Understanding the remote influences of ocean weather on the episodic pulses of particulate organic carbon flux
Ruhl, Henry A.; Bahr, Frederick L.; Henson, Stephanie A. ORCID: https://orcid.org/0000-0002-3875-6802; Hosking, W. Brett; Espinola, Benoit; Kahru, Mati; Daniel, Patrick; Drake, Patrick; Edwards, Christopher A.. 2020 Understanding the remote influences of ocean weather on the episodic pulses of particulate organic carbon flux. Deep Sea Research Part II: Topical Studies in Oceanography, 173, 104741. https://doi.org/10.1016/j.dsr2.2020.104741
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Abstract/Summary
The biological carbon pump has been estimated to export ~5–15 Gt C yr−1 into the deep ocean, and forms the principal deep-sea food resource. Irregular, intense pulses of particulate organic carbon (POC) have been found to make up about one-third of the overall POC fluxes at a long-term deep-sea research station influenced by coastal upwelling of the California Current, Station M (34°50′N, 123° W, 4000 m depth). However, the drivers of these pulses have been challenging to quantify. It has long been recognized that ocean currents can result in particles being advected while sinking to the point of collection by a sediment trap. Thus, a sediment trap time series can incorporate material from a dynamic catchment area, a concept sometimes referred to as a statistical funnel. This concept raises many questions including: what are the day-to-day conditions at the source locations of the sinking POC? And, how might such ‘ocean weather’ and related ecosystem factors influence the intense variation seen at the seafloor? Here we analyzed three-dimensional ocean currents from a Regional Ocean Modeling System (ROMS) model from 2011 to 2017 to trace the potential source locations of particles sinking at 1000, 100, and 50 m d−1 from an export depth of 100 m. We then used regionally tailored satellite data products to estimate export flux of POC from these locations. For the 100 m d−1 speed, the particles had origins of up to ~300 km horizontal distance from the sediment trap location, moored at Station M at 3400 m depth., and nearly 1000 km for the 50 m d−1 speed. Particle tracking indicated that, there was considerable inter-annual variation in source locations. Particle source locations tended to originate from the east in the summer months, with higher export and POC fluxes. Occasionally these locations were in the vicinity of highly productive ocean features nearer to the coast. We found significant correlations between export flux of organic carbon from the estimated source locations at 100 m depth to trap-estimated POC fluxes at 3400 m depth. These results set the stage for further investigation into sinking speed distributions, conditions at the source locations, and comparisons with mechanistic biogeochemical models and between particle tracking model frameworks.
Item Type: | Publication - Article |
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Digital Object Identifier (DOI): | https://doi.org/10.1016/j.dsr2.2020.104741 |
ISSN: | 09670645 |
Date made live: | 14 May 2020 15:35 +0 (UTC) |
URI: | https://nora.nerc.ac.uk/id/eprint/527725 |
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