Underway Data from R/V Melville, R/V Roger Revelle cruises MV1101, RR1202 in the Southern Ocean (30-60S); 2011-2012 (Great Calcite Belt project)

<p>Along track temperature, Salinity, backscatter, Chlorophyll Fluoresence, and normalized water leaving radiance (nLw).<br /> <br /> On the bow of the vessel was a Satlantic SeaWiFS Aircraft Simulator (MicroSAS) system, used to estimate water-leaving radiance from the ship, analog...

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Main Author: William M. Balch
Format: Dataset
Language:unknown
Published: Biological and Chemical Oceanography Data Management Office (BCO-DMO) 2015
Subjects:
Online Access:https://search.dataone.org/view/sha256:895e9481a1a68ac8a69fc8efc5d5eb0fa797432da97dae46b726439e7ffd578e
id dataone:sha256:895e9481a1a68ac8a69fc8efc5d5eb0fa797432da97dae46b726439e7ffd578e
record_format openpolar
institution Open Polar
collection Biological and Chemical Oceanography Data Management Office (BCO-DMO) (via DataONE)
op_collection_id dataone:urn:node:BCODMO
language unknown
topic oceans
spellingShingle oceans
William M. Balch
Underway Data from R/V Melville, R/V Roger Revelle cruises MV1101, RR1202 in the Southern Ocean (30-60S); 2011-2012 (Great Calcite Belt project)
topic_facet oceans
description <p>Along track temperature, Salinity, backscatter, Chlorophyll Fluoresence, and normalized water leaving radiance (nLw).<br /> <br /> On the bow of the vessel was a Satlantic SeaWiFS Aircraft Simulator (MicroSAS) system, used to estimate water-leaving radiance from the ship, analogous to to the nLw derived by the SeaWiFS and MODIS satellite sensors, but free from atmospheric error (hence, it can provide data below clouds).<br /> <br /> The system consisted of a down-looking radiance sensor and a sky-viewing radiance sensor, both mounted on a steerable holder on the bow. A downwelling irradiance sensor was mounted at the top of the ship's meterological mast, on the bow, far from any potentially shading structures. These data were used to estimate normalized water-leaving radiance as a function of wavelength. The radiance detector was set to view the water at 40deg from nadir as recommended by Mueller et al. [2003b]. The water radiance sensor was able to view over an azimuth range of ~180deg across the ship's heading with no viewing of the ship's wake. The direction of the sensor was adjusted to view the water 90-120deg from the sun's azimuth, to minimize sun glint. This was continually adjusted as the time and ship's gyro heading were used to calculate the sun's position using an astronomical solar position subroutine interfaced with a stepping motor which was attached to the radiometer mount (designed and fabricated at Bigelow Laboratory for Ocean Sciences). Protocols for operation and calibration were performed according to Mueller [Mueller et al., 2003a; Mueller et al., 2003b; Mueller et al., 2003c]. Before 1000h and after 1400h, data quality was poorer as the solar zenith angle was too low. Post-cruise, the 10Hz data were filtered to remove as much residual white cap and glint as possible (we accept the lowest 5% of the data). Reflectance plaque measurements were made several times at local apparent noon on sunny days to verify the radiometer calibrations.<br /> <br /> Within an hour of local apparent noon each day, a Satlantic OCP sensor was deployed off the stern of the vessel after the ship oriented so that the sun was off the stern. The ship would secure the starboard Z-drive, and use port Z-drive and bow thruster to move the ship ahead at about 25cm s-1. The OCP was then trailed aft and brought to the surface ~100m aft of the ship, then allowed to sink to 100m as downwelling spectral irradiance and upwelling spectral radiance were recorded continuously along with temperature and salinity. This procedure ensured there were no ship shadow effects in the radiometry.