Beam attenuation, scattering and backscattering of marine particles in relation to particle size distribution and composition in <scp>H</scp>udson <scp>B</scp>ay (<scp>C</scp>anada)

Xi, Hongyan; Larouche, Pierre; Michel, Christine; Tang, Shilin

doi:10.1002/2014jc010668

Cited by 17 publications

(18 citation statements)

References 73 publications

(164 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…At LJCO our observations of type 2 waters are similar, while type 1 waters show values lower than these theoretical predictions (Figure ). However, lower than 0.02 values of backscattering ratio are theoretically predicted (Duforêt‐Gaurier et al, ; Twardowski et al, ) and observed (Boss et al, ; Loisel et al, ; McKee & Cunningham, ; Snyder et al, ; Whitmire et al, ; Xi et al, ) in regions dominated by phytoplankton and organic detritus and recently also found in the waters of Yellow and East China Seas dominated on average by 80% of inorganic particles (Sun et al, ). Microscopic imaging of mineral/organic flocs in our study area (Bainbridge et al, ) shows complex particle geometries, which may explain the difference from idealized theoretical prediction based on more regular geometry and no organic matter.…”

Section: Discussionmentioning

confidence: 88%

Particulate Backscattering Ratio as an Indicator of Changing Particle Composition in Coastal Waters: Observations From Great Barrier Reef Waters

et al. 2019

View full text Add to dashboard Cite

Particle scattering is an important process that determines both the light penetration through the water column and water‐leaving light. Backscattering, in combination with absorption, determines the remote‐sensing reflectance that is used in ocean color algorithms. Additionally, the wavelength dependence of the backscattering ratio can be related to the particle composition in seawater. Here, we examine the magnitude and the spectral behavior of the backscattering ratio against other bio‐optical properties based on a comprehensive set of continuous measurements collected in coastal waters of the Great Barrier Reef over 3 years. The site is located offshore of a major river, and close to the cross‐shelf transition of bottom sediments from terrigenous muds to marine carbonates. The backscattering ratio measured at 650 nm clearly clustered the data into two types. Type 1, which we identified as terrigenous mud with a low organic fraction, is characterized by backscattering ratio below 0.011 with a mean value of 0.005. Type 2, which we identified as marine carbonate with a higher organic fraction, has backscattering ratio above 0.011 with a mean value of 0.02. Within 3 years, study site was exposed to type 1‐dominated particles 13% of the time, and type 2 87%. The observed changes in the backscattering ratio at this one coastal site are as large as the variability seen throughout the global ocean. This work provides a better understanding of processes determining the optical characteristics and insights into optical parameterizations that can be used in process‐based optical modeling of the Great Barrier Reef.

show abstract

Section: Discussionmentioning

confidence: 88%

Particulate Backscattering Ratio as an Indicator of Changing Particle Composition in Coastal Waters: Observations From Great Barrier Reef Waters

et al. 2019

View full text Add to dashboard Cite

show abstract

“…For instance, phytoplankton functional types usually vary with size, a finding that has been incorporated into global biogeochemical models and used to assess the ecological feedback to the ocean's carbon In this study, we investigate the variability in PSD in two typically shallow and semi-enclosed seas, the Bohai Sea (BS) and the Yellow Sea (YS), with the following two objectives: (1) to model the PSD of the surface waters; and (2) to characterize the spatial variability and vertical distributions of the PSD. The potential findings by this study are very significant for understanding and documenting the particle size distributions in the BS and the YS, which have been regarded as important factors influencing water inherent optical properties [11,[40][41][42][43], and further changing water color remote sensing signals [44].…”

