Investigating Labrador Sea's persistent surface O2 anomaly using observations and biogeochemical model results
Investigating Labrador Sea's persistent surface O2 anomaly using observations and biogeochemical model results
Deviations of surface ocean dissolved oxygen (O2) from equilibrium with the atmosphere should be rectified about twenty times more quickly than deviations of dissolved carbon dioxide (CO2). Therefore, persistent O2 disequilibria in the Labrador Sea, while CO2 is close to equilibrium, has been a matter of interest to many previous works. Here we investigate this phenomenon by using a novel analytical technique, the ‘CORS (Carbon Dioxide and Oxygen Relative to Saturation) method’, and also by using more data than was available previously. We compare observations to results from a model we developed for the Labrador Sea which combines plankton ecology with biogeochemical cycling of oxygen, carbon and nitrogen. In contrast to earlier works which mostly considered individual factors in isolation, here we used the model, together with data, to distinguish between the varying influences of several processes potentially contributing to the long-lasting O2 undersaturation: mixed layer depth, duration of mixed layer deepening, convection, entrainment and bottom water O2 content. Our model experiments confirm that, for the same gas exchange rate, the effects on surface O2 concentration differ significantly among the identified drivers. Our results suggest that prolonged surface O2 undersaturation is not always dependent on the extreme winter mixed layer depths, but rather that even moderately deep mixed layers (e.g. 300m), when prolonged and in conjunction with continuous entrainment of oxygen-depleted deep water, can also drive persistent surface O2 anomalies. An implication of our results is that regions in the North Atlantic with maximum winter mixed layer depths of only a few hundred metres should also show persistent surface O2 undersaturation. We further reveal that convection in deep water formation regions produces trendlines that do not pass through the origin of a plot of CO2 vs. O2 deviations which have previously been thought to indicate erroneous data.
Autonomous data quality, Biogeochemical Models, CORS method, Labrador Sea, Oxygen, mixed layer depth, Mixed layer depth, Biogeochemical models
Silva, Amavi N.
214721e8-c82d-4e40-9953-66bc47b21ef3
Purdie, Duncan A.
18820b32-185a-467a-8019-01f245191cd8
Bates, Nicholas R.
954a83d6-8424-49e9-8acd-e606221c9c57
Tyrrell, Toby
6808411d-c9cf-47a3-88b6-c7c294f2d114
September 2024
Silva, Amavi N.
214721e8-c82d-4e40-9953-66bc47b21ef3
Purdie, Duncan A.
18820b32-185a-467a-8019-01f245191cd8
Bates, Nicholas R.
954a83d6-8424-49e9-8acd-e606221c9c57
Tyrrell, Toby
6808411d-c9cf-47a3-88b6-c7c294f2d114
Silva, Amavi N., Purdie, Duncan A., Bates, Nicholas R. and Tyrrell, Toby
(2024)
Investigating Labrador Sea's persistent surface O2 anomaly using observations and biogeochemical model results.
Journal of Marine Systems, 245, [103996].
(doi:10.1016/j.jmarsys.2024.103996).
Abstract
Deviations of surface ocean dissolved oxygen (O2) from equilibrium with the atmosphere should be rectified about twenty times more quickly than deviations of dissolved carbon dioxide (CO2). Therefore, persistent O2 disequilibria in the Labrador Sea, while CO2 is close to equilibrium, has been a matter of interest to many previous works. Here we investigate this phenomenon by using a novel analytical technique, the ‘CORS (Carbon Dioxide and Oxygen Relative to Saturation) method’, and also by using more data than was available previously. We compare observations to results from a model we developed for the Labrador Sea which combines plankton ecology with biogeochemical cycling of oxygen, carbon and nitrogen. In contrast to earlier works which mostly considered individual factors in isolation, here we used the model, together with data, to distinguish between the varying influences of several processes potentially contributing to the long-lasting O2 undersaturation: mixed layer depth, duration of mixed layer deepening, convection, entrainment and bottom water O2 content. Our model experiments confirm that, for the same gas exchange rate, the effects on surface O2 concentration differ significantly among the identified drivers. Our results suggest that prolonged surface O2 undersaturation is not always dependent on the extreme winter mixed layer depths, but rather that even moderately deep mixed layers (e.g. 300m), when prolonged and in conjunction with continuous entrainment of oxygen-depleted deep water, can also drive persistent surface O2 anomalies. An implication of our results is that regions in the North Atlantic with maximum winter mixed layer depths of only a few hundred metres should also show persistent surface O2 undersaturation. We further reveal that convection in deep water formation regions produces trendlines that do not pass through the origin of a plot of CO2 vs. O2 deviations which have previously been thought to indicate erroneous data.
Text
1-s2.0-S0924796324000344-main
- Version of Record
More information
Accepted/In Press date: 3 June 2024
e-pub ahead of print date: 4 June 2024
Published date: September 2024
Additional Information:
Publisher Copyright:
© 2024 The Authors
Keywords:
Autonomous data quality, Biogeochemical Models, CORS method, Labrador Sea, Oxygen, mixed layer depth, Mixed layer depth, Biogeochemical models
Identifiers
Local EPrints ID: 491117
URI: http://eprints.soton.ac.uk/id/eprint/491117
ISSN: 0924-7963
PURE UUID: f887da08-8f31-47b4-b957-501c28028f9c
Catalogue record
Date deposited: 12 Jun 2024 17:23
Last modified: 13 Jul 2024 02:02
Export record
Altmetrics
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