<br /> <br /> Instruments include a WETLabs wetstar fluorometer, a WETLabs ECOTriplet and a SeaBird microTSG.<br /> Radiometry was done using a Satlantic 7 channel microSAS system with Es, Lt and Li sensors.<br /> <br /> Chl data is based on inter calibrating surface discrete Chlorophyll measure with the temporally closest fluorescence measurement and applying the regression results to all fluorescence data.<br /> <br /> Data have been corrected for instrument biofouling and drift based on weekly purewater calibrations of the system. Radiometric data has been processed using standard Satlantic processing software and has been checked with periodic plaque measurements using a 2% spectralon standard.</p> <p>Lw is calculated from Lt and Lsky and is \"what Lt would be if the<br /> sensor were looking straight down\". Since our sensors are mounted at<br /> 40o, based on various NASA protocols, we need to do that conversion.<br /> <br /> Lwn adds Es to the mix. Es is used to normalize Lw. Nlw is related to Rrs, Remote Sensing Reflectance</p> <p><strong>Techniques used are as described in:</strong><br /> Balch WM, Drapeau DT, Bowler BC, Booth ES, Windecker LA, Ashe A (2008) Space–time variability of carbon standing stocks and fixation rates in the Gulf of Maine, along the GNATS transect between Portland, ME, USA, and Yarmouth, Nova Scotia, Canada.<br /> J Plankton Res 30:119–139</p>
format Dataset
author William M. Balch
author_facet William M. Balch
author_sort William M. Balch
title Underway Data from R/V Melville, R/V Roger Revelle cruises MV1101, RR1202 in the Southern Ocean (30-60S); 2011-2012 (Great Calcite Belt project)
title_short Underway Data from R/V Melville, R/V Roger Revelle cruises MV1101, RR1202 in the Southern Ocean (30-60S); 2011-2012 (Great Calcite Belt project)
title_full Underway Data from R/V Melville, R/V Roger Revelle cruises MV1101, RR1202 in the Southern Ocean (30-60S); 2011-2012 (Great Calcite Belt project)
title_fullStr Underway Data from R/V Melville, R/V Roger Revelle cruises MV1101, RR1202 in the Southern Ocean (30-60S); 2011-2012 (Great Calcite Belt project)
title_full_unstemmed Underway Data from R/V Melville, R/V Roger Revelle cruises MV1101, RR1202 in the Southern Ocean (30-60S); 2011-2012 (Great Calcite Belt project)
title_sort underway data from r/v melville, r/v roger revelle cruises mv1101, rr1202 in the southern ocean (30-60s); 2011-2012 (great calcite belt project)
publisher Biological and Chemical Oceanography Data Management Office (BCO-DMO)
publishDate 2015
url https://search.dataone.org/view/sha256:895e9481a1a68ac8a69fc8efc5d5eb0fa797432da97dae46b726439e7ffd578e
long_lat ENVELOPE(-63.967,-63.967,-65.250,-65.250)
ENVELOPE(55.533,55.533,-66.917,-66.917)
geographic Balch
Canada
Mueller
Southern Ocean
geographic_facet Balch
Canada
Mueller
Southern Ocean
genre Southern Ocean
genre_facet Southern Ocean
_version_ 1814741183273893888
spelling dataone:sha256:895e9481a1a68ac8a69fc8efc5d5eb0fa797432da97dae46b726439e7ffd578e 2024-11-03T19:45:37+00:00 Underway Data from R/V Melville, R/V Roger Revelle cruises MV1101, RR1202 in the Southern Ocean (30-60S); 2011-2012 (Great Calcite Belt project) William M. Balch 2015-06-08T00:00:00Z https://search.dataone.org/view/sha256:895e9481a1a68ac8a69fc8efc5d5eb0fa797432da97dae46b726439e7ffd578e unknown Biological and Chemical Oceanography Data Management Office (BCO-DMO) oceans Dataset 2015 dataone:urn:node:BCODMO 2024-11-03T19:08:36Z <p>Along track temperature, Salinity, backscatter, Chlorophyll Fluoresence, and normalized water leaving radiance (nLw).<br /> <br /> On the bow of the vessel was a Satlantic SeaWiFS Aircraft Simulator (MicroSAS) system, used to estimate water-leaving radiance from the ship, analogous to to the nLw derived by the SeaWiFS and MODIS satellite sensors, but free from atmospheric error (hence, it can provide data below clouds).