiguous United States (CONUS) and more than 5,000 in Alaska. This contribution greatly increases the ease of use of satellite remote sensing data for inland water quality monitoring, as well as highlights new horizons in inland water remote sensing algorithm development. We evaluate the performance of satellite remote sensing Cyanobacteria Index (CI)-based chlorophyll algorithms, the retrievals for which provide surrogate estimates of phytoplankton concentrations in cyanobacteria dominated lakes. Our analysis quantifies the algorithms' abilities to assess lake trophic state across the CONUS. As a case study, we apply a bootstrapping approach to derive a new CI-to-chlorophyll relationship, ChlBS, which performs relatively well with a multiplicative bias of 1.11 (11%) and mean absolute error of 1.60 (60%). While the primary contribution of this work is the distribution of the MERIS radiometric timeseries, we provide this case study as a roadmap for future stakeholders' algorithm development activities, as well as a tool to assess the strengths and weaknesses of applying a single algorithm across CONUS. •Timeseries data set was developed of satellite remote sensing of US inland waters.•The dataset includes radiometry and an estimation of cyanobacteria abundance.•The dataset is public and easily modifiable for a variety of end-user applications.•A case study on algorithm development to estimate cyanoHAB chlorophyll is presented.•This case study provides steps for end-user algorithm development. Lakes and other surface fresh waterbodies provide drinking water, recreational and economic opportunities, food, and other critical support for humans, aquatic life, and ecosystem health. Lakes are also productive ecosystems that provide habitats and influence global cycles. Chlorophyll concentration provides a common metric of water quality, and is frequently used as a proxy for lake trophic state. Here, we document the generation and distribution of the complete MEdium Resolution Imaging Spectrometer (MERIS; Appendix A provides a complete list of abbreviations) radiometric time series for over 2300 satellite resolvable inland bodies of water across the contiguous United States (CONUS) and more than 5,000 in Alaska. This contribution greatly increases the ease of use of satellite remote sensing data for inland water quality monitoring, as well as highlights new horizons in inland water remote sensing algorithm development. We evaluate the performance of satellite remote sensing Cyanobacteria Index (CI)-based chlorophyll algorithms, the retrievals for which provide surrogate estimates of phytoplankton concentrations in cyanobacteria dominated lakes. Our analysis quantifies the algorithms' abilities to assess lake trophic state across the CONUS. As a case study, we apply a bootstrapping approach to derive a new CI-to-chlorophyll relationship, ChlBS, which performs relatively well with a multiplicative bias of 1.11 (11%) and mean absolute error of 1.60 (60%). While the primary contribution of this work is the distribution of the MERIS radiometric timeseries, we provide this case study as a roadmap for future stakeholders' algorithm development activities, as well as a tool to assess the strengths and weaknesses of applying a single algorithm across CONUS.Lakes and other surface fresh waterbodies provide drinking water, recreational and economic opportunities, food, and other critical support for humans, aquatic life, and ecosystem health. Lakes are also productive ecosystems that provide habitats and influence global cycles. Chlorophyll concentration provides a common metric of water quality, and is frequently used as a proxy for lake trophic state. Here, we document the generation and distribution of the complete MEdium Resolution Imaging Spectrometer (MERIS; Appendix A provides a complete list of abbreviations) radiometric time series for over 2300 satellite resolvable inland bodies of water across the contiguous United States (CONUS) and more than 5,000 in Alaska. This contribution greatly increases the ease of use of satellite remote sensing data for inland water quality monitoring, as well as highlights new horizons in inland water remote sensing algorithm development. We evaluate the performance of satellite remote sensing Cyanobacteria Index (CI)-based chlorophyll algorithms, the retrievals for which provide surrogate estimates of phytoplankton concentrations in cyanobacteria dominated lakes. Our analysis quantifies the algorithms' abilities to assess lake trophic state across the CONUS. As a case study, we apply a bootstrapping approach to derive a new CI-to-chlorophyll relationship, ChlBS, which performs relatively well with a multiplicative bias of 1.11 (11%) and mean absolute error of 1.60 (60%). While the primary contribution of this work is the distribution of the MERIS radiometric timeseries, we provide this case study as a roadmap for future stakeholders' algorithm development activities, as well as a tool to assess the strengths and weaknesses of applying a single algorithm across CONUS. Lakes and other surface fresh waterbodies provide drinking water, recreational and economic opportunities, food, and other critical support for humans, aquatic life, and ecosystem health. Lakes are also productive ecosystems that provide habitats and influence global cycles. Chlorophyll concentration provides a common metric of water quality, and is frequently used as a proxy for lake trophic state. Here, we document the generation and distribution of the complete MEdium Resolution Imaging Spectrometer (MERIS; Appendix A provides a complete list of abbreviations) radiometric time series for over 2300 satellite resolvable inland bodies of water across the contiguous United States (CONUS) and more than 5,000 in Alaska. This contribution greatly increases the ease of use of satellite remote sensing data for inland water quality monitoring, as well as highlights new horizons in inland water remote sensing algorithm development. We evaluate the performance of satellite remote sensing Cyanobacteria Index (CI)-based chlorophyll lgorithms, the retrievals for which provide surrogate estimates of phytoplankton concentrations in cyanobacteria dominated lakes. Our analysis quantifies the algorithms' abilities to assess lake trophic state across the CONUS. As a case study, we apply a bootstrapping approach to derive a new CI-to-chlorophyll relationship, Chl , which performs relatively well with a multiplicative bias of 1.11 (11%) and mean absolute error of 1.60 (60%). While the primary contribution of this work is the distribution of the MERIS radiometric timeseries, we provide this case study as a roadmap for future stakeholders' algorithm development activities, as well as a tool to assess the strengths and weaknesses of applying a single algorithm across CONUS.
