The volume scattering function of natural bubble populations

Zhang, Xiaodong; Lewis, Marlon R.; Lee, Michael; Johnson, Bruce D.; Коротаев, Г. К.

doi:10.4319/lo.2002.47.5.1273

Cited by 97 publications

(85 citation statements)

References 54 publications

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“…Winter et al, 2014) and be mimicked by the spectral characteristics of other scattering sources. The most important among them are probably microbubbles (Zhang et al, 2002), glacial flour and non-calcifying organisms such as Phaeocystis antarctica (Winter et al, 2014), a colonial prymnesiophyte algae very abundant in high-latitude systems of the Southern Ocean (e.g. Arrigo et al, 1999Arrigo et al, , 2000.…”

Section: Background and Objectivesmentioning

confidence: 99%

Coccolithophore populations and their contribution to carbonate export during an annual cycle in the Australian sector of the Antarctic zone

et al. 2018

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Abstract. The Southern Ocean is experiencing rapid and relentless change in its physical and biogeochemical properties. The rate of warming of the Antarctic Circumpolar Current exceeds that of the global ocean, and the enhanced uptake of carbon dioxide is causing basin-wide ocean acidification. Observational data suggest that these changes are influencing the distribution and composition of pelagic plankton communities. Long-term and annual field observations on key environmental variables and organisms are a critical basis for predicting changes in Southern Ocean ecosystems. These observations are particularly needed, since highlatitude systems have been projected to experience the most severe impacts of ocean acidification and invasions of allochthonous species.

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Section: Background and Objectivesmentioning

confidence: 99%

Coccolithophore populations and their contribution to carbonate export during an annual cycle in the Australian sector of the Antarctic zone

et al. 2018

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“…Volten et al (1998) measured the VSF as well as the F 12 element of the Mueller matrix for 15 different phytoplankton species and 2 different ensembles of silt particles. Lee and Lewis (2003) and Zhang et al (2002) presented a recently developed instrument with the capability of measuring the VSF in the angular range from 0.6°t o 177°. This instrument can be used both for in situ applications and laboratory measurements.…”

mentioning

confidence: 99%

Laboratory measurements of light scattering from marine particles

Lotsberg

Marken

Stamnes

et al. 2007

Limnology & Ocean Methods

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Oceans cover about 70% of the surface of the Earth and represent an important source of food. To obtain information about primary production, propagation of phytoplankton blooms, nutrient status, and temperature, the marine environment is continuously monitored both in situ and from satellites. In this context, in situ optical measurements are indispensable because they are fast and suited for automated routine operation. Among the most commonly measured parameters in situ are the absorption and attenuation coefficients, the diffuse attenuation coefficient for downwelling irradiance, and natural fluorescence. From satellite measurements, one can estimate the water-leaving radiance, and in the laboratory, the chlorophyll concentrations of water samples can be measured by fluorometric or spectrophotometric methods.The volume-scattering function (VSF) is an important optical property that is not routinely measured. Thus, the measurements of Petzold (1977), which date back to the 1970s, are still commonly used to represent the VSF for seawater. Among the laboratory measurements of the VSF relevant for our study, the data obtained by Privoznik et al. (1978) and Morel and Bricaud (1986) AbstractWe present an improved technique for measurements of the volume-scattering function (VSF) for marine particles, which include added spectral information, a novel optical design of the sample container, and two new ways of eliminating unwanted reflections. The novel optical design enables us to measure an angular range comparable to the largest angular range previously reported. Our improved setup eliminates the need for an empirically based data correction and reveals interesting characteristics of the VSF for different phytoplankton species. Measurements with our improved setup provide information that is important to understand and simulate radiative transfer in the ocean.

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“…Within the PhytoDOAS retrieval, such pixels are flagged and not processed by the differential absorption method, because the spectral footprint of the wind-driven whitecaps is almost flat in the visible range (Koepke, 1984). Moreover, contrary to the hypothesis proposed by Zhang et al (2002), suggesting that the storm-induced micro-bubble injection might explain the high reflectance in the so-called region of Great Calcite Belt (between the subtropical front and the northern part of the Subantarctic front), PhytoDOAS coccolithophore results at sAtl and sPac (both located within the Great Calcite Belt) prove that in these regions coccolithophores are indeed highly abundant (the same observation was reported by Eynaud et al (1999) based on the results of a sampling cruise crossing this high reflectance area).…”

Section: Time Series Of Biological and Geophysical Parametersmentioning

confidence: 97%

Remote sensing of coccolithophore blooms in selected oceanic regions using the PhytoDOAS method applied to hyper-spectral satellite data

et al. 2012

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Abstract. In this study temporal variations of coccolithophore blooms are investigated using satellite data. Eight years (from 2003 to 2010) of data of SCIAMACHY, a hyperspectral satellite sensor on-board ENVISAT, were processed by the PhytoDOAS method to monitor the biomass of coccolithophores in three selected regions. These regions are characterized by frequent occurrence of large coccolithophore blooms. The retrieval results, shown as monthly mean time series, were compared to related satellite products, including the total surface phytoplankton, i.e. total chlorophyll a (from GlobColour merged data) and the particulate inorganic carbon (from MODIS-Aqua). The inter-annual variations of the phytoplankton bloom cycles and their maximum monthly mean values have been compared in the three selected regions to the variations of the geophysical parameters: sea-surface temperature (SST), mixed-layer depth (MLD) and surface wind-speed, which are known to affect phytoplankton dynamics. For each region, the anomalies and linear trends of the monitored parameters over the period of this study have been computed. The patterns of total phytoplankton biomass and specific dynamics of coccolithophore chlorophyll a in the selected regions are discussed in relation to other studies. The PhytoDOAS results are consistent with the two other ocean color products and support the reported dependencies of coccolithophore biomass dynamics on the compared geophysical variables. This suggests that PhytoDOAS is a valid method for retrieving coccolithophore biomass and for monitoring its bloom developments in the global oceans. Future applications of time series studies using the PhytoDOAS data set are proposed, also using the new upcoming generations of hyper-spectral satellite sensors with improved spatial resolution.

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The volume scattering function of natural bubble populations

Cited by 97 publications

References 54 publications

Coccolithophore populations and their contribution to carbonate export during an annual cycle in the Australian sector of the Antarctic zone

Coccolithophore populations and their contribution to carbonate export during an annual cycle in the Australian sector of the Antarctic zone

Laboratory measurements of light scattering from marine particles

Remote sensing of coccolithophore blooms in selected oceanic regions using the PhytoDOAS method applied to hyper-spectral satellite data

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