Section: Introductionmentioning

confidence: 92%

Variability of Particle Size Distributions in the Bohai Sea and the Yellow Sea

Qiu

Sun

et al. 2016

Remote Sensing

View full text Add to dashboard Cite

Particle size distribution (PSD) is an important parameter that is relevant to many aspects of marine ecosystems, such as phytoplankton functional types, optical absorption and scattering from particulates, sediment fluxes, and carbon export. However, only a handful of studies have documented the PSD variability in different regions. Here, we investigate the PSD properties and variability in two shallow and semi-enclosed seas (the Bohai Sea (BS) and Yellow Sea (YS)), using in situ laser diffraction measurements (LISST-100X Type C) and other measurements at 79 stations in November 2013. The results show large variability in particle concentrations (in both volume and number concentrations), with volume concentrations varying by 57-fold. The median particle diameter (D v 50 ) from each of the water samples also covers a large range (22.4-307.0 µm) and has an irregular statistical distribution, indicating complexity in the PSD. The PSD slopes (2.7-4.5), estimated from a power-law model, cover nearly the entire range reported previously for natural waters. Small mineral particles (with large PSD slopes) are characteristic of near-shore waters prone to sediment resuspension by winds and tides, while large biological particles (with small PSD slopes) dominate the total suspended particulates for waters away from the coast. For the BS and YS, this study provides the first report on the properties and spatial variability of the PSD, which may influence the optical properties of the ocean surface and remote sensing algorithms that are based on estimations of particle concentrations and sizes.

show abstract

“…A Wetlabs ac‐s was used to collect profiles of total nonwater beam attenuation, c pg (

λ

), absorption, a pg (

λ

), and dissolved absorption, a g (

λ

), at 86 spectral channels between 400 nm and 737 nm with a spectral resolution of 4 nm and a measurement accuracy ± 0.01 m −1 . Di‐ionized water and air calibrations were performed on this instrument before, during and after data collection periods to ensure instrument precision remained within factory specifications (Xi et al ). On each sampling day, approximately every fourth cast was performed with a 0.2 μm filter attached to the absorption tube of the ac‐s to measure a g (

λ

).…”

Section: Methodsmentioning

confidence: 99%

“…The reported precision error of the calibrated ac‐s is ± 0.005 m −1 (Wetlabs 2015), which we ensured was maintained through water and air calibrations (section Optical profile data analysis). Under low scattering conditions, b p error can be as high as 18% (Piskozub et al ; Martinez‐Vincente et al ; Xi et al ). Error should be lower in our study due to relatively large b p magnitudes.…”

Section: Methodsmentioning

confidence: 99%

Bio-optical variability at a Vancouver Island aquaculture site

et al. 2016

View full text Add to dashboard Cite

Variability of the particulate beam attenuation, scattering, and backscattering coefficients, along with discrete measurements of HPLC derived pigments and particulate organic carbon, is investigated within and beside a finfish aquaculture cage on the west coast of Vancouver Island, Canada. Large bio‐optical variability was observed over three seasons: fall, spring, and summer. The use of multiple optical proxies for organic particle concentrations, bulk particle‐size distributions, and compositions allowed for the characterization of the particle assemblage over the dynamic conditions. Specifically, in fall, low biological productivity and surface influences from runoff were observed. In the lower‐cage, after feeding the fish, optical proxies suggest the dominance of large particles with high indices of refraction, possibly due to the influence of fish fecal particles. Optical variability in spring was driven by diatom bloom conditions (Chaetoceros and Skeletonema). Strong bio‐optical relationships were observed and the optical proxies suggest a particle‐size distribution (PSD) dominated by large particles with low indices of refraction. In turn, summer conditions displayed noticeably high and persistent particulate backscattering in the surface waters, suggesting the presence of an Emiliania huxleyi bloom. Neither spring nor summer showed distinct influences by aquaculture wastes indicating that optical characterization of particulate waste dispersal is likely constrained to low ambient seston conditions. Outside of these conditions bio‐optical analysis would be beneficial for environmental monitoring of ambient particles moving through aquaculture systems.

show abstract

Beam attenuation, scattering and backscattering of marine particles in relation to particle size distribution and composition in Hudson Bay (Canada)

Cited by 17 publications

References 73 publications

Particulate Backscattering Ratio as an Indicator of Changing Particle Composition in Coastal Waters: Observations From Great Barrier Reef Waters

Particulate Backscattering Ratio as an Indicator of Changing Particle Composition in Coastal Waters: Observations From Great Barrier Reef Waters

Variability of Particle Size Distributions in the Bohai Sea and the Yellow Sea

Bio-optical variability at a Vancouver Island aquaculture site

Contact Info

Product

Resources

About