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CaCO 3 nucleation by cyanobacteria: laboratory evidence for a passive, surface‐induced mechanism
Author(s) -
OBST M.,
WEHRLI B.,
DITTRICH M.
Publication year - 2009
Publication title -
geobiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.859
H-Index - 72
eISSN - 1472-4669
pISSN - 1472-4677
DOI - 10.1111/j.1472-4669.2009.00200.x
Subject(s) - nucleation , calcite , photosynthesis , cyanobacteria , synechococcus , chemistry , precipitation , supersaturation , chemical engineering , biophysics , mineralogy , geology , biology , biochemistry , bacteria , paleontology , physics , organic chemistry , meteorology , engineering
Calcite nucleation on the surface of cyanobacteria of the Synechococcus leopoliensis strain PCC 7942 was investigated to assess the influence of photosynthetic uptake of inorganic carbon and active ion exchange processes across the cell membrane on the nucleation and precipitation mechanisms. We performed long‐term precipitation experiments at a constant CO 2 level in ambient air by adding suspensions of previously washed cyanobacteria to solutions of NaHCO 3 /CaCl 2 which were supersaturated with respect to calcite. Induction times between 4 and 110 h were measured over a range of saturation states, Ω, between 8 and 4. The kinetics of CaCO 3 nucleation was compared between experiments: (i) with ongoing photosynthesis, (ii) with cells metabolizing but not undergoing photosynthetic uptake of inorganic carbon and (iii) in darkness without photosynthesis. No significant differences were observed between the three treatments. The results reveal that under low nutrient concentrations and permanent CO 2 supply, photosynthetic uptake of inorganic carbon predominantly uses CO 2 and consequently does not directly influence the nucleation process of CaCO 3 at the surface of S. leopoliensis. Furthermore, ion exchange processes did not affect the kinetics, indicating a passive nucleation process wherein the cell surface or extracellular polymers provided preferential sites for mineral nucleation. The catalyzing effect of the cyanobacteria on calcite nucleation was equivalent to a ∼18% reduction in the specific interfacial free energy of the calcite nuclei. This result and the ubiquitous abundance of cyanobacteria suggest that this process may have an impact on local and global carbon cycling.