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Assessing the impact of a two-layered spherical geometry of phytoplankton cells on the bulk backscattering ratio of marine particulate matter
Duforet-Gaurier, L.; Dessailly, D.; Moutier, W.; Loisel, H. (2018). Assessing the impact of a two-layered spherical geometry of phytoplankton cells on the bulk backscattering ratio of marine particulate matter. Applied Sciences-Basel 8(12): 2689. https://dx.doi.org/10.3390/app8122689
In: Applied Sciences-Basel. MDPI: Basel. e-ISSN 2076-3417, meer
Peer reviewed article  

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Trefwoord
    Marien/Kust
Author keywords
    ocean optics; backscattering ratio; phytoplankton; coated-sphere model;bulk refractive index; seawater component

Auteurs  Top 
  • Duforet-Gaurier, L.
  • Dessailly, D.
  • Moutier, W., meer
  • Loisel, H.

Abstract
    The bulk backscattering ratio (b(bp)(similar to)) is commonly used as a descriptor of the bulk real refractive index of the particulate assemblage in natural waters. Based on numerical simulations, we analyze the impact of modeled structural heterogeneity of phytoplankton cells on b(bp)(similar to). b(bp)(similar to)is modeled considering viruses, heterotrophic bacteria, phytoplankton, organic detritus, and minerals. Three case studies are defined according to the relative abundance of the components. Two case studies represent typical situations in open ocean, oligotrophic waters, and phytoplankton bloom. The third case study is typical of coastal waters with the presence of minerals. Phytoplankton cells are modeled by a two-layered spherical geometry representing a chloroplast surrounding the cytoplasm. The b(bp)(similar to) values are higher when structural heterogeneity is considered because the contribution of coated spheres to light backscattering is higher than homogeneous spheres. The impact of heterogeneity is; however, strongly conditioned by the hyperbolic slope xi of the particle size distribution. Even if the relative abundance of phytoplankton is small (<1%), b(bp)(similar to) increases by about 58% (for xi = 4 and for oligotrophic waters), when the heterogeneity is taken into account, in comparison with a particulate population composed only of homogeneous spheres. As expected, heterogeneity has a much smaller impact (about 12% for xi = 4) on b(bp)(similar to) in the presence of suspended minerals, whose increased light scattering overwhelms that of phytoplankton.

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