A Visual Tour of Carbon Export by Sinking Particles

A Visual Tour of Carbon Export by Sinking Particles

To better quantify the ocean's biological carbon pump, we resolved the diversity of sinking particles that transport carbon into the ocean's interior, their contribution to carbon export, and their attenuation with depth. Sinking particles collected in sediment trap gel layers from four di...

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Bibliographic Details
Published in:Global biogeochemical cycles Vol. 35; no. 10; pp. e2021GB006985 - n/a
Main Authors: Durkin, Colleen A, Buesseler, Ken O, Cetinic, Ivona, Estapa, Margaret L, Kelly, Roger P, Omand, Melissa M
Format: Journal Article
Language:English
Published: Goddard Space Flight Center American Geophysical Union 01-10-2021
Blackwell Publishing Ltd
John Wiley and Sons Inc
Subjects:
Aggregates
Atmospheric models
Attenuation
Biogeochemical Cycles, Processes, and Modeling
Biogeochemical Kinetics and Reaction Modeling
Biogeochemistry
Biogeosciences
biological carbon pump
Carbon
Carbon cycle
Composition
Cryosphere
Depth
Detritus
Faecal pellets
fecal pellets
Feces
Fluctuations
Fluxes
Gelatinous zooplankton
Gels
Global Change
Imagery
Marine ecosystems
Marine invertebrates
Ocean basins
Ocean models
Oceanography
Oceanography: Biological and Chemical
Oceans
Organic carbon
Paleoceanography
Particle composition
particles
Particulate flux
Particulate organic carbon
Pellets
Plankton
salp
Sediment
Sediment traps
Sinking
Surveying
Transport
Zooplankton
Carbon Flux
Phytoplankton
Sinking Particle
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Summary:To better quantify the ocean's biological carbon pump, we resolved the diversity of sinking particles that transport carbon into the ocean's interior, their contribution to carbon export, and their attenuation with depth. Sinking particles collected in sediment trap gel layers from four distinct ocean ecosystems were imaged, measured, and classified. The size and identity of particles was used to model their contribution to particulate organic carbon (POC) flux. Measured POC fluxes were reasonably predicted by particle images. Nine particle types were identified, and most of the compositional variability was driven by the relative contribution of aggregates, long cylindrical fecal pellets, and salp fecal pellets. While particle composition varied across locations and seasons, the entire range of compositions was measured at a single well-observed location in the subarctic North Pacific over one month, across 500 m of depth. The magnitude of POC flux was not consistently associated with a dominant particle class, but particle classes did influence flux attenuation. Long fecal pellets attenuated most rapidly with depth whereas certain other classes attenuated little or not at all with depth. Small particles (<100 m) consistently contributed ~5% to total POC flux in samples with higher magnitude fluxes. The relative importance of these small particle classes (spherical mini pellets, short oval fecal pellets, and dense detritus) increased in low flux environments (up to 46% of total POC flux). Imaging approaches that resolve large variations in particle composition across ocean basins, depth, and time will help to better parameterize biological carbon pump models
Bibliography:GSFC
Goddard Space Flight Center
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0886-6236
1944-9224
DOI:10.1029/2021GB006985