Seasonal particle and carbon dynamics in the eastern Bering Sea

The ocean margins of high-latitude seas, such as the eastern Bering Sea, are recognized as important areas for the enhanced scavenging removal of particle reactive chemicals and for the potential to sequester atmospheric carbon dioxide via photosynthetic conversion to biogenic particles and subseque...

Full description

Bibliographic Details
Main Author: Baumann, Matthew S
Format: Text
Language:English
Published: DigitalCommons@URI 2013
Subjects:
Chemical Oceanography
Bering Sea
Sea ice
Online Access:https://digitalcommons.uri.edu/dissertations/AAI3604652
id ftunivrhodeislan:oai:digitalcommons.uri.edu:dissertations-3050
record_format openpolar
institution Open Polar
collection University of Rhode Island: DigitalCommons@URI
op_collection_id ftunivrhodeislan
language English
topic Chemical Oceanography
spellingShingle Chemical Oceanography
Baumann, Matthew S
Seasonal particle and carbon dynamics in the eastern Bering Sea
topic_facet Chemical Oceanography
description The ocean margins of high-latitude seas, such as the eastern Bering Sea, are recognized as important areas for the enhanced scavenging removal of particle reactive chemicals and for the potential to sequester atmospheric carbon dioxide via photosynthetic conversion to biogenic particles and subsequent downward particle transport to deeper waters. This region is expected to warm in the future, and with the warming will come a reduction in the extent and duration of seasonal sea-ice. This physical process exerts an important control on the timing, location, and magnitude of the spring primary production bloom. Within the context that 2008-2010 are characterized as cold years in the eastern Bering Sea, establishing the mechanistic link between primary production and the seasonal progression in particle export represents a significant challenge because these processes exert a control on organic matter transport from the surface ocean and on the success of economically and culturally important animals. During spring and summer cruises in 2009 and 2010, distributions of 234Th (t1/2 = 24.1 days) in the water column and sediments were measured at ∼60 stations over the middle and outer regions of the shelf and at the shelf break. The inventory of excess 234Th (234Th which is not produced in the sediments) in shelf sediments was ∼1/3 of the total deficit of 234Th (234Th scavenged by sinking particles) in the overlying water column leading to an average focusing factor of 0.34 ± 0.23. Further, 234Th export from the shelf was determined to ∼30% of the total production of this radionuclide by 238U decay based on a 234Th budget. These results, taken together with elevated focusing factors in the off-shelf region, suggest that the shelf sediments and lateral transport of particles from the shelf represent significant sinks for biogenic particles produced over the shelf in the spring and summer. The elevated focusing factors at the shelf break are attributed to enhanced particle flux from blooms of primary production in this region, an area commonly referred to as the 'Green Belt' for its exceptionally high rates of primary production. Thus, seasonal export of particles from elevated rates of primary production at the shelf break may transfer a significant amount of particulate organic carbon (POC) from the surface waters. POC export in this region demonstrates a clear seasonal progression with low fluxes in the early spring that increase by late spring and early summer. Rates of net primary production (NPP) were high and export fluxes relatively low near the ice-edge in spring, leading to export ratios (e-ratio = POC export/NPP) <0.25. In early summer, POC export exceeded NPP individual stations leading e-ratios >1, which is attributed to a temporal lag, or offset, between the high rates of primary production in spring and export as POC during the early summer. Using a water column-sediment 234Th budget, the export of POC from the outer shelf to slope water was estimated to be 24±35 mmol C m-2 d-1, which represents an off-shelf e-ratio of 0.07-0.52 for contemporaneous seasonally averaged and historical monthly averaged daily rates of NPP. In addition to the vertical POC fluxes measured at the shelf break, the imputed off-shelf export flux and e-ratios further suggests that there may be a significant transfer of shelf-derived particles to the slope waters. The high e-ratios and particles fluxes determined at the shelf may be a result of the biological response to the timing of physical processes in spring and summer of cold years. In spring, total chlorophyll a concentrations are generally low; however, localized phytoplankton blooms near the marginal ice zone (MIZ) lead to elevated spring average chlorophyll a concentrations, relative to summer, over the shelf and at the shelf break. (Abstract shortened by UMI.)
format Text
author Baumann, Matthew S
author_facet Baumann, Matthew S
author_sort Baumann, Matthew S
title Seasonal particle and carbon dynamics in the eastern Bering Sea
title_short Seasonal particle and carbon dynamics in the eastern Bering Sea
