skip to main content
US FlagAn official website of the United States government
dot gov icon
Official websites use .gov
A .gov website belongs to an official government organization in the United States.
https lock icon
Secure .gov websites use HTTPS
A lock ( lock ) or https:// means you've safely connected to the .gov website. Share sensitive information only on official, secure websites.

Explore Research Products in the PAR
It may take a few hours for recently added research products to appear in PAR search results.


Title: Dynamic benthic oxygen fluxes lessen hypoxia effects on open continental shelves
Abstract Under the supposition that organisms inhabiting physically dynamic marine environments are better able to survive hypoxic conditions than those experiencing little turbulent or advective augmentation of oxygen fluxes, we evaluated summertime benthic macrofauna communities, in situ aquatic eddy covariance measurements, and ex situ sediment core incubations from 5 latitudinally distinct mid‐shelf locations off Oregon–Washington, USA. Despite bottom water dissolved oxygen (DO) concentrations averaging from 17 to 75 μmol L−1, invertebrate faunal collections contained mixtures of 11 to 28 taxa per 0.1 m2box core and increased in richness and abundance at sites with greater velocity variation. Eddy covariance velocity records of 18‐30 hours regularly showed the arrivals of internal waves. Oxygen fluxes, derived in 15‐min intervals, correlated with multiple flow parameters assessed from velocity components. Daily averages of the oxygen fluxes to the sediment were determined to range from −3.5 to −23 mmol m−2 d−1, and these fluxes, assumed to fully represent seabed respiration, were 2 to 5 times greater than rates of DO uptake by sediment cores from the same locations. Velocity profiles measured from 0.3 to 2.5 m above the seafloor at a subset of sites were consistent with a wave‐current boundary layer modulated by ocean swell. These findings illustrate how natural physical processes can relieve the stress of hypoxia exposure on the benthos. Physical dynamics play critical roles in supplying DO and determining sediment grain size, permeability, and the activities of benthic organisms. Thus, these factors need consideration when predicting the impacts of low DO concentrations in coastal regions.  more » « less
Award ID(s):
2126112
PAR ID:
10651145
Author(s) / Creator(s):
 ;  ;  ;  ;  ;  
Publisher / Repository:
Wiley
Date Published:
Journal Name:
Limnology and Oceanography
Volume:
70
Issue:
10
ISSN:
0024-3590
Page Range / eLocation ID:
2998 to 3015
Subject(s) / Keyword(s):
oxygen flux, benthos, hypoxia, continental shelf
Format(s):
Medium: X
Sponsoring Org:
National Science Foundation
More Like this
  1. ; ; ; ; ; ; (, Marine Ecology Progress Series)
    Organic carbon mineralization and nutrient cycling in benthic environments are critically important for their biogeochemical functioning, but are poorly understood in coastal upwelling systems. The main objective of this study was to determine benthic oxygen fluxes in a muddy sediment in the Ria de Vigo (NW Iberian coastal upwelling), by applying the aquatic eddy covariance (AEC) technique during 2 campaigns in different seasons (June and October 2017). The main drivers of benthic fluxes were studied and compared among days in each season and between seasons. The 2 campaigns were characterized by an upwelling-relaxation period followed by a downwelling event, the last of which was due to the extratropical cyclone Ophelia in October. The mean (±SD) seasonal benthic oxygen fluxes were not significantly different for the 2 campaigns despite differences in hydrodynamic and biogeochemical conditions (June: -20.9 ± 7.1 mmol m -2 d -1 vs. October: -26.5 ± 3.1 mmol m -2 d -1 ). Benthic fluxes were controlled by different drivers depending on the season. June was characterized by sinking labile organic material, which enhanced benthic fluxes in the downwelling event, whereas October had a significantly higher bottom velocity that stimulated the benthic fluxes. Finally, a comparison with a large benthic chamber (0.50 m 2 ) was made during October. Despite methodological differences between AEC and chamber measurements, concurrent fluxes agreed within an acceptable margin (AEC:benthic chamber ratio = 0.78 ± 0.13; mean ± SD). Bottle incubations of water sampled from the chamber interior indicated that mineralization could explain this difference. These results show the importance of using non-invasive techniques such as AEC to resolve benthic flux dynamics. 
    more » « less
  2. ; ; (, Biogeosciences)
    null (Ed.)
