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Optical Radiometry for Ocean Climate Measurements. (2014)

Zibordi, Giuseppe.

San Diego :Elsevier Science & Technology,

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Keywords: Ocean-atmosphere interaction. ; Electronic books.

Type of Medium: Online Resource

Pages: 1 online resource (723 pages)

Edition: 1st ed.

ISBN: 9780124169944

Series Statement: Issn Series ; v.Volume 47

URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=1844195

DDC: 551.5246

Language: English

Note: Front Cover -- Experimental Methods in the Physical Sciences -- Optical Radiometry for Ocean Climate Measurements -- Copyright -- Contents -- List of Contributors -- Volumes in Series -- Foreword -- Preface -- Chapter 1 - Introduction to Optical Radiometry and Ocean Climate Measurements from Space -- Chapter 1.1 - Ocean Climate and Satellite Optical Radiometry -- 1. INTRODUCTION -- 2. GLOBAL CLIMATE OBSERVING SYSTEM REQUIREMENTS FOR ECVS AND CDRS -- 3. FROM ESSENTIAL CLIMATE VARIABLES TO CLIMATE DATA RECORDS -- 4. CONCLUSION -- REFERENCES -- Chapter 1.2 - Principles of Optical Radiometry and Measurement Uncertainty -- 1. BASICS OF RADIOMETRY -- 2. RADIOMETRIC STANDARDS AND SCALE REALIZATIONS -- 3. THE MEASUREMENT EQUATION -- 4. SUMMARY -- ACKNOWLEDGMENTS -- REFERENCES -- Chapter 2 - Satellite Radiometry -- Chapter 2.1 - Satellite Ocean Color Sensor Design Concepts and Performance Requirements -- 1. INTRODUCTION -- 2. OCEAN COLOR MEASUREMENT FUNDAMENTALS AND RELATED SCIENCE OBJECTIVES -- 3. EVOLUTION OF SCIENCE OBJECTIVES AND SENSOR REQUIREMENTS -- 4. PERFORMANCE PARAMETERS AND SPECIFICATIONS -- 5. SENSOR ENGINEERING -- 6. SUMMARY -- ACRONYMS -- SYMBOLS AND DIMENSIONS -- 7. APPENDIX. HISTORICAL SENSORS -- REFERENCES -- Chapter 2.2 - On Orbit Calibration of Ocean Color Reflective Solar Bands -- 1. INTRODUCTION -- 2. SOLAR CALIBRATION -- 3. LUNAR CALIBRATIONS -- 4. SPECTRAL CALIBRATION OF GRATING INSTRUMENTS -- 5. VICARIOUS CALIBRATION -- 6. ON-ORBIT CALIBRATION UNCERTAINTIES -- 7. COMPARISON OF UNCERTAINTIES ACROSS INSTRUMENTS -- 8. SUMMARY OF ON-ORBIT CALIBRATION -- REFERENCES -- Chapter 2.3 - Thermal Infrared Satellite Radiometers: Design and Prelaunch Characterization -- 1. INTRODUCTION -- 2. RADIOMETER DESIGN PRINCIPLES -- 3. REMOTE SENSING SYSTEMS -- 4. CALIBRATION MODEL -- 5. ON-BOARD CALIBRATION. , 6. PRE-LAUNCH CHARACTERIZATION AND CALIBRATION -- 7. CONCLUSIONS -- REFERENCES -- Chapter 2.4 - Postlaunch Calibration and Stability: Thermal Infrared Satellite Radiometers -- 1. INTRODUCTION -- 2. ON-BOARD CALIBRATION -- 3. COMPARISONS WITH REFERENCE SATELLITE SENSORS -- 4. VALIDATING GEOPHYSICAL RETRIEVALS -- 5. DISCUSSION -- 6. CONCLUSIONS -- REFERENCES -- Chapter 3 - In Situ Optical Radiometry -- Chapter 3.1 - In situ Optical Radiometry in the Visible and Near Infrared -- 1. INTRODUCTION AND HISTORY -- 2. FIELD RADIOMETER SYSTEMS -- 3. SYSTEM