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- Title
Evidence for Kilometer‐Scale Biophysical Features at the Gulf Stream Front.
- Authors
Gray, Patrick Clifton; Savelyev, Ivan; Cassar, Nicolas; Lévy, Marina; Boss, Emmanuel; Lehahn, Yoav; Bourdin, Guillaume; Thompson, Kate A.; Windle, Anna; Gronniger, Jessica; Floge, Sheri; Hunt, Dana E.; Silsbe, Greg; Johnson, Zackary I.; Johnston, David W.
- Abstract
Understanding the interplay of ocean physics and biology at the submesoscale and below (<30 km) is an ongoing challenge in oceanography. While poorly constrained, these scales may be of critical importance for understanding how changing ocean dynamics will impact marine ecosystems. Fronts in the ocean, regions where two disparate water masses meet and isopycnals become tilted toward vertical, are considered hotspots for biophysical interaction, but there is limited observational evidence at the appropriate scales to assess their importance. Fronts around western boundary currents like the Gulf Stream are of particular interest as these dynamic physical regions are thought to influence both productivity and composition of primary producers; however, how exactly this plays out is not well known. Using satellite data and 2 years of in situ observations across the Gulf Stream front near Cape Hatteras, North Carolina, we investigate how submesoscale frontal dynamics could affect biological communities and generate hotspots of productivity and export. We assess the seasonality and phenology of the region, generalize the kilometer‐scale structure of the front, and analyze 69 transects to assess two physical processes of potential biogeochemical importance: cold shelf filament subduction and high salinity Sargasso Sea obduction. We link these processes observationally to meanders in the Gulf Stream and discuss how cold filament subduction could be exporting carbon and how obduction of high salinity water from depth is connected with high chlorophyll‐a. Finally, we report on phytoplankton community composition in each of these features and integrate these observations into our understanding of frontal submesoscale dynamics. Plain Language Summary: The interplay of physics and biology in determining the biomass and composition of phytoplankton communities is poorly understood and is key to understanding marine ecosystem resilience and structure in a changing ocean. In this work we investigated the impact of physics and biology on phytoplankton across scales focusing on the Gulf Stream front. Fronts in the ocean are where lines of equal density go from being horizontal to having a vertical tile, and because of this can enable nutrients and plankton to move from depth to the surface and vice versa. The objective of this work is to understand how physics might drive important changes in phytoplankton biomass and composition in the Gulf Stream front, which is amongst the sharpest gradients in temperature, density, and current speed in the global ocean. We find two frequent processes at the front, the apparent downward movement of cold filaments along the edge of the Gulf Stream, associated with meander troughs, and upward movement of high salinity Sargasso Sea water into the front linked to meander crests. While ephemeral, these processes are frequent and could have a large impact on local phytoplankton biomass, phytoplankton composition, and the export of organic matter to depth. Key Points: The frontal zone of the Gulf Stream has an interface water mass with different origins and a range of biogeochemical impactsMeanders appear to control the front interface: troughs lead to shelf filament subduction and crests lead to high salinity water obductionSubduction and obduction appear to be common at the front and could lead to ephemeral kilometer‐scale export and productivity
- Subjects
HATTERAS, Cape (N.C.); NORTH Carolina; GULF Stream; BIOTIC communities; WATERFRONTS; WATER masses; ECOSYSTEMS; OCEAN dynamics; MARINE ecosystem management; EPHEMERAL streams
- Publication
Journal of Geophysical Research. Oceans, 2024, Vol 129, Issue 3, p1
- ISSN
2169-9275
- Publication type
Article
- DOI
10.1029/2023JC020526