    Abstract. Sediment–water oxygen fluxes are widely used as a proxy fororganic carbon production and mineralization at the seafloor. In situ fluxescan be measured non-invasively with the aquatic eddy covariance technique,but a critical requirement is that the sensors of the instrument are able tocorrectly capture the high-frequency variations in dissolved oxygenconcentration and vertical velocity. Even small changes in sensorcharacteristics during deployment as caused, e.g. by biofouling can result inerroneous flux data. Here we present a dual-optode eddy covarianceinstrument (2OEC) with two fast oxygen fibre sensors and document howerroneous flux interpretations and data loss can effectively be reduced bythis hardware and a new data analysis approach. With deployments over acarbonate sandy sediment in the Florida Keys and comparison with parallelbenthic advection chamber incubations, we demonstrate the improved dataquality and data reliability facilitated by the instrument and associateddata processing. Short-term changes in flux that are dubious in measurementswith single oxygen sensor instruments can be confirmed or rejected with the2OEC and in our deployments provided new insights into the temporal dynamicsof benthic oxygen flux in permeable carbonate sands. Under steadyconditions, representative benthic flux data can be generated with the 2OECwithin a couple of hours, making this technique suitable for mappingsediment–water, intra-water column, or atmosphere–water fluxes. 
    more » « less
  3. ; ; (, Biogeosciences)
    Abstract. The aquatic eddy covariance technique stands out as a powerful method for benthic O2 flux measurements in shelf environments because itintegrates effects of naturally varying drivers of the flux such as current flow and light. In conventional eddy covariance instruments, the timeshift caused by spatial separation of the measuring locations of flow and O2 concentration can produce substantial flux errors that aredifficult to correct. We here introduce a triple O2 sensor eddy covariance instrument (3OEC) that by instrument design eliminates theseerrors. This is achieved by positioning three O2 sensors around the flow measuring volume, which allows the O2concentration to be calculated at the point of the current flow measurements. The new instrument was tested in an energetic coastal environment with highly permeablecoral reef sands colonised by microphytobenthos. Parallel deployments of the 3OEC and a conventional eddy covariance system (2OEC) demonstrate thatthe new instrument produces more consistent fluxes with lower error margin. 3OEC fluxes in general were lower than 2OEC fluxes, and the nighttimefluxes recorded by the two instruments were statistically different. We attribute this to the elimination of uncertainties associated with the timeshift correction. The deployments at ∼ 10 m water depth revealed high day- and nighttime O2 fluxes despite the relatively loworganic content of the coarse sediment and overlying water. High light utilisation efficiency of the microphytobenthos and bottom currents increasingpore water exchange facilitated the high benthic production and coupled respiration. 3OEC measurements after sunset documented a gradual transfer ofnegative flux signals from the small turbulence generated at the sediment–water interface to the larger wave-dominated eddies of the overlying watercolumn that still carried a positive flux signal, suggesting concurrent fluxes in opposite directions depending on eddy size and a memory effect oflarge eddies. The results demonstrate that the 3OEC can improve the precision of benthic flux measurements, including measurements in environmentsconsidered challenging for the eddy covariance technique, and thereby produce novel insights into the mechanisms that control flux. We consider thefluxes produced by this instrument for the permeable reef sands the most realistic achievable with present-day technology. 
    more » « less
  4. ; (, Limnology and Oceanography Letters)
    Abstract Megaripples are current‐generated seafloor bedforms of well‐sorted sand or gravel and wavelengths over 1 m. In this aquatic eddy covariance study, we measured large rates of benthic primary production and respiration for a shallow‐water sandy megaripple field exposed to strong tidally driven currents and intense sunlight. Current and light were the main short‐term drivers of a highly dynamic oxygen exchange. Daytime oxygen release as high as 300 mmol m−2 d−1and nighttime oxygen uptake up to −100 mmol m−2 d−1were likely sustained by current‐driven transport of oxygen, nutrients, and organic matter (fuel) into and out of the sand and superimposed by rapid internal cycling. Seasonal differences in temperature (45%) and light (69%) between April and September were the main long‐term drivers of substantially greater rates of gross primary production and respiration in September. The megaripples functioned as an intense metabolic hotspot with carbon cycling rates larger than those of most near‐shore sediments. 
    more » « less
  5. ; ; (, Limnology and Oceanography: Methods)
    Abstract In shallow coastal systems, sediments are exposed to dramatic and complex variability in environmental conditions that influences sediment processes on short timescales. Sediment oxygen demand (SOD), or consumption of oxygen by sediment‐dwelling organisms and chemical reactions within sediments, is one such process and an important metric of aquatic ecosystem functioning and health. The most common instruments used to measure SOD in situ are batch‐style benthic chambers, which generally require long measurement periods to resolve fluxes and thus do not capture the high temporal variability in SOD that can be driven by dynamic coastal processes. These techniques also preclude linking changes in SOD through time to specific features of the sediment, for example, shifts in sediment faunal activities which can vary on short time scales and can also be affected by ambient oxygen concentrations. Here we present an in situ semi‐flow through instrument to repeatedly measure SOD in discrete areas of sediment. The system isolates patches of sediment in replicate benthic chambers, and measures and records oxygen decrease for a short time before refreshing the overlying water in the chamber with water from the external environment. This results in a sawtooth pattern in which each tooth is an incubation, providing an automated method to produce direct measurements of in situ SOD that can be directly linked to an area of sediment and related to rapid shifts in environmental conditions. 
    more » « less
  • Citation Formats
  • MLA
  • APA
  • Chicago
  • BibTeX
  • Text Encoded Conversion
  • XML
  • Save / Share this Record
  • Send to Email