<br /> <br /> The system consisted of a down-looking radiance sensor and a sky-viewing radiance sensor, both mounted on a steerable holder on the bow. A downwelling irradiance sensor was mounted at the top of the ship's meterological mast, on the bow, far from any potentially shading structures. These data were used to estimate normalized water-leaving radiance as a function of wavelength. The radiance detector was set to view the water at 40deg from nadir as recommended by Mueller et al. [2003b]. The water radiance sensor was able to view over an azimuth range of ~180deg across the ship's heading with no viewing of the ship's wake. The direction of the sensor was adjusted to view the water 90-120deg from the sun's azimuth, to minimize sun glint. This was continually adjusted as the time and ship's gyro heading were used to calculate the sun's position using an astronomical solar position subroutine interfaced with a stepping motor which was attached to the radiometer mount (designed and fabricated at Bigelow Laboratory for Ocean Sciences). Protocols for operation and calibration were performed according to Mueller [Mueller et al., 2003a; Mueller et al., 2003b; Mueller et al., 2003c]. Before 1000h and after 1400h, data quality was poorer as the solar zenith angle was too low. Post-cruise, the 10Hz data were filtered to remove as much residual white cap and glint as possible (we accept the lowest 5% of the data). Reflectance plaque measurements were made several times at local apparent noon on sunny days to verify the radiometer calibrations.<br /> <br /> Within an hour of local apparent noon each day, a Satlantic OCP sensor was deployed off the stern of the vessel after the ship oriented so that the sun was off the stern. The ship would secure the starboard Z-drive, and use port Z-drive and bow thruster to move the ship ahead at about 25cm s-1. The OCP was then trailed aft and brought to the surface ~100m aft of the ship, then allowed to sink to 100m as downwelling spectral irradiance and upwelling spectral radiance were recorded continuously along with temperature and salinity. This procedure ensured there were no ship shadow effects in the radiometry.<br /> <br /> Instruments include a WETLabs wetstar fluorometer, a WETLabs ECOTriplet and a SeaBird microTSG.<br /> Radiometry was done using a Satlantic 7 channel microSAS system with Es, Lt and Li sensors.<br /> <br /> Chl data is based on inter calibrating surface discrete Chlorophyll measure with the temporally closest fluorescence measurement and applying the regression results to all fluorescence data.<br /> <br /> Data have been corrected for instrument biofouling and drift based on weekly purewater calibrations of the system. Radiometric data has been processed using standard Satlantic processing software and has been checked with periodic plaque measurements using a 2% spectralon standard.</p> <p>Lw is calculated from Lt and Lsky and is \"what Lt would be if the<br /> sensor were looking straight down\". Since our sensors are mounted at<br /> 40o, based on various NASA protocols, we need to do that conversion.<br /> <br /> Lwn adds Es to the mix. Es is used to normalize Lw. Nlw is related to Rrs, Remote Sensing Reflectance</p> <p><strong>Techniques used are as described in:</strong><br /> Balch WM, Drapeau DT, Bowler BC, Booth ES, Windecker LA, Ashe A (2008) Space–time variability of carbon standing stocks and fixation rates in the Gulf of Maine, along the GNATS transect between Portland, ME, USA, and Yarmouth, Nova Scotia, Canada.<br /> J Plankton Res 30:119–139</p> Dataset Southern Ocean Biological and Chemical Oceanography Data Management Office (BCO-DMO) (via DataONE) Balch ENVELOPE(-63.967,-63.967,-65.250,-65.250) Canada Mueller ENVELOPE(55.533,55.533,-66.917,-66.917) Southern Ocean