Hydrography-Driven Optical Domains in the Vaigat-Disko Bay and Godthabsfjord: Effects of Glacial Meltwater Discharge

Hydrography-Driven Optical Domains in the Vaigat-Disko Bay and Godthabsfjord: Effects of Glacial Meltwater Discharge

We present here an assessment of in situ hyperspectral bio-optical variability in the Vaigat-Disko Bay and Godthabsfjord along the southwest coast of Greenland. The dataset consists of state-of-the-art profiler measurements of hyperspectral apparent and inherent optical properties of water complemen...

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Bibliographic Details
Main Authors: Veloisa J. Mascarenhas, Oliver Zielinski
Format: Article
Language:English
Published: Frontiers Media S.A. 2019-06-01
Series:Frontiers in Marine Science
Subjects:
bio-optics
hyperspectral
ocean color
fjords
Greenland
closure
Online Access:https://www.frontiersin.org/article/10.3389/fmars.2019.00335/full
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spelling doaj-0aac07f0720c49e39afa6062968b025b2020-11-25T01:56:44ZengFrontiers Media S.A.Frontiers in Marine Science2296-77452019-06-01610.3389/fmars.2019.00335444044Hydrography-Driven Optical Domains in the Vaigat-Disko Bay and Godthabsfjord: Effects of Glacial Meltwater DischargeVeloisa J. Mascarenhas0Oliver Zielinski1Oliver Zielinski2Center for Marine Sensors, Institute for Chemistry and Biology of the Marine Environment, University of Oldenburg, Wilhelmshaven, GermanyCenter for Marine Sensors, Institute for Chemistry and Biology of the Marine Environment, University of Oldenburg, Wilhelmshaven, GermanyGerman Research Center for Artificial Intelligence (DFKI), RG Marine Perception, Oldenburg, GermanyWe present here an assessment of in situ hyperspectral bio-optical variability in the Vaigat-Disko Bay and Godthabsfjord along the southwest coast of Greenland. The dataset consists of state-of-the-art profiler measurements of hyperspectral apparent and inherent optical properties of water complemented by traditional observations of Secchi disk and Forel Ule scale in the context of ocean color. Water samples were collected and analyzed for concentration of optically active constituents (OACs). Near-surface observations of hydrographic parameters revealed three different water masses in the Bay: meltwater plume, frontal zone, and Atlantic water mass. Underwater spectral light availability reveals three different spectral types. Low salinity, increased temperature, deep euphotic depths, and case-1 water type remote sensing reflectance spectra with tabletop peaks in the 400–500 nm wavelength range characterize the glacial meltwater plume in the Vaigat-Disko Bay. The conservative relationship between salinity and chromophoric dissolved organic matter (CDOM) commonly observed in estuarine and shelf seas is weaker in the Godthabsfjord and reverses in the Vaigat-Disko Bay. Efficiency of machine learning techniques such as cluster analysis is tested in delineating water masses in the bay w.r.t. hydrographic and bio-optical parameters. Tests of optical closure yield low root mean square error at longer wavelengths. The study provides strong evidence that despite similar geographic setting, fjord ecosystems exhibit contrasting bio-optical properties which necessitate fjord-specific investigations.https://www.frontiersin.org/article/10.3389/fmars.2019.00335/fullbio-opticshyperspectralocean colorfjordsGreenlandclosure
collection DOAJ
language English
format Article
sources DOAJ
author Veloisa J. Mascarenhas
Oliver Zielinski
Oliver Zielinski
spellingShingle Veloisa J. Mascarenhas
Oliver Zielinski
Oliver Zielinski
Hydrography-Driven Optical Domains in the Vaigat-Disko Bay and Godthabsfjord: Effects of Glacial Meltwater Discharge
Frontiers in Marine Science
bio-optics
hyperspectral
ocean color
fjords
Greenland
closure
author_facet Veloisa J. Mascarenhas
Oliver Zielinski
Oliver Zielinski
author_sort Veloisa J. Mascarenhas
title Hydrography-Driven Optical Domains in the Vaigat-Disko Bay and Godthabsfjord: Effects of Glacial Meltwater Discharge
title_short Hydrography-Driven Optical Domains in the Vaigat-Disko Bay and Godthabsfjord: Effects of Glacial Meltwater Discharge
title_full Hydrography-Driven Optical Domains in the Vaigat-Disko Bay and Godthabsfjord: Effects of Glacial Meltwater Discharge
title_fullStr Hydrography-Driven Optical Domains in the Vaigat-Disko Bay and Godthabsfjord: Effects of Glacial Meltwater Discharge
title_full_unstemmed Hydrography-Driven Optical Domains in the Vaigat-Disko Bay and Godthabsfjord: Effects of Glacial Meltwater Discharge
title_sort hydrography-driven optical domains in the vaigat-disko bay and godthabsfjord: effects of glacial meltwater discharge
publisher Frontiers Media S.A.
series Frontiers in Marine Science
issn 2296-7745
publishDate 2019-06-01
description We present here an assessment of in situ hyperspectral bio-optical variability in the Vaigat-Disko Bay and Godthabsfjord along the southwest coast of Greenland. The dataset consists of state-of-the-art profiler measurements of hyperspectral apparent and inherent optical properties of water complemented by traditional observations of Secchi disk and Forel Ule scale in the context of ocean color. Water samples were collected and analyzed for concentration of optically active constituents (OACs). Near-surface observations of hydrographic parameters revealed three different water masses in the Bay: meltwater plume, frontal zone, and Atlantic water mass. Underwater spectral light availability reveals three different spectral types. Low salinity, increased temperature, deep euphotic depths, and case-1 water type remote sensing reflectance spectra with tabletop peaks in the 400–500 nm wavelength range characterize the glacial meltwater plume in the Vaigat-Disko Bay. The conservative relationship between salinity and chromophoric dissolved organic matter (CDOM) commonly observed in estuarine and shelf seas is weaker in the Godthabsfjord and reverses in the Vaigat-Disko Bay. Efficiency of machine learning techniques such as cluster analysis is tested in delineating water masses in the bay w.r.t. hydrographic and bio-optical parameters. Tests of optical closure yield low root mean square error at longer wavelengths. The study provides strong evidence that despite similar geographic setting, fjord ecosystems exhibit contrasting bio-optical properties which necessitate fjord-specific investigations.
topic bio-optics
hyperspectral
ocean color
fjords
Greenland
closure
url https://www.frontiersin.org/article/10.3389/fmars.2019.00335/full
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AT oliverzielinski hydrographydrivenopticaldomainsinthevaigatdiskobayandgodthabsfjordeffectsofglacialmeltwaterdischarge
AT oliverzielinski hydrographydrivenopticaldomainsinthevaigatdiskobayandgodthabsfjordeffectsofglacialmeltwaterdischarge
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