CALIBRATION -- 4. MEASUREMENT METHODS -- 5. ERRORS AND UNCERTAINTY ESTIMATES -- 6. APPLICATIONS -- 7. SUMMARY AND OUTLOOK -- REFERENCES -- Chapter 3.2 - Ship-Borne Thermal Infrared Radiometer Systems -- 1. INTRODUCTION AND BACKGROUND -- 2. TIR MEASUREMENT THEORY -- 3. TIR FIELD RADIOMETER DESIGN -- 4. EXAMPLES OF FRM SHIP-BORNE TIR RADIOMETER DESIGN AND DEPLOYMENTS -- 5. FUTURE DIRECTIONS -- 6. CONCLUSIONS -- ACKNOWLEDGMENTS -- REFERENCES -- Chapter 4 - Theoretical Investigations -- Chapter 4.1 - Simulation of In Situ Visible Radiometric Measurements -- 1. OVERVIEW -- 2. THE RTE AND ITS SOLUTION METHODS -- 3. SIMULATIONS OF IN SITU RADIOMETRIC MEASUREMENT PERTURBATIONS -- 4. SUMMARY AND REMARKS -- REFERENCES -- Chapter 4.2 - Simulation of Satellite Visible, Near-Infrared, and Shortwave-Infrared Measurements -- 1. INTRODUCTION -- 2. OCEAN-ATMOSPHERIC SYSTEM -- 3. SIMULATIONS -- 4. SUMMARY -- DISCLAIMER -- REFERENCES -- Chapter 4.3 - Simulation and Inversion of Satellite Thermal Measurements -- 1. INTRODUCTION -- 2. RADIATIVE TRANSFER SIMULATION FOR THERMAL REMOTE SENSING -- 3. PROPAGATION OF THERMAL RADIATION THROUGH CLEAR SKY -- 4. SIMULATION OF INTERACTION WITH AEROSOL AND CLOUD -- 5. SIMULATION OF SURFACE EMISSION AND REFLECTION -- 6. USE OF SIMULATIONS IN THERMAL IMAGE CLASSIFICATION (CLOUD DETECTION). , 7. USE OF SIMULATIONS IN GEOPHYSICAL INVERSION (RETRIEVAL) -- 8. USE OF SIMULATIONS IN UNCERTAINTY ESTIMATION -- 9. CONCLUSION -- REFERENCES -- Chapter 5 - In Situ Measurement Strategies -- Chapter 5.1 - Requirements and Strategies for In situ Radiometry in Support of Satellite Ocean Color -- 1. INTRODUCTION -- 2. OVERVIEW OF PAST AND CURRENT FIELD-RELATED RADIOMETRIC ACTIVITIES -- 3. REQUIREMENTS AND STRATEGIES FOR FUTURE SATELLITE OCEAN-COLOR MISSIONS -- 4. SUMMARY AND WAY FORWARD -- REFERENCES -- Chapter 5.2 - Strategies for the Laboratory and Field Deployment of Ship-Borne Fiducial Reference Thermal Infrared Radiomet ... -- 1. INTRODUCTION -- 2. FIDUCIAL REFERENCE MEASUREMENTS FOR SST CDRS AND UNCERTAINTY BUDGETS -- 3. LABORATORY INTERCALIBRATION EXPERIMENTS FOR FRM SHIP-BORNE RADIOMETERS -- 4. SHIP-BORNE RADIOMETER FIELD INTERCOMPARISON EXERCISES -- 5. PROTOCOLS TO MAINTAIN THE SI TRACEABILITY OF FRM SHIP-BORNE TIR RADIOMETERS FOR SATELLITE SST VALIDATION -- 6. SUMMARY AND FUTURE PERSPECTIVES -- ACKNOWLEDGMENTS -- REFERENCES -- Chapter 6 - Assessment of Satellite Products for Climate Applications -- Chapter 6.1 - Assessment of Satellite Ocean Colour Radiometry and Derived Geophysical Products -- 1. INTRODUCTION -- 2. VALIDATION OF SATELLITE PRODUCTS -- 3. COMPARISON OF CROSS-MISSION DATA PRODUCTS -- 4. CONCLUSIONS -- ACKNOWLEDGMENTS -- REFERENCES -- Chapter 6.2 - Assessment of Long-Term Satellite Derived Sea Surface Temperature Records -- 1. INTRODUCTION -- 2. BACKGROUND -- 3. ASSESSMENT OF LONG-TERM SST DATASETS -- 4. SUMMARY AND RECOMMENDATIONS -- REFERENCES -- Index.

