Eddy-Modified Iron, Light, and Phytoplankton Cell Division Rates in the Simulated Southern Ocean

We examine the effects of Southern Ocean eddies on phytoplankton cell division rates in a global, multiyear, eddyâ€resolving, 3â€D ocean simulation of the Community Earth System Model. We first identify and track eddies in the simulation and validate their distribution and demographics against obser...

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Published in:	Global Biogeochemical Cycles
Main Authors:	Rohr, Tyler, Harrison, Cheryl S., Long, Matthew C., Gaube, Peter, Doney, Scott C.
Format:	Text
Language:	unknown
Published:	ScholarWorks @ UTRGV 2020
Subjects:	Biogeochemistry Phytoplankton Eddies Southern Ocean Simulated Earth Sciences Environmental Sciences Marine Biology Antarc* Antarctic Southern Ocean
Online Access:	https://scholarworks.utrgv.edu/eems_fac/81 https://doi.org/10.1029/2019GB006380 https://scholarworks.utrgv.edu/context/eems_fac/article/1081/viewcontent/2020__Rohr_2020_Eddymodified_iron_light_and_phytopl.pdf

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record_format	openpolar
spelling	ftutexasriogrand:oai:scholarworks.utrgv.edu:eems_fac-1081 2024-09-15T17:43:24+00:00 Eddy-Modified Iron, Light, and Phytoplankton Cell Division Rates in the Simulated Southern Ocean Rohr, Tyler Harrison, Cheryl S. Long, Matthew C. Gaube, Peter Doney, Scott C. 2020-04-01T07:00:00Z application/pdf https://scholarworks.utrgv.edu/eems_fac/81 https://doi.org/10.1029/2019GB006380 https://scholarworks.utrgv.edu/context/eems_fac/article/1081/viewcontent/2020__Rohr_2020_Eddymodified_iron_light_and_phytopl.pdf unknown ScholarWorks @ UTRGV https://scholarworks.utrgv.edu/eems_fac/81 doi:10.1029/2019GB006380 https://scholarworks.utrgv.edu/context/eems_fac/article/1081/viewcontent/2020__Rohr_2020_Eddymodified_iron_light_and_phytopl.pdf School of Earth, Environmental, and Marine Sciences Faculty Publications and Presentations Biogeochemistry Phytoplankton Eddies Southern Ocean Simulated Earth Sciences Environmental Sciences Marine Biology text 2020 ftutexasriogrand https://doi.org/10.1029/2019GB006380 2024-07-17T03:41:29Z We examine the effects of Southern Ocean eddies on phytoplankton cell division rates in a global, multiyear, eddyâ€resolving, 3â€D ocean simulation of the Community Earth System Model. We first identify and track eddies in the simulation and validate their distribution and demographics against observed eddy trajectory characteristics. Next, we examine how simulated cyclones and anticyclones differentially modify iron, light, and ultimately populationâ€specific cell division rates. We use an eddyâ€centric, depthâ€averaged framework to explicitly examine the dynamics of the phytoplankton population across the entire water column within an eddy. We find that populationâ€averaged iron availability is elevated in anticyclones throughout the year. The dominant mechanism responsible for vertically transporting iron from depth in anticyclones is eddyâ€induced Ekman upwelling. During winter, in regions with deep climatological mixed layer depths, anticyclones also induce anomalously deep mixed layer depths, which further supply new iron from depth via an increased upward mixing flux. However, this additional contribution comes at the price of deteriorating light availability as biomass is distributed deeper in the water column. Therefore, even though populationâ€averaged specific division rates are elevated in Southern Ocean anticyclones throughout most of the year, in the winter, severe light stress can dominate relieved iron stress and lead to depressed division rates in some anticyclones, particularly in the deep mixing South Pacific Antarctic Circumpolar Current. The opposite is true in cyclones, which exhibit a consistently symmetric physical and biogeochemical response relative to anticyclones. Text Antarc* Antarctic Southern Ocean Scholarworks@UTRGV (The University of Texas RioGrande Valley) Global Biogeochemical Cycles 34 6
institution	Open Polar
collection	Scholarworks@UTRGV (The University of Texas RioGrande Valley)
op_collection_id	ftutexasriogrand
