Microbially-driven formation of Cenozoic siderite and calcite concretions from eastern Austria

Baumann, Lydia; Birgel, Daniel; Wagreich, Michael; Peckmann, Jörn

doi:10.17738/ajes.2016.0016

Cited by 8 publications

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“…While there are studies looking at crystal morphology and isotopic composition of modern and ancient siderites (Abdul Hadi & Astin, ; Allison & Pye, ; Baumann et al, ; Moore, Ferrell, & Aharon, ; Raiswell & Fisher, ; Wittkop et al, ), and separate studies trying to nucleate siderite biotically or abiotically in the laboratory (Köhler, Konhauser, Papineau, Bekker, & Kappler, ; Mortimer, Galsworthy, Bittrell, Wilmot, & Newton, ; Mortimer & Coleman, ; Sanchez‐Roman et al, ), there are few studies that couple the analysis of modern siderite to laboratory experiments trying to grow it. In the East Anglian salt marshes (particularly along the north Norfolk coast, in the salt marshes named Warham, Stiffkey, and Blakeney), there are large siderite concretions (up to 20 cm in diameter) found actively growing in the sediment (Figure ).…”

Section: Introductionmentioning

confidence: 99%

“…A pH lower than 6 means carbonate precipitation will be significantly delayed, and if the pore fluid pH is greater than 7.2, precipitation of calcite or aragonite is favored (Roberts et al, 2013). The formation of siderite is often assumed to involve microbially mediated chemical reactions, such as bacterial iron reduction, that produce dissolved iron and generate alkalinity through the oxidation of organic carbon (Baumann, Birgel, Wargreich, & Peckmann, 2016;Van Lith et al, 2003;Roberts et al, 2013;Sel, Radha, Dideriksen, & Navrotsky, 2012). However, bacterial iron reduction alone tends to push the pH of the pore fluid higher than 7.2 (Soetaert, Hofmann, Middleberg, Meysman, & Greenwood, 2007;Zeng & Tice, 2014), which means that for siderite to form, more is needed than simply local conditions that favor bacterial iron reduction.…”

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confidence: 99%

“…Despite some early studies exploring the mineralogy and solid-phase geochemistry of the siderite concretions in these salt marsh sediments, there has been less attention paid to the interplay between the microbes and aqueous geochemistry that leads to the precipitation of siderite (Allison & Pye, 1994;Coleman, Hedrick, Lovley, White, & Pye, 1993;Pye, 1984;Pye, Dickinson, Schiavon, Coleman, & Cox, 1990). Previous studies attribute the formation and growth of siderite concretions to high rates of "bacterial activity,' high organic matter content, tidal pumping, and high sedimentation rate (Baumann et al, 2016;Coleman, 1993;Pye, 1984;Pye et al, 1990). In this study, we examine the mineralogy and elemental distributions of siderite concretions collected from the East Anglian salt marsh sediment, particularly those of the Warham salt marshes, to better understand the geochemical conditions during concretion nucleation and subsequent growth.…”

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The microbially driven formation of siderite in salt marsh sediments

et al. 2019

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We employ complementary field and laboratory‐based incubation techniques to explore the geochemical environment where siderite concretions are actively forming and growing, including solid‐phase analysis of the sediment, concretion, and associated pore fluid chemistry. These recently formed siderite concretions allow us to explore the geochemical processes that lead to the formation of this less common carbonate mineral. We conclude that there are two phases of siderite concretion growth within the sediment, as there are distinct changes in the carbon isotopic composition and mineralogy across the concretions. Incubated sediment samples allow us to explore the stability of siderite over a range of geochemical conditions. Our incubation results suggest that the formation of siderite can be very rapid (about two weeks or within 400 hr) when there is a substantial source of iron, either from microbial iron reduction or from steel material; however, a source of dissolved iron is not enough to induce siderite precipitation. We suggest that sufficient alkalinity is the limiting factor for siderite precipitation during microbial iron reduction while the lack of dissolved iron is the limiting factor for siderite formation if microbial sulfate reduction is the dominant microbial metabolism. We show that siderite can form via heated transformation (at temperature 100°C for 48 hr) of calcite and monohydrocalcite seeds in the presence of dissolved iron. Our transformation experiments suggest that the formation of siderite is promoted when carbonate seeds are present.

