Your search keyword '"Peter M. J. Douglas"' showing total 2 results

1. Methane clumped isotopes in the Songliao Basin (China): New insights into abiotic vs. biotic hydrocarbon formation

Author

Giuseppe Etiope, Ling Huang, Peter M. J. Douglas, John M. Eiler, Yanhua Shuai, and Shuichang Zhang

Subjects

chemistry.chemical_classification, Abiotic component, 010504 meteorology & atmospheric sciences, business.industry, Geochemistry, 010502 geochemistry & geophysics, 01 natural sciences, Methane, Catagenesis (geology), Carbon cycle, Paleontology, chemistry.chemical_compound, Geophysics, Hydrocarbon, Source rock, chemistry, Space and Planetary Science, Geochemistry and Petrology, Ultramafic rock, Natural gas, Earth and Planetary Sciences (miscellaneous), business, Geology, 0105 earth and related environmental sciences

Abstract

Abiotic hydrocarbon gas, typically generated in serpentinized ultramafic rocks and crystalline shields, has important implications for the deep biosphere, petroleum systems, the carbon cycle and astrobiology. Distinguishing abiotic gas (produced by chemical reactions like Sabatier synthesis) from biotic gas (produced from degradation of organic matter or microbial activity) is sometimes challenging because their isotopic and molecular composition may overlap. Abiotic gas has been recognized in numerous locations on the Earth, although there are no confirmed instances where it is the dominant source of commercially valuable quantities in reservoir rocks. The deep hydrocarbon reservoirs of the Xujiaweizi Depression in the Songliao Basin (China) have been considered to host significant amounts of abiotic methane. Here we report methane clumped-isotope values (Δ_(18)) and the isotopic composition of C_1–C_3 alkanes, CO_2 and helium of five gas samples collected from those Xujiaweizi deep reservoirs. Some geochemical features of these samples resemble previously suggested identifiers of abiotic gas (^(13)C-enriched CH_4; decrease in ^(13)C/^(12)C ratio with increasing carbon number for the C1–C4 alkanes; abundant, apparently non-biogenic CO_2; and mantle-derived helium). However, combining these constraints with new measurements of the clumped-isotope composition of methane and careful consideration of the geological context, suggests that the Xujiaweizi depression gas is dominantly, if not exclusively, thermogenic and derived from over-mature source rocks, i.e., from catagenesis of buried organic matter at high temperatures. Methane formation temperatures suggested by clumped-isotopes (167–213 °C) are lower than magmatic gas generation processes and consistent with the maturity of local source rocks. Also, there are no geological conditions (e.g., serpentinized ultramafic rocks) that may lead to high production of H_2 and thus abiotic production of CH_4 via CO_2 reduction. We propose that the Songliao gas is representative of an atypical type of thermogenic gas that can be mistaken for abiotic gas. Such gases may be encountered more frequently in future exploration of deep or over-mature petroleum systems.

Published

2018

2. Diverse origins of Arctic and Subarctic methane point source emissions identified with multiply-substituted isotopologues

Author

Peter M. J. Douglas, Alex L. Sessions, Scott R. Dallimore, K. M. Walter Anthony, Mathias Winterdahl, Daniel A. Stolper, Patrick M. Crill, John M. Eiler, Charles K. Paull, Martin Wik, and Derek Smith

Subjects

Geochemistry & Geophysics, Biogeochemical cycle, 010504 meteorology & atmospheric sciences, Methanogenesis, 010502 geochemistry & geophysics, 01 natural sciences, Methane, Physical Geography and Environmental Geoscience, Carbon cycle, chemistry.chemical_compound, Arctic, Geochemistry and Petrology, Life Below Water, 0105 earth and related environmental sciences, biology, Atmospheric methane, Geology, biology.organism_classification, Methanogen, Clumped isotope geochemistry, Greenhouse gases, Geochemistry, chemistry, Greenhouse gas, Environmental chemistry

Abstract

© 2016 Elsevier Ltd. Methane is a potent greenhouse gas, and there are concerns that its natural emissions from the Arctic could act as a substantial positive feedback to anthropogenic global warming. Determining the sources of methane emissions and the biogeochemical processes controlling them is important for understanding present and future Arctic contributions to atmospheric methane budgets. Here we apply measurements of multiply-substituted isotopologues, or clumped isotopes, of methane as a new tool to identify the origins of ebullitive fluxes in Alaska, Sweden and the Arctic Ocean. When methane forms in isotopic equilibrium, clumped isotope measurements indicate the formation temperature. In some microbial methane, however, non-equilibrium isotope effects, probably related to the kinetics of methanogenesis, lead to low clumped isotope values. We identify four categories of emissions in the studied samples: thermogenic methane, deep subsurface or marine microbial methane formed in isotopic equilibrium, freshwater microbial methane with non-equilibrium clumped isotope values, and mixtures of deep and shallow methane (i.e., combinations of the first three end members). Mixing between deep and shallow methane sources produces a non-linear variation in clumped isotope values with mixing proportion that provides new constraints for the formation environment of the mixing end-members. Analyses of microbial methane emitted from lakes, as well as a methanol-consuming methanogen pure culture, support the hypothesis that non-equilibrium clumped isotope values are controlled, in part, by kinetic isotope effects induced during enzymatic reactions involved in methanogenesis. Our results indicate that these kinetic isotope effects vary widely in microbial methane produced in Arctic lake sediments, with non-equilibrium δ18values spanning a range of more than 5‰.

Published

2016