Your search keyword '"Allwood, Abigail C."' showing total 4 results

1. Controls on Development and Diversity of Early Archean Stromatolites

Author

Allwood, Abigail C., Grotzinger, John P., Knoll, Andrew H., Burch, Ian W., Anderson, Mark S., Coleman, Max L., and Kanik, Isik

Published

2009

2. Microbially influenced formation of Neoarchean ooids.

Author

Flannery, David T., Allwood, Abigail C., Hodyss, Robert, Summons, Roger Everett, Tuite, Michael, Walter, Malcolm R., and Williford, Kenneth H.

Subjects

*NEOARCHAEAN, *STROMATOLITES, *CARBONATE rocks, *ORGANIC compounds, *RAMAN spectroscopy

Abstract

Ooids are accretionary grains commonly reported from turbulent, shallow‐water environments. They have long been associated with microbially dominated ecosystems and often occur in close proximity to, or embedded within, stromatolites, yet have historically been thought to form solely through physicochemical processes. Numerous studies have revealed both constructive and destructive roles for microbes colonizing the surfaces of modern calcitic and aragonitic ooids, but there has been little evidence for the operation of these processes during the Archean and Proterozoic, when both ooids and microbially dominated ecosystems were more widespread. Recently described carbonate ooids from the 2.9 Ga Pongola Supergroup, South Africa, include well‐preserved examples composed of diagenetic dolomite interpreted to have formed from a high‐Mg‐calcite precursor. Spatial distributions of organic matter and elements associated with metabolic activity (N, S, and P) were interpreted as evidence for a biologically induced origin. Here, we describe exceptionally well‐preserved ooids composed of calcite, collected from Earth's oldest known carbonate lake system, the ~2.72 Ga Meentheena Member (Tumbiana Formation), Fortescue Group, Western Australia. We used optical microscopy, Raman spectroscopy, XRD, SEM‐EDS, LA‐ICP‐MS, EA‐IRMS, and a novel micro‐XRF instrument to investigate an oolite shoal deposited between stromatolites that preserve abundant evidence for microbial activity. We report an extremely fine, radial‐concentric, calcitic microfabric that is similar to the primary and early diagenetic fabrics of calcitic ooids reported from modern temperate lakes. Early diagenetic silica has trapped isotopically light and thermally mature organic matter. The close association of organic matter with mineral phases and microfabrics related to primary and early diagenetic processes suggest incorporation of organic matter occurred during accretion, likely due to the presence of microbial biofilms. We conclude that the oldest known calcitic ooids were likely formed through processes similar to those that mediate the accretion of ooids in similar environments today, including formation within a microbial biosphere. [ABSTRACT FROM AUTHOR]

Published

2019

3. Sulfur isotopes of organic matter preserved in 3.45-billion-year-old stromatolites reveal microbial metabolism.

Author

Bontognali, Tonnaso R. R., Sessions, Alex L., Allwood, Abigail C., Fischer, Woodward W., Grotzinger, John P., Summons, Roger E., and Eiler, John M.

Subjects

SULFUR isotopes, ORGANIC compounds, STROMATOLITES, MICROBIAL metabolism, GEOLOGICAL formations, PALEONTOLOGY

Abstract

The 3.45-billion-year-old Strelley Pool Formation of Western Australia preserves stromatolites that are considered among the oldest evidence for life on Earth. In places of exceptional preservation, these stromatolites contain laminae rich in organic carbon, interpreted as the fossil remains of ancient microbial mats. To better understand the biogeochemistry of these rocks, we performed microscale in situ sulfur isotope measurements of the preserved organic sulfur, including both Δ33S and &delta34SCDT. This approach allows us to tie physiological inference from isotope ratios directly to fossil biomass, providing a means to understand sulfur metabolism that is complimentary to, and independent from, inorganic proxies (e.g., pyrite). Δ33S values of the kerogen reveal mass-anomalous fractionations expected of the Archean sulfur cycle, whereas &delta34SCDT values show large fractionations at very small spatial scales, including values below -15‰. We interpret these isotopic patterns as recording the process of sulf urization of organic matter by H2S in heterogeneous mat pore-waters influenced by respiratory S metabolism. Positive Δ33S anomalies suggest that dispro-portionation of elemental sulfur would have been a prominent microbial process in these communities. [ABSTRACT FROM AUTHOR]

Published

2012

4. Reappraisal of purported ca. 3.7 Ga stromatolites from the Isua Supracrustal Belt (West Greenland) from detailed chemical and structural analysis.

Author

Zawaski, Mike J., Kelly, Nigel M., Orlandini, Omero Felipe, Nichols, Claire I.O., Allwood, Abigail C., and Mojzsis, Stephen J.

Subjects

*STROMATOLITES, *SEDIMENTARY structures, *ANALYTICAL chemistry, *METAMORPHIC rocks, *QUARTZ, *ARABINOXYLANS, *ELECTRON diffraction, *SILICATE minerals

Abstract

• Claimed ca. 3.7 Ga Isua stromatolites are instead granoblastic quartz + dolomite boudins. • Absence of internal convex upward laminae precludes classification as stromatolites. • 3-D structural analysis reveals the boudins form ridges parallel to regional deformation. • Parallel micro- and macro-structural and chemical analyses are essential to assess biogenicity of any proposed bio-structures in ancient, deformed terranes. The biogenicity of proposed stromatolite structures from Eoarchean (ca. 3.71 Ga) rocks of the Isua Supracrustal Belt (ISB) in West Greenland is under debate. The structures in question are found within a suite of multiply deformed greenschist- to amphibolite-facies metamorphic rocks. To assess their premise as primary sedimentary features – as opposed to products of strain localization in layered, variably ductile rocks – we report new field mapping at the appropriate scale and resolution from the original discovery Sites reported by Nutman et al. (2016). Our new map was used to guide micro- and macro-structural investigations and comprehensive geochemical sampling. Here, we report detailed field characterization and structural analysis to show that the structures are linear inverted ridges aligned with azimuths of local and regional fold axes and parallel to linear structures; they are not deformed conical stromatolites. Combined major element (e.g., Ca, Mg, Si) scanning μXRF maps, and electron backscatter diffraction (EBSD) patterns collected on fresh surfaces cut perpendicular and parallel to the ridges attest to the lack of any residual sedimentary laminae (e.g., compositional layering) within these structures' cores. Internal layering previously inferred for these features instead arises from variable weathering of outcrop surfaces that otherwise conceals granoblastic quartz ± dolomite cored boudins that sit between semi-continuous competent layers of enveloping quartzite in a calc-silicate schist. The morphology of boudins reflects viscosity contrasts of the different ductile layers during deformation. Therefore, these features are not of sedimentary origin. Furthermore, discontinuous field relationships and absence of primary sedimentary structures that could serve as way-up indicators preclude confident assignment of these outcrops as being structurally overturned, as originally argued. Collectively, our results show that the Isua structures are the expected result of a tectonic fabric that preserves no fine-scale primary sedimentary structures and were probably never stromatolites. [ABSTRACT FROM AUTHOR]

Published

2020