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Brightness temperature measured by HUTRAD radiometer at 6.8 and 10.65 GHz from March to September 2020 during the MOSAiC expedition (2023)

Rostosky, Philip ; Spreen, Gunnar ; Casal, Tânia ; [et al.]

PANGAEA

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Publication Date: 2024-04-20

Description: This datasets contains ground-based on sea-ice floe observations from the Helsinki University of Technology RADiometer (HUTRAD) at microwave frequencies 6.8 GHz 10.65 GHz and 18.7 GHz taken during Leg 3 (April - May, 2020), Leg 4 (July 2020) and Leg 5 (August - September 2020) of the MOSAiC campaign. Two types of data are provided. Raw observations of individual measurement periods (hutrad_*.dat) for leg 3 to leg 5 and calibrated brightness temperatures (HUTRAD_*.txt) for leg 3 and leg 5. The raw observations of HUTRAD (counts) are calibrated to brightness temperature using a standard two-point calibration approach by assuming a linear relation between the measurements of the cold sky and measurements at ambient temperature using a microwave absorber. Details about the data format, usage and the instrument can be found in the file Data_manual.pdf.

Keywords: Arctic; Arctic Ocean; Binary Object; Binary Object (File Size); brightness temperatures; Comment; Cruise/expedition; DATE/TIME; ELEVATION; Event label; File content; HUTRAD; IceSense; LATITUDE; LONGITUDE; Microwave Radiometer; Mosaic; MOSAiC; MOSAiC20192020; MRA; Multidisciplinary drifting Observatory for the Study of Arctic Climate; Polarstern; PS122/3; PS122/3_28-52; PS122/3_28-76; PS122/4; PS122/4_43-111; PS122/5; PS122/5_58-50; radiometer; Remote Sensing of the Seasonal Evolution of Climate-relevant Sea Ice Properties; Sea ice

Type: Dataset

Format: text/tab-separated-values, 48 data points

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The FluxEngine air–sea gas flux toolbox: simplified interface and extensions for in situ analyses and multiple sparingly soluble gases (2019)

Holding, Thomas ; Ashton, Ian G. ; Shutler, Jamie D. ; [et al.]

Copernicus Publications (EGU)

In: Ocean Science, 15 . pp. 1707-1728.

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Publication Date: 2022-01-31

Description: The flow (flux) of climate-critical gases, such as carbon dioxide (CO2), between the ocean and the atmosphere is a fundamental component of our climate and an important driver of the biogeochemical systems within the oceans. Therefore, the accurate calculation of these air–sea gas fluxes is critical if we are to monitor the oceans and assess the impact that these gases are having on Earth's climate and ecosystems. FluxEngine is an open-source software toolbox that allows users to easily perform calculations of air–sea gas fluxes from model, in situ, and Earth observation data. The original development and verification of the toolbox was described in a previous publication. The toolbox has now been considerably updated to allow for its use as a Python library, to enable simplified installation, to ensure verification of its installation, to enable the handling of multiple sparingly soluble gases, and to enable the greatly expanded functionality for supporting in situ dataset analyses. This new functionality for supporting in situ analyses includes user-defined grids, time periods and projections, the ability to reanalyse in situ CO2 data to a common temperature dataset, and the ability to easily calculate gas fluxes using in situ data from drifting buoys, fixed moorings, and research cruises. Here we describe these new capabilities and demonstrate their application through illustrative case studies. The first case study demonstrates the workflow for accurately calculating CO2 fluxes using in situ data from four research cruises from the Surface Ocean CO2 ATlas (SOCAT) database. The second case study calculates air–sea CO2 fluxes using in situ data from a fixed monitoring station in the Baltic Sea. The third case study focuses on nitrous oxide (N2O) and, through a user-defined gas transfer parameterisation, identifies that biological surfactants in the North Atlantic could suppress individual N2O sea–air gas fluxes by up to 13 %. The fourth and final case study illustrates how a dissipation-based gas transfer parameterisation can be implemented and used. The updated version of the toolbox (version 3) and all documentation is now freely available.

