Your search keyword '"Eiler, J.M."' showing total 3 results

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

Author

Douglas, P.M.J., Stolper, D.A., Smith, D.A., Walter Anthony, K.M., Paull, C.K., Dallimore, S., Wik, M., Crill, P.M., Winterdahl, M., Eiler, J.M., and Sessions, A.L.

Subjects

*ATMOSPHERIC methane, *POINT sources (Pollution), *GREENHOUSE gases, *BIOGEOCHEMICAL cycles, *GLOBAL warming, *EMISSIONS (Air pollution), *NONLINEAR analysis, *LAKE sediments

Abstract

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 Δ 18 values spanning a range of more than 5‰. [ABSTRACT FROM AUTHOR]

Published

2016

2. Distinguishing and understanding thermogenic and biogenic sources of methane using multiply substituted isotopologues.

Author

Stolper, D.A., Martini, A.M., Clog, M., Douglas, P.M., Shusta, S.S., Valentine, D.L., Sessions, A.L., and Eiler, J.M.

Subjects

*METHANE, *ISOTOPOLOGUES, *SUBSTITUTION reactions, *STABLE isotopes, *GEOTHERMOMETERS

Abstract

Sources of methane to sedimentary environments are commonly identified and quantified using the stable isotopic compositions of methane. The methane “clumped-isotope geothermometer”, based on the measurement of multiply substituted methane isotopologues ( 13 CH 3 D and 12 CH 2 D 2 ), shows promise in adding new constraints to the sources and formational environments of both biogenic and thermogenic methane. However, questions remain about how this geothermometer behaves in systems with mixtures of biogenic and thermogenic gases and different biogenic environments. We have applied the methane clumped-isotope thermometer to a mixed biogenic–thermogenic system (Antrim Shale, USA) and to biogenic gas from gas seeps (Santa Barbara and Santa Monica Basin, USA), a pond on the Caltech campus, and methanogens grown in pure culture. We demonstrate that clumped-isotope based temperatures add new quantitative constraints to the relative amounts of biogenic vs. thermogenic gases in the Antrim Shale indicating a larger proportion (∼50%) of thermogenic gas in the system than previously thought. Additionally, we find that the clumped-isotope temperature of biogenic methane appears related to the environmental settings in which the gas forms. In systems where methane generation rates appear to be slow (e.g., the Antrim Shale and gas seeps), microbial methane forms in or near both internal isotopic equilibrium and hydrogen-isotope equilibrium with environmental waters. In systems where methane forms rapidly, microbial methane is neither in internal isotopic equilibrium nor hydrogen-isotope equilibrium with environmental waters. A quantitative model of microbial methanogenesis that incorporates isotopes is proposed to explain these results. [ABSTRACT FROM AUTHOR]

Published

2015

3. Combined 13C–D and D–D clumping in methane: Methods and preliminary results.

Author

Stolper, D.A., Sessions, A.L., Ferreira, A.A., Santos Neto, E.V., Schimmelmann, A., Shusta, S.S., Valentine, D.L., and Eiler, J.M.

Subjects

*METHANE, *STABLE isotopes, *ISOTOPOLOGUES, *GEOCHEMISTRY, *MASS spectrometry, *GEOTHERMOMETERS

Abstract

Abstract: The stable isotopic composition of methane (e.g., δD and δ13C values) is often used as a tracer for its sources and sinks. Conventional δD and δ13C measurements represent the average isotope ratios of all ten isotopologues of methane, though they are effectively controlled by the relative abundances of the three most abundant species: 12CH4, 13CH4, and 12CH3D. The precise relative abundances of the other seven isotopologues remains largely unexplored because these species contain multiple rare isotopes and are thus rare themselves. These multiply substituted (or ‘clumped’) isotopologues each have their own distinctive chemical and physical properties, which could provide additional constraints on the geochemistry of methane. This work focuses on quantifying the abundances of two rare isotopologues, 13CH3D and 12CH2D2, of methane in order to assess their utility as a window into methane’s geochemistry. Specifically, we seek to assess whether clumped isotope distributions might be useful to quantify the temperature at which methane formed and/or equilibrated. To this end, we report the first highly precise combined measurements of the relative abundances of 13CH3D and 12CH2D2 at natural abundances (i.e., unlabeled) via the high-resolution magnetic-sector mass spectrometry of intact methane. We calibrate the use of these measurements as a geothermometer using both theory and experiment, and apply this geothermometer to representative natural samples. The method yields accurate average (i.e., bulk) isotopic ratios based on comparison with conventional techniques. We demonstrate the accuracy and precision of measurements of 13CH3D and 12CH2D2 through analyses of methane driven to high temperature (>200°C) equilibrium in the laboratory. Application of this thermometer to natural samples yields apparent temperatures consistent with their known formation environments and appears to distinguish between biogenic and thermogenic methane. [Copyright &y& Elsevier]

Published

2014