Microbial processes during early diagenesis of carbonate

H2O + + CO2 O2 S0 + RUBISCO ATP energy + reducing power NADPH Photosystem I + II Calvin Cycle O2 H2O H2S + ...
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Microbial processes during early diagenesis of carbonate reservoirs: A laboratory approach Christophe Dupraz, Marine Sciences/Geosciences, University of Connecticut Microbially-mediated carbon cycle

Photosynthesis Oxygenic CO2

+

RUBISCO ATP

Photosystem I + II

Degassing

energy + reducing power

O2

+



Anoxygenic H2S + CO2

CO2 - Inorg. C

Atmosphere

Calvin Cycle

NADPH

S0 +

Volatilization

H2O

Atmosphere

Org. C

Fermentation

Aerobic O2

H2O

ΔG°’ (kJ/mol CH2O)

-479

Anaerobic

Respiration

Biologically-induced Biomineralization

Microbially-induced precipitation

Metabolic activity (Modification of the microenvironment)

Water Reactants

Products

Mineralization

EPS

Shift in alkalinity due to microbial metabolism

Microbially-influenced precipitation

Environmental pressure (Evaporation, Degassing, alkaline water input)

Water Mineralization EPS

Shift in alkalinity due to the macroenvironment

Ca2+

Biomass

R

R

Ca2+

Adsorption of Ca2+ (and other cations)

Microbial communities are situated at the interface between the biosphere, the lithosphere and the hydrosphere. These microbes are key players in the global carbon cycle, where they influence the balance between the organic and inorganic carbon reservoirs. Microbial populations can be organized in microbial mats, which can be defined as organosedimentary biofilms that are dominated by cyanobacteria, and exhibit tight coupling of element cycles. Complex interactions between mat microbes and their surrounding environment can result in the precipitation of carbonate minerals. This process refers as ‘organomineralization’, which differs from ‘biomineralization’ (e.g., in shells and bones) by lacking genetic control on the mineral product. Organomineralization can be: (1) active, when microbial metabolic reactions are responsible for the precipitation (“biologically-induced” mineralization) or (2) passive, when mineralization within a microbial organic matrix is environmentally driven (e.g., through degassing or desiccation) (“biologically-influenced” mineralization). Studying microbe-mineral interactions is essential to many emerging fields of the biogeoscience, such as the study of life in extreme environments (e.g, deep biosphere), the origin of life, the search for traces of extraterrestrial life or the seek of new carbon sink. This research approach combines sedimentology, biogeochemistry and microbiology. Two tightly coupled components that control carbonate organomineralization s.l.: (1) the alkalinity engine and 2) the extracellular organic matter (EOM), which is ultimately the location of mineral nucleation. Carbonate alkalinity can be altered both by microbial metabolism and environmental factors. The EOM play a critical role in carbonate precipitation by providing Ca2+ and CO32- as well as a nucleation template for mineral growth. Organomineralization is only possible if the inhibition potential is reduced through (1) oversaturation of the EOM binding capacity or (2) Organic matter degradation. This can be investigated using in laboratory experiments.