Type: Article , PeerReviewed , info:eu-repo/semantics/article

Format: text

DOI: 10.5194/os-15-1707-2019

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SKIM, a Candidate Satellite Mission Exploring Global Ocean Currents and Waves (2019)

Ardhuin, Fabrice ; Brandt, Peter ; Gaultier, Lucile ; [et al.]

Frontiers

In: Frontiers in Marine Science, 6 (Art.Nr. 209).

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Publication Date: 2022-01-31

Description: The Sea surface KInematics Multiscale monitoring (SKIM) satellite mission is designed to explore ocean surface current and waves. This includes tropical currents, notably the unknown patterns of divergence and their impact on the ocean heat budget near the Equator, monitoring of the emerging Arctic up to 82.5$(\circ)$N. SKIM will also make unprecedented direct measurements of strong currents, from boundary currents to the Antarctic circumpolar current, and their interaction with ocean waves with expected impacts on air-sea fluxes and extreme waves. For the first time, SKIM will directly measure the ocean surface current vector from space. The main instrument on SKIM is a Ka-band conically scanning, multi-beam Doppler radar altimeter/wave scatterometer that includes a state-of-the-art nadir beam comparable to the Poseidon-4 instrument on Sentinel 6. The well proven Doppler pulse-pair technique will give a surface drift velocity representative of the top two meters of the ocean, after subtracting a large wave-induced contribution. Horizontal velocity components will be obtained with an accuracy better than 7 cm/s for horizontal wavelengths larger than 80~km and time resolutions larger than 15 days, with a mean revisit time of 4 days for of 99\% of the global oceans. This will provide unique and innovative measurements that will further our understanding of the transports in the upper ocean layer, permanently distributing heat, carbon, plankton, and plastics. SKIM will also benefit from co-located measurements of water vapor, rain rate, sea ice concentration, and wind vectors provided by the European operational satellite MetOp-SG(B), allowing many joint analyses. SKIM is one of the two candidate satellite missions under development for ESA Earth Explorer 9. The other candidate is the Far infrared Radiation Understanding and Monitoring (FORUM). The final selection will be announced by September 2019, for a launch in the coming decade.

Type: Article , PeerReviewed

Format: text

DOI: 10.3389/fmars.2019.00209

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Global in situ Observations of Essential Climate and Ocean Variables at the Air–Sea Interface (2019)

Centurioni, Luca R. ; Turton, Jon ; Lumpkin, Rick ; [et al.]

Frontiers

In: Frontiers in Marine Science, 6 . Art.Nr. 419.

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Publication Date: 2022-01-31

Description: The air–sea interface is a key gateway in the Earth system. It is where the atmosphere sets the ocean in motion, climate/weather-relevant air–sea processes occur, and pollutants (i.e., plastic, anthropogenic carbon dioxide, radioactive/chemical waste) enter the sea. Hence, accurate estimates and forecasts of physical and biogeochemical processes at this interface are critical for sustainable blue economy planning, growth, and disaster mitigation. Such estimates and forecasts rely on accurate and integrated in situ and satellite surface observations. High-impact uses of ocean surface observations of essential ocean/climate variables (EOVs/ECVs) include (1) assimilation into/validation of weather, ocean, and climate forecast models to improve their skill, impact, and value; (2) ocean physics studies (i.e., heat, momentum, freshwater, and biogeochemical air–sea fluxes) to further our understanding and parameterization of air–sea processes; and (3) calibration and validation of satellite ocean products (i.e., currents, temperature, salinity, sea level, ocean color, wind, and waves). We review strengths and limitations, impacts, and sustainability of in situ ocean surface observations of several ECVs and EOVs. We draw a 10-year vision of the global ocean surface observing network for improved synergy and integration with other observing systems (e.g., satellites), for modeling/forecast efforts, and for a better ocean observing governance. The context is both the applications listed above and the guidelines of frameworks such as the Global Ocean Observing System (GOOS) and Global Climate Observing System (GCOS) (both co-sponsored by the Intergovernmental Oceanographic Commission of UNESCO, IOC–UNESCO; the World Meteorological Organization, WMO; the United Nations Environment Programme, UNEP; and the International Science Council, ISC). Networks of multiparametric platforms, such as the global drifter array, offer opportunities for new and improved in situ observations. Advances in sensor technology (e.g., low-cost wave sensors), high-throughput communications, evolving cyberinfrastructures, and data information systems with potential to improve the scope, efficiency, integration, and sustainability of the ocean surface observing system are explored.