ArticleNumber	112685
Audience	PUBLIC
Author	Owens, Tommy J. Seegers, Bridget N. Bailey, Sean W. Werdell, P. Jeremy Vandermeulen, Ryan A. Salls, Wilson Schaeffer, Blake A. Scott, Joel P. Loftin, Keith A. Stumpf, Richard P.
AuthorAffiliation	d U.S. Environmental Protection Agency, Office of Research and Development, Durham, NC 27711, USA a NASA Goddard Space Flight Center, Ocean Ecology Laboratory, Greenbelt, MD 20771, USA c Science Systems and Applications Inc., Lanham, MD 20706, USA f Science Application International Corp., Reston, VA 20190, USA e NOAA, National Ocean Service, Silver Spring, MD 20910,USA g U.S. Geological Survey, Kansas Water Science Center, Lawrence, KS 66049, USA b Universities Space Research Association (USRA), Columbia, MD 21046, USA
AuthorAffiliation_xml	– name: g U.S. Geological Survey, Kansas Water Science Center, Lawrence, KS 66049, USA – name: a NASA Goddard Space Flight Center, Ocean Ecology Laboratory, Greenbelt, MD 20771, USA – name: f Science Application International Corp., Reston, VA 20190, USA – name: b Universities Space Research Association (USRA), Columbia, MD 21046, USA – name: c Science Systems and Applications Inc., Lanham, MD 20706, USA – name: d U.S. Environmental Protection Agency, Office of Research and Development, Durham, NC 27711, USA – name: e NOAA, National Ocean Service, Silver Spring, MD 20910,USA
Author_xml	– sequence: 1 givenname: Bridget N. surname: Seegers fullname: Seegers, Bridget N. email: bridget.n.seegers@nasa.gov organization: NASA Goddard Space Flight Center, Ocean Ecology Laboratory, Greenbelt, MD 20771, USA – sequence: 2 givenname: P. Jeremy surname: Werdell fullname: Werdell, P. Jeremy email: jeremy.werdell@nasa.gov organization: NASA Goddard Space Flight Center, Ocean Ecology Laboratory, Greenbelt, MD 20771, USA – sequence: 3 givenname: Ryan A. surname: Vandermeulen fullname: Vandermeulen, Ryan A. email: ryan.a.vandermeulen@nasa.gov organization: NASA Goddard Space Flight Center, Ocean Ecology Laboratory, Greenbelt, MD 20771, USA – sequence: 4 givenname: Wilson surname: Salls fullname: Salls, Wilson email: salls.wilson@epa.gov organization: U.S. Environmental Protection Agency, Office of Research and Development, Durham, NC 27711, USA – sequence: 5 givenname: Richard P. surname: Stumpf fullname: Stumpf, Richard P. email: richard.stumpf@noaa.gov organization: NOAA, National Ocean Service, Silver Spring, MD 20910,USA – sequence: 6 givenname: Blake A. surname: Schaeffer fullname: Schaeffer, Blake A. email: Schaeffer.Blake@epa.gov organization: U.S. Environmental Protection Agency, Office of Research and Development, Durham, NC 27711, USA – sequence: 7 givenname: Tommy J. surname: Owens fullname: Owens, Tommy J. email: tommy.owens@nasa.gov organization: NASA Goddard Space Flight Center, Ocean Ecology Laboratory, Greenbelt, MD 20771, USA – sequence: 8 givenname: Sean W. surname: Bailey fullname: Bailey, Sean W. email: sean.w.bailey@nasa.gov organization: NASA Goddard Space Flight Center, Ocean Ecology Laboratory, Greenbelt, MD 20771, USA – sequence: 9 givenname: Joel P. surname: Scott fullname: Scott, Joel P. email: joel.scott@nasa.gov organization: NASA Goddard Space Flight Center, Ocean Ecology Laboratory, Greenbelt, MD 20771, USA – sequence: 10 givenname: Keith A. surname: Loftin fullname: Loftin, Keith A. email: kloftin@usgs.gov organization: U.S. Geological Survey, Kansas Water Science Center, Lawrence, KS 66049, USA
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Keywords	MERIS timeseries Algorithm validation Chlorophylla Remote sensing Water quality Inland waters Algorithm Validation Remote Sensing Inland Waters Meris Timeseries Water Quality
Language	English
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PQID	2600348371
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PublicationDate	2021-12-01
PublicationDateYYYYMMDD	2021-12-01
PublicationDate_xml	– month: 12 year: 2021 text: 2021-12-01 day: 01
PublicationDecade	2020
PublicationPlace	Goddard Space Flight Center
PublicationPlace_xml	– name: Goddard Space Flight Center – name: United States – name: New York
PublicationTitle	Remote sensing of environment
PublicationTitleAlternate	Remote Sens Environ
PublicationYear	2021
Publisher	Elsevier Inc Elsevier Elsevier BV
Publisher_xml	– name: Elsevier Inc – name: Elsevier – name: Elsevier BV
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Snippet	Lakes and other surface fresh waterbodies provide drinking water, recreational and economic opportunities, food, and other critical support for humans, aquatic...
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StartPage	112685
SubjectTerms	Abbreviations Alaska Algorithm validation Algorithms Aquatic ecosystems Aquatic organisms Case studies Chlorophyll Chlorophylla Cyanobacteria Drinking water Earth Resources And Remote Sensing environment environmental health Imaging spectrometers Inland waters Lakes MERIS timeseries Phytoplankton radiometry Remote sensing Satellites spectrometers stakeholders surface water Time series time series analysis Water monitoring Water quality Water quality management Water quality monitoring
Title	Satellites for long-term monitoring of inland U.S. lakes: The MERIS time series and application for chlorophyll-a
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