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The microbially driven formation of siderite in salt marsh sediments

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“…Bulbous structures (e.g., structure b in Figure 1) are embedded in the host rock of the stick-like structures. They are here interpreted as concretions, intended as confined bodies of clastic sediment lithified by authigenic minerals [57]. On Earth, formation of concretions is commonly mediated by biogenic processes such as microbial activity and the presence of organic matter-including mucus on burrow walls [58]-but fully abiotic processes can also explain the origin of some concretions [59].…”

Section: Discussionmentioning

confidence: 99%

Ichnofossils, Cracks or Crystals? A Test for Biogenicity of Stick-Like Structures from Vera Rubin Ridge, Mars

et al. 2020

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New images from Mars rover Curiosity display millimetric, elongate stick- like structures in the fluvio-lacustrine deposits of Vera Rubin Ridge, the depositional environment of which has been previously acknowledged as habitable. Morphology, size and topology of the structures are yet incompletely known and their biogenicity remains untested. Here we provide the first quantitative description of the Vera Rubin Ridge structures, showing that ichnofossils, i.e., the product of life-substrate interactions, are among their closest morphological analogues. Crystal growth and sedimentary cracking are plausible non-biological genetic processes for the structures, although crystals, desiccation and syneresis cracks do not typically present all the morphological and topological features of the Vera Rubin Ridge structures. Morphological analogy does not necessarily imply biogenicity but, given that none of the available observations falsifies the ichnofossil hypothesis, Vera Rubin Ridge and its sedimentary features are here recognized as a privileged target for astrobiological research.

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“…Calcite was dissolved by a late diagenetic process, i.e. pore water chemistry was already independent from open water chemistry (Baumann et al 2016). 5.…”

Section: Processes and Causesmentioning

confidence: 99%

A calcite crisis unravelling Early Miocene (Ottnangian) stratigraphy in the North Alpine–Carpathian Foreland Basin: a litho- and chemostratigraphic marker for the Rzehakia Lake System

Palzer-Khomenko¹,

Wagreich²,

Knierzinger³

et al. 2018

Geologica Carpathica

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Within the Lower Austrian part of the North Alpine Foreland Basin (NAFB), up to 1000 m of sediments were deposited throughout the Ottnangian (Early Miocene, Burdigalian). According to homogeneous compositions and sparse biostratigraphic resolution, a consistent stratigraphic concept from the basin margins into the foreland depocenter was still lacking. New investigations on several deep drill cores throughout the basin provide comprehensive sedimentological, mineralogical, chemical and micropaleontological data. A calcite poor, fossil- and pyrite-free, smectite-rich, up to 800 m thick interval was identified and correlated to the time interval of the late Ottnangian brackish Rzehakia Lake System. For this section, we introduce the term Calcite Minimum Interval (CMI). We define the onset of the CMI by a sharp decrease of calcite contents and the disappearance of autochthonous (and reworked) calcareous nannofossils. We define the termination of the CMI by the permanent increase of pyrite contents and the reappearance of calcareous nannofossils. The CMI as a litho- and chemostratigraphical marker for the Rzehakia Lake System constitutes a stratigraphic key horizon. Within the NAFB in Lower Austria, its onset corresponds to the middle/upper Ottnangian transition while its termination correlates roughly to the Ottnangian / Karpatian boundary. This allows a precise definition, identification and correlation of (upper) Ottnangian stratigraphic units of the NAFB. For the central basinal parts of the Rzehakia Lake System, we introduce the new lithostratigraphic term Wildendürnbach Formation which correlates to the marginal Traisen Formation.

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Microbially-driven formation of Cenozoic siderite and calcite concretions from eastern Austria

Cited by 8 publications

References 71 publications

The microbially driven formation of siderite in salt marsh sediments

The microbially driven formation of siderite in salt marsh sediments

Ichnofossils, Cracks or Crystals? A Test for Biogenicity of Stick-Like Structures from Vera Rubin Ridge, Mars

A calcite crisis unravelling Early Miocene (Ottnangian) stratigraphy in the North Alpine–Carpathian Foreland Basin: a litho- and chemostratigraphic marker for the Rzehakia Lake System

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