Early post-mortem formation of carbonate concretions around tusk-shells over week-month timescales

Yoshida, Hidekazu; Ujihara, Atsushi; Minami, Masayo; Asahara, Yoshihiro; Katsuta, Nagayoshi; Yamamoto, Koshi; Sirono, Sin-iti; Maruyama, Isao; Nishimoto, Shoji; Metcalfe, Richard

doi:10.1038/srep14123

Cited by 60 publications

(51 citation statements)

References 23 publications

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“…Spherical, isolated carbonate concretions occur throughout the world in marine argillaceous sedimentary rocks of widely varying geological ages. These concretions are characteristically highly enriched in CaCO 3 compared to the surrounding sedimentary rock matrices and are typically separated from these rock matrices by sharp boundaries 1 – 3 . These sharp boundaries mean that the isolated carbonate concretions are readily identifiable and both geologists and non-scientists alike have been motivated to consider how such concretions could have formed.…”

Section: Introductionmentioning

confidence: 99%

“…It is also known that many of these concretions have various kinds of well-preserved fossils at their centres 3 . Isotopic analyses have been used to identify the source of carbon that formed the concretions 4 – 6 and to understand the diagenetic processes, including microbial activity, that occurred during sediment burial and concretion formation 1 , 7 , 8 .…”

Section: Introductionmentioning

confidence: 99%

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Generalized conditions of spherical carbonate concretion formation around decaying organic matter in early diagenesis

Yoshida

Yamamoto

Minami

et al. 2018

Sci Rep

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Isolated spherical carbonate concretions observed in marine sediments are fascinating natural objet trouve because of their rounded shapes and distinct sharp boundaries. They occur in varied matrices and often contain well preserved fossils. The formation process of such concretions has been explained by diffusion and rapid syn-depositional reactions with organic solutes and other pore water constituents. However, the rates, conditions and formation process of syngenetic spherical concretions are still not fully clear. Based on the examination of different kinds of spherical concretions from several locations in Japan, a diffusion based growth diagram was applied to define the generalized growth conditions of spherical concretions formed around decaying organic matter. All analytical data imply that the spherical concretions formed very rapidly, at least three to four orders of magnitude faster than previously estimated timescales. The values indicate that spherical concretions are preferentially grown within clay- to silt-grade marine sediments deposited in relatively deep (a few tens of metres) environments dominated by diffusive solute transport, very early in diagenesis.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Generalized conditions of spherical carbonate concretion formation around decaying organic matter in early diagenesis

Yoshida

Yamamoto

Minami

et al. 2018

Sci Rep

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“…In particular, the widespread presence of dolomite concretions enclosing many fossil vertebrates of the Pisco Formation has been recently recognized. The formation of mineral concretions during early diagenesis as a consequence of biomediated processes related to organic matter decay has been described elsewhere (McCoy et al, 2015;Yoshida et al, 2015). In the Pisco Formation, early precipitation of dolomite around vertebrate carcasses, although not always present, has been pointed out for its major contribution in allowing the preservation of complete and articulated skeletons, delicate anatomical structures, and even soft organic tissues (Gariboldi et al, 2015;Gioncada et al, 2016Gioncada et al, , 2018.…”

Section: Introductionmentioning

confidence: 99%

Looking for the key to preservation of fossil marine vertebrates in the Pisco Formation of Peru: new insights from a small dolphin skeleton

Gioncada

Gariboldi

Collareta

et al. 2018

andgeo

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The upper Neogene Pisco Formation of Peru is known worldwide as one of the most significant Cenozoic marine vertebrate Konservatt-Lagerstätten, even featuring cetacean specimens that retain remains of soft tissues or stomach contents. Previous works showed that biomediated precipitation of dolomite concretions around large-sized decaying carcasses was one of the most relevant processes responsible for exceptional fossil preservation. In turn, little is known about the modes of fossilization of well-preserved small-sized vertebrates, which are rather common in the Pisco Formation, but mostly do not exhibit dolomite concretions. We report on a cetacean specimen, identified as belonging to the extinct short-snouted, small dolphin species Brachydelphis mazeasi (Pontoporiidae), preserved within a late Miocene sandy deposit at the site of Pampa Corre Viento. This specimen consists of a moderately disarticulated partial skeleton exhibiting well-mineralized bones; it is not enclosed within a dolomite concretion, being however delimited by an evident dark boundary in the host sediment. Scanning electron microscopy and microanalytical investigations identify Mn-oxides and apatite as early diagenetic minerals around the skeleton. We argue that a rapid burial of the specimen was pivotal for the preservation of the bones, and allowed the early establishment of anoxic processes for degradation of organic matter. Coupled with availability of P in porewater, the reducing conditions and the lowered pH allowed precipitation of Ca-phosphate while increasing Mn solubility close to the pontoporiid carcass. Mn-oxides precipitated at the redox boundary, the latter defining the outer edge of the volume of sediment affected by altered chemical conditions due to the decaying processes. The permeability of the sediment and the small size of the carcass were possible factors unfavorable to extensive sulfate reduction, thus preventing the formation of a dolomite concretion and allowing bone phosphatization. This record emphasizes the role of conditions favorable to bone mineralization in absence of an isolating carbonate concretion, in cases of high quality preservation of small-sized vertebrates observed in the Pisco Formation. The observation of patterns in the distribution of diagenetic minerals in the sediment enclosing vertebrate remains without, or with limited carbonate concretions provides insights into early taphonomic processes.