title_full Seasonal particle and carbon dynamics in the eastern Bering Sea
title_fullStr Seasonal particle and carbon dynamics in the eastern Bering Sea
title_full_unstemmed Seasonal particle and carbon dynamics in the eastern Bering Sea
title_sort seasonal particle and carbon dynamics in the eastern bering sea
publisher DigitalCommons@URI
publishDate 2013
url https://digitalcommons.uri.edu/dissertations/AAI3604652
geographic Bering Sea
geographic_facet Bering Sea
genre Bering Sea
Sea ice
genre_facet Bering Sea
Sea ice
op_source Dissertations and Master's Theses (Campus Access)
op_relation https://digitalcommons.uri.edu/dissertations/AAI3604652
_version_ 1766377961932455936
spelling ftunivrhodeislan:oai:digitalcommons.uri.edu:dissertations-3050 2023-05-15T15:43:45+02:00 Seasonal particle and carbon dynamics in the eastern Bering Sea Baumann, Matthew S 2013-01-01T08:00:00Z https://digitalcommons.uri.edu/dissertations/AAI3604652 ENG eng DigitalCommons@URI https://digitalcommons.uri.edu/dissertations/AAI3604652 Dissertations and Master's Theses (Campus Access) Chemical Oceanography text 2013 ftunivrhodeislan 2021-06-29T19:21:08Z The ocean margins of high-latitude seas, such as the eastern Bering Sea, are recognized as important areas for the enhanced scavenging removal of particle reactive chemicals and for the potential to sequester atmospheric carbon dioxide via photosynthetic conversion to biogenic particles and subsequent downward particle transport to deeper waters. This region is expected to warm in the future, and with the warming will come a reduction in the extent and duration of seasonal sea-ice. This physical process exerts an important control on the timing, location, and magnitude of the spring primary production bloom. Within the context that 2008-2010 are characterized as cold years in the eastern Bering Sea, establishing the mechanistic link between primary production and the seasonal progression in particle export represents a significant challenge because these processes exert a control on organic matter transport from the surface ocean and on the success of economically and culturally important animals. During spring and summer cruises in 2009 and 2010, distributions of 234Th (t1/2 = 24.1 days) in the water column and sediments were measured at ∼60 stations over the middle and outer regions of the shelf and at the shelf break. The inventory of excess 234Th (234Th which is not produced in the sediments) in shelf sediments was ∼1/3 of the total deficit of 234Th (234Th scavenged by sinking particles) in the overlying water column leading to an average focusing factor of 0.34 ± 0.23. Further, 234Th export from the shelf was determined to ∼30% of the total production of this radionuclide by 238U decay based on a 234Th budget. These results, taken together with elevated focusing factors in the off-shelf region, suggest that the shelf sediments and lateral transport of particles from the shelf represent significant sinks for biogenic particles produced over the shelf in the spring and summer. The elevated focusing factors at the shelf break are attributed to enhanced particle flux from blooms of primary production in this region, an area commonly referred to as the 'Green Belt' for its exceptionally high rates of primary production. Thus, seasonal export of particles from elevated rates of primary production at the shelf break may transfer a significant amount of particulate organic carbon (POC) from the surface waters. POC export in this region demonstrates a clear seasonal progression with low fluxes in the early spring that increase by late spring and early summer. Rates of net primary production (NPP) were high and export fluxes relatively low near the ice-edge in spring, leading to export ratios (e-ratio = POC export/NPP) <0.25. In early summer, POC export exceeded NPP individual stations leading e-ratios >1, which is attributed to a temporal lag, or offset, between the high rates of primary production in spring and export as POC during the early summer. Using a water column-sediment 234Th budget, the export of POC from the outer shelf to slope water was estimated to be 24±35 mmol C m-2 d-1, which represents an off-shelf e-ratio of 0.07-0.52 for contemporaneous seasonally averaged and historical monthly averaged daily rates of NPP. In addition to the vertical POC fluxes measured at the shelf break, the imputed off-shelf export flux and e-ratios further suggests that there may be a significant transfer of shelf-derived particles to the slope waters. The high e-ratios and particles fluxes determined at the shelf may be a result of the biological response to the timing of physical processes in spring and summer of cold years. In spring, total chlorophyll a concentrations are generally low; however, localized phytoplankton blooms near the marginal ice zone (MIZ) lead to elevated spring average chlorophyll a concentrations, relative to summer, over the shelf and at the shelf break. (Abstract shortened by UMI.) Text Bering Sea Sea ice University of Rhode Island: DigitalCommons@URI Bering Sea

Similar Items