Autonomous oceanic primary production measurements through novel chlorophyll fluorometry
Phytoplankton Primary Production (PP) is a key index of marine ecosystem function, setting the constraint on energy flux to the marine biosphere. Extreme under-sampling limits confidence in our best estimates of the magnitude, variability, and drivers of such variability in PP. The current work intr...
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University of Southampton
2023
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ftsouthampton:oai:eprints.soton.ac.uk:484428 2023-12-17T10:50:34+01:00 Autonomous oceanic primary production measurements through novel chlorophyll fluorometry Wright, Alan Stanley 2023-11 text https://eprints.soton.ac.uk/484428/ https://eprints.soton.ac.uk/484428/1/ASW_Thesis_FINAL.pdf https://eprints.soton.ac.uk/484428/2/Final_thesis_submission_Examination_Mr_Alan_Wright.pdf en English eng University of Southampton https://eprints.soton.ac.uk/484428/1/ASW_Thesis_FINAL.pdf https://eprints.soton.ac.uk/484428/2/Final_thesis_submission_Examination_Mr_Alan_Wright.pdf Wright, Alan Stanley (2023) Autonomous oceanic primary production measurements through novel chlorophyll fluorometry. University of Southampton, Doctoral Thesis, 247pp. uos_thesis Thesis NonPeerReviewed 2023 ftsouthampton 2023-11-23T23:20:00Z Phytoplankton Primary Production (PP) is a key index of marine ecosystem function, setting the constraint on energy flux to the marine biosphere. Extreme under-sampling limits confidence in our best estimates of the magnitude, variability, and drivers of such variability in PP. The current work introduces, assesses, and demonstrates a new active chlorophyll fluorescence measurement sensor, developed by Chelsea Technologies Group (CTG), the STAFES (Single Turnover Active Fluorometry of Enclosed Samples). These sensors measure a range of primary production parameters, based on Electron Transport Rate (ETR), and contain 7 measurement LEDS, compared to 2 on earlier versions of single turnover active fluorometers. They are designed to operate continuously and autonomously making them Marine Autonomous System (MAS) deployable. Such deployments have the potential to greatly improve confidence and crucially, spatio-temporal scales of ETR derived parameters, and PP. As a precursor to in situ deployment, the residual error inherent in STAFES, post spectral correction was investigated over a range of assumed and measured phytoplankton absorption spectra. These analyses were performed using a series of hypothetical calculations using idealised underwater light fields generated with the HYDROLIGHT radiative transfer model, with calculations subsequently used to produce global scale residual error estimates. Overall residual errors in the upper water column (i.e. at or above the 50% light depth) remained modest even in the most productive regions where they were highest. Hence using a 7-wavelength instrument such as STAFES and then performing spectral corrections, results in the residual error already being reduced to a level where other sources of measurement error and uncertainties in algorithms will likely dominate. The STAFES sensor potential was demonstrated by performing a series of experiments in the South East (SE) Pacific sector of the Southern Ocean. Results provided new insight into the effects of iron (Fe) and ... Thesis Southern Ocean University of Southampton: e-Prints Soton Pacific Southern Ocean |
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University of Southampton: e-Prints Soton |
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ftsouthampton |
language |
English |
description |
Phytoplankton Primary Production (PP) is a key index of marine ecosystem function, setting the constraint on energy flux to the marine biosphere. Extreme under-sampling limits confidence in our best estimates of the magnitude, variability, and drivers of such variability in PP. The current work introduces, assesses, and demonstrates a new active chlorophyll fluorescence measurement sensor, developed by Chelsea Technologies Group (CTG), the STAFES (Single Turnover Active Fluorometry of Enclosed Samples). These sensors measure a range of primary production parameters, based on Electron Transport Rate (ETR), and contain 7 measurement LEDS, compared to 2 on earlier versions of single turnover active fluorometers. They are designed to operate continuously and autonomously making them Marine Autonomous System (MAS) deployable. Such deployments have the potential to greatly improve confidence and crucially, spatio-temporal scales of ETR derived parameters, and PP. As a precursor to in situ deployment, the residual error inherent in STAFES, post spectral correction was investigated over a range of assumed and measured phytoplankton absorption spectra. These analyses were performed using a series of hypothetical calculations using idealised underwater light fields generated with the HYDROLIGHT radiative transfer model, with calculations subsequently used to produce global scale residual error estimates. Overall residual errors in the upper water column (i.e. at or above the 50% light depth) remained modest even in the most productive regions where they were highest. Hence using a 7-wavelength instrument such as STAFES and then performing spectral corrections, results in the residual error already being reduced to a level where other sources of measurement error and uncertainties in algorithms will likely dominate. The STAFES sensor potential was demonstrated by performing a series of experiments in the South East (SE) Pacific sector of the Southern Ocean. Results provided new insight into the effects of iron (Fe) and ... |
format |
Thesis |
author |
Wright, Alan Stanley |
spellingShingle |
Wright, Alan Stanley Autonomous oceanic primary production measurements through novel chlorophyll fluorometry |
author_facet |
Wright, Alan Stanley |
author_sort |
Wright, Alan Stanley |
title |
Autonomous oceanic primary production measurements through novel chlorophyll fluorometry |
title_short |
Autonomous oceanic primary production measurements through novel chlorophyll fluorometry |
title_full |
Autonomous oceanic primary production measurements through novel chlorophyll fluorometry |
title_fullStr |
Autonomous oceanic primary production measurements through novel chlorophyll fluorometry |
title_full_unstemmed |
Autonomous oceanic primary production measurements through novel chlorophyll fluorometry |
title_sort |
autonomous oceanic primary production measurements through novel chlorophyll fluorometry |
publisher |
University of Southampton |
publishDate |
2023 |
url |
https://eprints.soton.ac.uk/484428/ https://eprints.soton.ac.uk/484428/1/ASW_Thesis_FINAL.pdf https://eprints.soton.ac.uk/484428/2/Final_thesis_submission_Examination_Mr_Alan_Wright.pdf |
geographic |
Pacific Southern Ocean |
geographic_facet |
Pacific Southern Ocean |
genre |
Southern Ocean |
genre_facet |
Southern Ocean |
op_relation |
https://eprints.soton.ac.uk/484428/1/ASW_Thesis_FINAL.pdf https://eprints.soton.ac.uk/484428/2/Final_thesis_submission_Examination_Mr_Alan_Wright.pdf Wright, Alan Stanley (2023) Autonomous oceanic primary production measurements through novel chlorophyll fluorometry. University of Southampton, Doctoral Thesis, 247pp. |
op_rights |
uos_thesis |
_version_ |
1785575455798067200 |