Carbon dioxide concentration dictates alternative methanogenic pathways in oil reservoirs

Deep subsurface formations (for example, high-temperature oil reservoirs) are candidate sites for carbon capture and storage technology. However, very little is known about how the subsurface microbial community would respond to an increase in CO2 pressure resulting from carbon capture and storage. Here we construct microcosms mimicking reservoir conditions (55 °C, 5 MPa) using high-temperature oil reservoir samples. Methanogenesis occurs under both high and low CO2 conditions in the microcosms. However, the increase in CO2 pressure accelerates the rate of methanogenesis to more than twice than that under low CO2 conditions. Isotope tracer and molecular analyses show that high CO2 conditions invoke acetoclastic methanogenesis in place of syntrophic acetate oxidation coupled with hydrogenotrophic methanogenesis that typically occurs in this environment (low CO2 conditions). Our results present a possibility of carbon capture and storage for enhanced microbial energy production in deep subsurface environments that can mitigate global warming and energy depletion.

[1]  M. Wagner,et al.  Non-Sulfate-Reducing, Syntrophic Bacteria Affiliated with Desulfotomaculum Cluster I Are Widely Distributed in Methanogenic Environments , 2006, Applied and Environmental Microbiology.

[2]  Bernard Ollivier,et al.  Microbiology of petroleum reservoirs , 2000, Antonie van Leeuwenhoek.

[3]  D. Schrag Preparing to Capture Carbon , 2007, Science.

[4]  David W Keith,et al.  Regulating the ultimate sink: managing the risks of geologic CO2 storage. , 2003, Environmental science & technology.

[5]  Karsten Pedersen,et al.  The deep subterranean biosphere , 1993 .

[6]  Saul B. Suslick,et al.  CO2 sequestration through enhanced oil recovery in a mature oil field , 2009 .

[7]  Sarah Brennan,et al.  The urgency of the development of CO2 capture from ambient air , 2012, Proceedings of the National Academy of Sciences.

[8]  Manya Ranjan,et al.  Economic and energetic analysis of capturing CO2 from ambient air , 2011, Proceedings of the National Academy of Sciences.

[9]  Forest Rohwer,et al.  FastGroupII: A web-based bioinformatics platform for analyses of large 16S rDNA libraries , 2006, BMC Bioinformatics.

[10]  David R. Cole,et al.  Gas-water-rock interactions in Frio Formation following CO2 injection: Implications for the storage of greenhouse gases in sedimentary basins , 2006 .

[11]  R. Stuart Haszeldine,et al.  Carbon Capture and Storage: How Green Can Black Be? , 2009, Science.

[12]  M. Kirk Variation in energy available to populations of subsurface anaerobes in response to geological carbon storage. , 2011, Environmental science & technology.

[13]  Jaai Kim,et al.  Group-specific primer and probe sets to detect methanogenic communities using quantitative real-time polymerase chain reaction. , 2005, Biotechnology and bioengineering.

[14]  A. K. Rowan,et al.  Crude-oil biodegradation via methanogenesis in subsurface petroleum reservoirs , 2008, Nature.

[15]  H. Dahle,et al.  Microbial community structure analysis of produced water from a high-temperature North Sea oil-field , 2007, Antonie van Leeuwenhoek.

[16]  J. Dolfing,et al.  Thermodynamic constraints on methanogenic crude oil biodegradation , 2008, The ISME Journal.

[17]  T. Barth Organic acids and inorganic ions in waters from petroleum reservoirs, Norwegian continental shelf: a multivariate statistical analysis and comparison with American reservoir formation waters , 1991 .

[18]  Daisuke Mayumi,et al.  Evidence for syntrophic acetate oxidation coupled to hydrogenotrophic methanogenesis in the high-temperature petroleum reservoir of Yabase oil field (Japan). , 2011, Environmental microbiology.

[19]  T. Barth,et al.  Interactions between organic acids anions in formation waters and reservoir mineral phases , 1992 .

[20]  A. Palmer,et al.  SUMMARY OF THE IPCC SPECIAL REPORT ON CARBON DIOXIDE CAPTURE AND STORAGE , 2006 .

[21]  W. Whitman,et al.  Prokaryotes: the unseen majority. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[22]  Joseph M Suflita,et al.  Methanogenesis, sulfate reduction and crude oil biodegradation in hot Alaskan oilfields. , 2010, Environmental microbiology.

[23]  Hilke Würdemann,et al.  Monitoring of the microbial community composition in saline aquifers during CO2 storage by fluorescence in situ hybridisation , 2010 .

[24]  Y. Kamagata,et al.  Thermacetogenium phaeum gen. nov., sp. nov., a strictly anaerobic, thermophilic, syntrophic acetate-oxidizing bacterium. , 2000, International journal of systematic and evolutionary microbiology.

[25]  P. Claus,et al.  Temporal change of 13C-isotope signatures and methanogenic pathways in rice field soil incubated anoxically at different temperatures , 2004 .

[26]  Catherine A Peters,et al.  Safe storage of CO2 in deep saline aquifers. , 2002, Environmental science & technology.

[27]  S. Goodison,et al.  16S ribosomal DNA amplification for phylogenetic study , 1991, Journal of bacteriology.

[28]  Thomas Huber,et al.  Bellerophon: a program to detect chimeric sequences in multiple sequence alignments , 2004, Bioinform..

[29]  J. Dolfing,et al.  Anomalous energy yields in thermodynamic calculations: importance of accounting for pH-dependent organic acid speciation , 2010, The ISME Journal.

[30]  S. D’Hondt,et al.  Gibbs energies of reaction and microbial mutualism in anaerobic deep subseafloor sediments of ODP Site 1226 , 2010 .