Type: Article , PeerReviewed

Format: text

DOI: 10.3389/fmars.2019.00419

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Altimetry for the future: Building on 25 years of progress (2021)

Abdalla, Saleh ; Abdeh Kolahchi, Abdolnabi ; Adusumilli, Susheel ; [et al.]

In: EPIC3Advances in Space Research, ISSN: 02731177

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Publication Date: 2021-04-14

Repository Name: EPIC Alfred Wegener Institut

Type: Article , isiRev

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An ocean-colour time series for use in climate studies: The experience of the ocean-colour climate change initiative (OC-CCI) (2019)

Sathyendranath, Shubha ; Brewin, Robert J. W. ; Brockmann, Carsten ; [et al.]

MDPI

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Publication Date: 2022-05-25

Description: © The Author(s), 2019. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Sathyendranath, S., Brewin, R. J. W., Brockmann, C., Brotas, V., Calton, B., Chuprin, A., Cipollini, P., Couto, A. B., Dingle, J., Doerffer, R., Donlon, C., Dowell, M., Farman, A., Grant, M., Groom, S., Horseman, A., Jackson, T., Krasemann, H., Lavender, S., Martinez-Vicente, V., Mazeran, C., Melin, F., Moore, T. S., Muller, D., Regner, P., Roy, S., Steele, C. J., Steinmetz, F., Swinton, J., Taberner, M., Thompson, A., Valente, A., Zuhlke, M., Brando, V. E., Feng, H., Feldman, G., Franz, B. A., Frouin, R., Gould, R. W., Hooker, S. B., Kahru, M., Kratzer, S., Mitchell, B. G., Muller-Karger, F. E., Sosik, H. M., Voss, K. J., Werdell, J., & Platt, T. An ocean-colour time series for use in climate studies: The experience of the ocean-colour climate change initiative (OC-CCI). Sensors, 19(19), (2019): 4285, doi: 10.3390/s19194285.

Description: Ocean colour is recognised as an Essential Climate Variable (ECV) by the Global Climate Observing System (GCOS); and spectrally-resolved water-leaving radiances (or remote-sensing reflectances) in the visible domain, and chlorophyll-a concentration are identified as required ECV products. Time series of the products at the global scale and at high spatial resolution, derived from ocean-colour data, are key to studying the dynamics of phytoplankton at seasonal and inter-annual scales; their role in marine biogeochemistry; the global carbon cycle; the modulation of how phytoplankton distribute solar-induced heat in the upper layers of the ocean; and the response of the marine ecosystem to climate variability and change. However, generating a long time series of these products from ocean-colour data is not a trivial task: algorithms that are best suited for climate studies have to be selected from a number that are available for atmospheric correction of the satellite signal and for retrieval of chlorophyll-a concentration; since satellites have a finite life span, data from multiple sensors have to be merged to create a single time series, and any uncorrected inter-sensor biases could introduce artefacts in the series, e.g., different sensors monitor radiances at different wavebands such that producing a consistent time series of reflectances is not straightforward. Another requirement is that the products have to be validated against in situ observations. Furthermore, the uncertainties in the products have to be quantified, ideally on a pixel-by-pixel basis, to facilitate applications and interpretations that are consistent with the quality of the data. This paper outlines an approach that was adopted for generating an ocean-colour time series for climate studies, using data from the MERIS (MEdium spectral Resolution Imaging Spectrometer) sensor of the European Space Agency; the SeaWiFS (Sea-viewing Wide-Field-of-view Sensor) and MODIS-Aqua (Moderate-resolution Imaging Spectroradiometer-Aqua) sensors from the National Aeronautics and Space Administration (USA); and VIIRS (Visible and Infrared Imaging Radiometer Suite) from the National Oceanic and Atmospheric Administration (USA). The time series now covers the period from late 1997 to end of 2018. To ensure that the products meet, as well as possible, the requirements of the user community, marine-ecosystem modellers, and remote-sensing scientists were consulted at the outset on their immediate and longer-term requirements as well as on their expectations of ocean-colour data for use in climate research. Taking the user requirements into account, a series of objective criteria were established, against which available algorithms for processing ocean-colour data were evaluated and ranked. The algorithms that performed best with respect to the climate user requirements were selected to process data from the satellite sensors. Remote-sensing reflectance data from MODIS-Aqua, MERIS, and VIIRS were band-shifted to match the wavebands of SeaWiFS. Overlapping data were used to correct for mean biases between sensors at every pixel. The remote-sensing reflectance data derived from the sensors were merged, and the selected in-water algorithm was applied to the merged data to generate maps of chlorophyll concentration, inherent optical properties at SeaWiFS wavelengths, and the diffuse attenuation coefficient at 490 nm. The merged products were validated against in situ observations. The uncertainties established on the basis of comparisons with in situ data were combined with an optical classification of the remote-sensing reflectance data using a fuzzy-logic approach, and were used to generate uncertainties (root mean square difference and bias) for each product at each pixel.