language	unknown
topic	Biogeochemistry Phytoplankton Eddies Southern Ocean Simulated Earth Sciences Environmental Sciences Marine Biology
spellingShingle	Biogeochemistry Phytoplankton Eddies Southern Ocean Simulated Earth Sciences Environmental Sciences Marine Biology Rohr, Tyler Harrison, Cheryl S. Long, Matthew C. Gaube, Peter Doney, Scott C. Eddy-Modified Iron, Light, and Phytoplankton Cell Division Rates in the Simulated Southern Ocean
topic_facet	Biogeochemistry Phytoplankton Eddies Southern Ocean Simulated Earth Sciences Environmental Sciences Marine Biology
description	We examine the effects of Southern Ocean eddies on phytoplankton cell division rates in a global, multiyear, eddyâ€resolving, 3â€D ocean simulation of the Community Earth System Model. We first identify and track eddies in the simulation and validate their distribution and demographics against observed eddy trajectory characteristics. Next, we examine how simulated cyclones and anticyclones differentially modify iron, light, and ultimately populationâ€specific cell division rates. We use an eddyâ€centric, depthâ€averaged framework to explicitly examine the dynamics of the phytoplankton population across the entire water column within an eddy. We find that populationâ€averaged iron availability is elevated in anticyclones throughout the year. The dominant mechanism responsible for vertically transporting iron from depth in anticyclones is eddyâ€induced Ekman upwelling. During winter, in regions with deep climatological mixed layer depths, anticyclones also induce anomalously deep mixed layer depths, which further supply new iron from depth via an increased upward mixing flux. However, this additional contribution comes at the price of deteriorating light availability as biomass is distributed deeper in the water column. Therefore, even though populationâ€averaged specific division rates are elevated in Southern Ocean anticyclones throughout most of the year, in the winter, severe light stress can dominate relieved iron stress and lead to depressed division rates in some anticyclones, particularly in the deep mixing South Pacific Antarctic Circumpolar Current. The opposite is true in cyclones, which exhibit a consistently symmetric physical and biogeochemical response relative to anticyclones.
format	Text
author	Rohr, Tyler Harrison, Cheryl S. Long, Matthew C. Gaube, Peter Doney, Scott C.
author_facet	Rohr, Tyler Harrison, Cheryl S. Long, Matthew C. Gaube, Peter Doney, Scott C.
author_sort	Rohr, Tyler
title	Eddy-Modified Iron, Light, and Phytoplankton Cell Division Rates in the Simulated Southern Ocean
title_short	Eddy-Modified Iron, Light, and Phytoplankton Cell Division Rates in the Simulated Southern Ocean
title_full	Eddy-Modified Iron, Light, and Phytoplankton Cell Division Rates in the Simulated Southern Ocean
title_fullStr	Eddy-Modified Iron, Light, and Phytoplankton Cell Division Rates in the Simulated Southern Ocean
title_full_unstemmed	Eddy-Modified Iron, Light, and Phytoplankton Cell Division Rates in the Simulated Southern Ocean
title_sort	eddy-modified iron, light, and phytoplankton cell division rates in the simulated southern ocean
publisher	ScholarWorks @ UTRGV
publishDate	2020
url	https://scholarworks.utrgv.edu/eems_fac/81 https://doi.org/10.1029/2019GB006380 https://scholarworks.utrgv.edu/context/eems_fac/article/1081/viewcontent/2020__Rohr_2020_Eddymodified_iron_light_and_phytopl.pdf
genre	Antarc* Antarctic Southern Ocean
genre_facet	Antarc* Antarctic Southern Ocean
op_source	School of Earth, Environmental, and Marine Sciences Faculty Publications and Presentations
op_relation	https://scholarworks.utrgv.edu/eems_fac/81 doi:10.1029/2019GB006380 https://scholarworks.utrgv.edu/context/eems_fac/article/1081/viewcontent/2020__Rohr_2020_Eddymodified_iron_light_and_phytopl.pdf
op_doi	https://doi.org/10.1029/2019GB006380
container_title	Global Biogeochemical Cycles
container_volume	34
container_issue	6
_version_	1810490360990793728

Eddy-Modified Iron, Light, and Phytoplankton Cell Division Rates in the Simulated Southern Ocean

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