E. ATEKWANA

Biogeophysics: A New Frontier in Earth Science Research

This paper introduces the concept of biogeophysics, how geophysics can help in detection of microbes and the properties of microbes that makes it possible for geophysical methods to be used in this case. Major properties are: biofilm, metabolic byproducts, redox processes, magnetotactic bacteria. It tells about biogeochemical transformations like microbe mediated reactions. It proposes the studies of deep ocean, cryosphere, extraterrestrial life using biogeophysics.

Acoustic and electrical property changes due to microbial growth and biofilm formation in porous media

This paper explains about a laboratory study that was conducted to investigate the effect of microbial growth and biofilm formation on compressional waves, and complex conductivity during stimulated microbial growth. It discusses the temporal variability of complex conductivity, spatial variability of  acoustic properties and effect of biofilm structure and development on acoustic properties.

The Microbial Community Structure in Petroleum-Contaminated Sediments Corresponds to Geophysical Signatures

This paper suggests the use of geoelectrical measurements as a cost-efficient tool to guide microbiological sampling for microbial ecology studies during the monitoring of natural or engineered bioremediation processes as changes in the geophysical properties of contaminated sediments

parallel changes in the microbial community compositions.

Evidence for microbial enhanced electrical conductivity in hydrocarbon­

contaminated sediments

Bulk electrical conductivity of sediments during microbial mineralization of diesel was investigated in a mesoscale laboratory experiment consisting of biotic

contaminated and uncontaminated columns. This study suggests that geophysical methodologies may potentially be used to investigate microbial activity.

Sensitivity of geoelectrical measurements to the presence

of bacteria in porous media

The study showed a correlation between imaginary conductivity and microbial concentration. It reports the low frequency electrical response to measure density of cells and distinction between live and dead cells.

Geophysical Signatures of Microbial Activity

at Hydrocarbon Contaminated Sites: A Review

This paper suggests that microbial processes alter the contaminated environment causing changes in the petrophysical properties, solute concentration of pore fluids, and temperature. Geophysical techniques such as electrical resistivity, induced polarization, electromagnetic induction, ground penetrating radar, and self potential can define the contaminated zones because of the new physical properties imparted by microbial processes. The changes in the physical properties of the contaminated environment vary spatially because microbial processes depend on the spatial distribution of the contaminant.

LEE SLATER

Pore­scale spectral induced polarization signatures associated with FeS biomineral
transformations

The low-­frequency (0.1–10 Hz peak) relaxations produced during biomineralization is modeled with a Cole­-Cole formulation, from which the evolution of the polarization magnitude and relaxation length scale can be estimated. It concludes that SIP signatures are diagnostic of pore-­scale geometrical changes associated with FeS biomineralization by sulfate reducing bacteria.

Spectral induced polarization and electrodic potential monitoring of microbially
mediated iron sulfide transformations

SIP model parameters based on a Cole­Cole relaxation model  of the polarization at the mineral­fluid interface were converted to estimated biomineral surface area to pore volume(Sp), and an equivalent polarizable sphere diameter(d) controlling the relaxation time. A laboratory column experiments to investigate the geoelectrical response of iron sulfide transformations by Desulfovibrio vulgaris was conducted. Spectral induced polarization (SIP), and electrodic potential measurements, were used for investigation.

ANDRE REVIL

A new model for the spectral induced polarization signature
of bacterial growth in porous media

This work develops a quantitative model to investigate the frequency domain induced polarization response of suspensions of bacteria and bacteria growth in porous media. It shows that the growth rate and endogenous decay

coefficients of bacteria in a porous sand can be inferred non-intrusively from time-lapse frequency domain induced polarization data.

CHI ZHANG

Improving Interpretation of geoelectrical signatures arising from biomineralization process in porous media: Low frequency dielectric spectroscopy measurements on Desulfovibrio vulgaris cell suspensions

This work studied low frequency dielectric properties of sulfate-­reducing bacteria. The results provide insights into the likely contribution of the cells themselves to biogeophysical signals observed during biomineralization processes.

Monitoring microbial sulfate reduction in porous media using multipurpose
electrodes

In this study, reactive electrode measurements were combined to electrical geophysical measurements during microbial sulfate reduction occurring in a column of silica beads saturated with natural river water. Electrodic potential (EP), self potential (SP) and complex conductivity signals were recorded.The results suggest that the implementation of multipurpose electrodes, combining reactive measurements with electrical geophysical measurements, could improve efforts to monitor

microbial processes in the Earth using electrodes.