Description: This work was funded by the Ocean Colour Climate Change initiative of the European Space Agency (Grant Number 4000101437/10/I-LG). We acknowledge additional funding support by NERC through the National Centre for Earth Observation (Grant Number PR140015). Additional funding from a Simons Foundation Grant (549947, SS) is also gratefully acknowledged. V.B. also acknowledges funding from the European Union’s Horizon 2020 Research and Innovation Programme grant agreement N_ 810139: Project Portugal Twinning for Innovation and Excellence in Marine Science and Earth Observation – PORTWIMS.

Keywords: ocean colour ; water-leaving radiance ; remote-sensing reflectance ; phytoplankton ; chlorophyll-a ; inherent optical properties ; Climate Change Initiative ; optical water classes ; Essential Climate Variable ; uncertainty characterisation

Repository Name: Woods Hole Open Access Server

Type: Article

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Global in situ observations of essential climate and ocean variables at the air-sea interface (2019)

Centurioni, Luca R. ; Turton, Jon ; Lumpkin, Rick ; [et al.]

Frontiers Media

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Publication Date: 2022-10-26

Description: © The Author(s), 2019. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Centurioni, L. R., Turton, J., Lumpkin, R., Braasch, L., Brassington, G., Chao, Y., Charpentier, E., Chen, Z., Corlett, G., Dohan, K., Donlon, C., Gallage, C., Hormann, V., Ignatov, A., Ingleby, B., Jensen, R., Kelly-Gerreyn, B. A., Koszalka, I. M., Lin, X., Lindstrom, E., Maximenko, N., Merchant, C. J., Minnett, P., O'Carroll, A., Paluszkiewicz, T., Poli, P., Poulain, P., Reverdin, G., Sun, X., Swail, V., Thurston, S., Wu, L., Yu, L., Wang, B., & Zhang, D. Global in situ observations of essential climate and ocean variables at the air-sea interface. Frontiers in Marine Science, 6, (2019): 419, doi: 10.3389/fmars.2019.00419.

Description: LC, LB, and VH were supported by NOAA grant NA15OAR4320071 and ONR grant N00014-17-1-2517. RL was supported by NOAA/AOML and NOAA’s Ocean Observation and Monitoring Division. NM was partly supported by NASA grant NNX17AH43G. IK was supported by the Nordic Seas Eddy Exchanges (NorSEE) funded by the Norwegian Research Council (Grant 221780). DZ was partly funded by the Joint Institute for the Study of the Atmosphere and Ocean (JISAO) under NOAA Cooperative Agreement NA15OAR4320063. RJ was supported by the USACE’s Civil Works 096×3123.

Keywords: Global in situ observations ; Air-sea interface ; Essential climate and ocean variables ; Climate variability and change ; Weather forecasting ; SVP drifters

Repository Name: Woods Hole Open Access Server

Type: Article

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