Relationship Between Coccolith Length and Thickness in the Coccolithophore Species Emiliania Huxleyi and Gephyrocapsa Oceanica

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2019 Aug 6

PMID 31381588

Citations 5

Authors

Simen Alexander Linge Johnsen

Jorg Bollmann

Christina Gebuehr

Jens O Herrle

Affiliations

Soon will be listed here.

Abstract

Coccolith mass is an important parameter for estimating coccolithophore contribution to carbonate sedimentation, organic carbon ballasting and coccolithophore calcification. Single coccolith mass is often estimated based on the ks model, which assumes that length and thickness increase proportionally. To evaluate this assumption, this study compared coccolith length, thickness, and mass of seven Emiliania huxleyi strains and one Gephyrocapsa oceanica strain grown in 25, 34, and 44 salinity artificial seawater. While coccolith length increased with salinity in four E. huxleyi strains, thickness did not increase significantly with salinity in three of these strains. Only G. oceanica showed a consistent increase in length with salinity that was accompanied by an increase in thickness. Coccolith length and thickness was also not correlated in 14 of 24 individual experiments, and in the experiments in which there was a positive relationship r2 was low (<0.4). Because thickness did not increase with length in E. huxleyi, the increase in mass was less than expected from the ks model, and thus, mass can not be accurately estimated from coccolith length alone.

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