Coccolithophorid blooms in the global ocean

Brown, Christopher W.; Yoder, James A.

doi:10.1029/93jc02156

Cited by 447 publications

(337 citation statements)

References 66 publications

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“…Yet, the N:P ratio per se does not seem to determine absolute biomass development, and hence the magnitude of the blooms (see also Table 4). Our results are in general agreement with other studies investigating the conditions conducive to coccolithophore bloom development, such as a low dSi:N ratio, shallow mixed layer depth, and increased irradiances (Brown and Yoder, 1994;Painter et al, 2010b). A higher proportion of coccolithophore biomass was associated with higher N:P ratios, even though these ratios were not that high (Table 3).…”

Section: Phytoplankton Community Structuresupporting

confidence: 83%

Phytoplankton community dynamics during late spring coccolithophore blooms at the continental margin of the Celtic Sea (North East Atlantic, 2006–2008)

Oostende

Harlay

Vanelslander

et al. 2012

Progress in Oceanography

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a b s t r a c tWe determined the spatial and temporal dynamics of major phytoplankton groups in relation to biogeochemical and physical variables during the late spring coccolithophore blooms (May-June) along and across the continental margin in the Celtic Sea (2006Sea ( -2008. Photosynthetic biomass (chl a) of the dominant plankton groups was determined by CHEMTAX analysis of chromatographic (HPLC) pigment signatures.Phytoplankton standing stock biomass varied substantially between and during the campaigns (areal chl a [mg chl a m À2 ] in June 2006: 63.8 ± 26.5, May 2007: 27.9 ± 8.4, and May 2008: 41.3 ± 21.8), reflecting the different prevailing conditions of weather, irradiance, and sea surface temperature between the campaigns. Coccolithophores, represented mainly by Emiliania huxleyi, and diatoms were the dominant phytoplankton groups, with a maximal contribution of, respectively, 72% and 89% of the total chl a. Prasinophytes, dinoflagellates, and chrysophytes often co-occurred during coccolithophorid blooms, while diatoms dominated the phytoplankton biomass independently of the biomass of other groups. The location of the stations on the shelf or on the slope side of the continental margin did not influence the biomass and the composition of the phytoplankton community despite significantly stronger water column stratification and lower nutrient concentrations on the shelf. The alternation between diatom and coccolithophorid blooms of similar biomass, following the mostly diatom-dominated main spring bloom, was partly driven by changes in nutrient stoichiometry (N:P and dSi:N). High concentrations of transparent exopolymer particles (TEP) were associated with stratified, coccolithophore-rich water masses, which probably originated from the slope of the continental margin and warmed during advection onto the shelf. Although we did not determine the proportion of export production attributed to phytoplankton groups, the abundance of coccolithophores, together with TEP and coccoliths may affect the carbon export efficiency through increased sinking rates of particles formed by aggregation of TEP and coccoliths.

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Section: Phytoplankton Community Structuresupporting

confidence: 83%

Phytoplankton community dynamics during late spring coccolithophore blooms at the continental margin of the Celtic Sea (North East Atlantic, 2006–2008)

Oostende

Harlay

Vanelslander

et al. 2012

Progress in Oceanography

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“…Coccolithophores may generate large oceanic blooms exceeding 100 000 km 2 in area (Brown and Yoder, 1994;Fernández et al, 1993). Coccolithophore blooms may persist for 3-6 weeks, can act as passive tracers of water movement, and have a variable distribution from year to year (Holligan et al, 1993b).…”

Section: Introductionmentioning

confidence: 99%

The hydrography and biology of a bloom of the coccolithophorid Emiliania huxleyi in the northern North Sea

Head

Crawford

Egge

et al. 1998

Journal of Sea Research

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In June=July 1994 a study was made of a small bloom of the coccolithophorid Emiliania huxleyi in an area of the North Sea to the east of the Shetland Islands. Observations on the hydrography of the study area indicated the bloom was associated with Atlantic water and was confined to an area in which a stable shallow mixed layer had formed. There was no evidence to suggest association of horizontal physical structure with the bloom development. High cell densities of >1-6 ð 10 6 cells dm 3 , together with low concentrations of PIC (<50 µg dm 3 ) and detached liths (2-3 ð 10 4 liths cm 3 ) indicated that the bloom was studied at an early stage of development. Biochemical and physiological observations indicated active growth was taking place. The results presented are discussed in comparison with previous studies carried out in both oceanic and shelf seas.

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“…48 Another consequence is that, in the case of ocean color sensors, a different algorithm needs to be used to estimate their abundance from satellite data. 47 It also means that it is possible to monitor one specific species of phytoplankton, whereas the standard chlorophyll measurements obtained from ocean color do not allow discrimination between different species of phytoplankton. Two effects of the presence of large numbers of coccoliths in the water are first, an increase in the ocean's albedo, and, second, a shading effect that reduces the light level in deeper water (while the scattering of photons increases the light level in the surface waters).…”

Section: Coccolithophoresmentioning

confidence: 99%

“…46 Their importance is probably greatest during a bloom, where their concentrations can reach up to 115 million cells per liter. 47 The most abundant of the species is Emiliania huxleyi, which can be found throughout most of the world's oceans, with the exception of the polar oceans. 48 They can be detected in satellite imagery because the presence of the coccoliths leads to high reflectance in the surface waters due to their intense scattering of light.…”

Section: Coccolithophoresmentioning

confidence: 99%

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Biological Oceanography by Remote Sensing

Srokosz

2000

Encyclopedia of Analytical Chemistry

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Biological oceanography may be studied from space using sensors on satellites that determine the color of the ocean. The presence of phytoplankton (microscopic algae) in the upper layers of the ocean changes the color of the water as seen from above. In simplified terms, this is due to the selective absorption of blue light by the phytoplankton pigments (primarily chlorophyll) which changes the appearance of the water from blue to green. These changes in color can be observed using a satellite‐borne spectroradiometer that measures the water‐leaving radiance in a number of bands in the visible part of the electromagnetic spectrum. The limitations of the technique are first, that only information on the phytoplankton in the upper layers of the ocean can be obtained (light does not penetrate very far into the ocean). Second, most of the signal measured by the satellite sensor originates in the atmosphere (due to the molecular and aerosol scattering of photons there), so careful correction for atmospheric effects is necessary if good ocean data are to be obtained. Of course, in the presence of clouds the sensor will not “see” the ocean surface at all, and no data will be obtained. Third, only one component of the ocean ecosystem, namely the phytoplankton, can be studied by this means. Despite these limitations, satellite observations of ocean color have given new insights into biological oceanography on a global scale that could not have been obtained by any other means of observation. Observations of ocean color have contributed to a better understanding of the biophysical interactions that determine the phytoplankton productivity, the seasonal and interannual variations of the phytoplankton biomass on global scales, and the role of phytoplankton in the climate system. They have also contributed to the improved modeling of biogeochemical processes in the ocean.

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Coccolithophorid blooms in the global ocean

Cited by 447 publications

References 66 publications

Phytoplankton community dynamics during late spring coccolithophore blooms at the continental margin of the Celtic Sea (North East Atlantic, 2006–2008)

Phytoplankton community dynamics during late spring coccolithophore blooms at the continental margin of the Celtic Sea (North East Atlantic, 2006–2008)

The hydrography and biology of a bloom of the coccolithophorid Emiliania huxleyi in the northern North Sea

Biological Oceanography by Remote Sensing

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