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Carbon and Sulfur Isotopic Signatures of Ancient Life and Environment at the Microbial Scale: Neoarchean Shales and CarbonatesAn approach to coordinated, spatially resolved, in situ carbon isotope analysis of organic matter and carbonate minerals, and sulfur three- and four-isotope analysis of pyrite with an unprecedented combination of spatial resolution, precision, and accuracy is described. Organic matter and pyrite from eleven rock samples of Neoarchean drill core express nearly the entire range of delta(sup 13)C, delta(sup 34)S, Delta(sup 33)S, and Delta(sup 36)S known from the geologic record, commonly in correlation with morphology, mineralogy, and elemental composition. A new analytical approach (including a set of organic calibration standards) to account for a strong correlation between H/C and instrumental bias in SIMS delta(sup 13)C measurement of organic matter is identified. Small (2-3 microns) organic domains in carbonate matrices are analyzed with sub-permil accuracy and precision. Separate 20- to 50-micron domains of kerogen in a single approx. 0.5 cu cm sample of the approx. 2.7 Ga Tumbiana Formation have delta(sup 13)C = −52.3 +/- 0.1per mille and −34.4 +/- 0.1per mille, likely preserving distinct signatures of methanotrophy and photoautotrophy. Pyrobitumen in the approx. 2.6 Ga Jeerinah Formation and the approx. 2.5 Ga Mount McRae Shale is systematically 13C-enriched relative to co-occurring kerogen, and associations with uraniferous mineral grains suggest radiolytic alteration. A large range in sulfur isotopic compositions (including higher Delta(sup 33)S and more extreme spatial gradients in Delta(sup 33)S and Delta(sup 36)S than any previously reported) are observed in correlation with morphology and associated mineralogy. Changing systematics of delta(sup 34)S, Delta(sup 33)S, and Delta(sup 36)S, previously investigated at the millimeter to centimeter scale using bulk analysis, are shown to occur at the micrometer scale of individual pyrite grains. These results support the emerging view that the dampened signature of mass-independent sulfur isotope fractionation (S-MIF) associated with the Mesoarchean continued into the early Neoarchean, and that the connections between methane and sulfur metabolism affected the production and preservation of S-MIF during the first half of the planet's history.
Document ID
20160013889
Acquisition Source
Goddard Space Flight Center
Document Type
Reprint (Version printed in journal)
External Source(s)
Authors
Williford, K. H.
(Jet Propulsion Lab., California Inst. of Tech. Pasadena, CA, United States)
Ushikubo, T.
(Wisconsin Univ. Madison, WI, United States)
Lepot, K.
(Wisconsin Univ. Madison, WI, United States)
Kitajima, K.
(Wisconsin Univ. Madison, WI, United States)
Hallmann, C.
(Massachusetts Inst. of Tech. Cambridge, MA, United States)
Spicuzza, M. J.
(Wisconsin Univ. Madison, WI, United States)
Kozdon, R.
(Wisconsin Univ. Madison, WI, United States)
Eigenbrode, J. L.
(NASA Goddard Space Flight Center Greenbelt, MD United States)
Summons, R. E.
(Massachusetts Inst. of Tech. Cambridge, MA, United States)
Valley, J. W.
(Wisconsin Univ. Madison, WI, United States)
Date Acquired
November 30, 2016
Publication Date
October 24, 2015
Publication Information
Publication: Geobiology
Publisher: Wiley & Sons LTD
Volume: 14
Issue: 2
Subject Category
Lunar And Planetary Science And Exploration
Life Sciences (General)
Report/Patent Number
GSFC-E-DAA-TN27878
Distribution Limits
Public
Copyright
Other
Keywords
isotopic signatures
Earth
carbon and Sulfur

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