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“…Organic matter enrichment within concretion interiors may also arise if concretions preferentially precipitate around sediments with relatively high organic carbon content. Organic nuclei have been found in concretions of other localities (Allison & Pye, ; Gaines et al ., ; Grazhdankin et al ., ; Yoshida et al ., ; Plet et al ., ), and this association may result from localized alkalinity production upon organic nucleus degradation (Berner, ). In Holz Shale concretions, discrete organic nuclei are lacking, however, enrichments in disseminated organic matter could promote similar localized concretion precipitation.…”

Section: Discussionmentioning

confidence: 99%

“…Cementation may act to preserve primary sedimentary components by filling host rock pore space, thereby reducing local permeability, providing rigidity, and limiting the potential for chemical and physical degradation. In some cases, carbonate cementation has been shown to preserve unstable igneous minerals (Bramlette, 1946;Dickinson et al, 1969), magnetic minerals (McNeill & Kirschvink, 1993;Maloof et al, 2007), sedimentary structures (Lattman, 1973;Plet et al, 2016), microfossils (Blome & Albert, 1985), shells (Allison & Pye, 1994), biogenic particles (El Albani et al, 2001), soft organic tissues (Gaines et al, 2005;Grazhdankin et al, 2008;Yoshida et al, 2015), and specific biomolecules/biomolecular compositions (Pearson & Nelson, 2005;Melendez et al, 2013;Plet et al, 2016). In other cases, primary sedimentary components are relatively degraded within concretions compared to the host rock (Walker, 1984;Molenaar & Martinius, 1990;Vasconcelos & McKenzie, 1997;Taylor et al, 2000), reflecting a dichotomous relationship between cementation and preservation.…”

Section: Introductionmentioning

confidence: 99%

Preservation of overmature, ancient, sedimentary organic matter in carbonate concretions during outcrop weathering

Loyd

2016

Geobiology

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Concretions are preferentially cemented zones within sediments and sedimentary rocks. Cementation can result from relatively early diagenetic processes that include degradation of sedimentary organic compounds or methane as indicated by significantly C-depleted or enriched carbon isotope compositions. As minerals fill pore space, reduced permeability may promote preservation of sediment components from degradation during subsequent diagenesis, burial heating and outcrop weathering. Discrete and macroscopic organic remains, macro and microfossils, magnetic grains, and sedimentary structures can be preferentially preserved within concretions. Here, Cretaceous carbonate concretions of the Holz Shale are shown to contain relatively high carbonate-free total organic carbon (TOC) contents (up to ~18.5 wt%) compared to the surrounding host rock (with<2.1 wt%). TOC increases with total inorganic carbon (TIC) content, a metric of the degree of cementation. Pyrite contents within concretions generally correlate with organic carbon contents. Concretion carbonate carbon isotope compositions (δ C ) range from -22.5 to -3.4‰ (VPDB) and do not correlate strongly with TOC. Organic carbon isotope compositions (δ C ) of concretions and host rock are similar. Thermal maturity data indicate that both host and concretion organic matter are overmature and have evolved beyond the oil window maturity stage. Although the organic matter in general has experienced significant oxidative weathering, concretion interiors exhibit lower oxygen indices relative to the host. These results suggest that carbonate concretions can preferentially preserve overmature, ancient, sedimentary organic matter during outcrop weathering, despite evidence for organic matter degradation genetic mechanisms. As a result, concretions may provide an optimal proxy target for characterization of more primary organic carbon concentrations and chemical compositions. In addition, these findings indicate that concretions can promote delayed oxidative weathering of organic carbon in outcrop and therefore impact local chemical cycling.

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Early post-mortem formation of carbonate concretions around tusk-shells over week-month timescales

Cited by 60 publications

References 23 publications

Generalized conditions of spherical carbonate concretion formation around decaying organic matter in early diagenesis

Generalized conditions of spherical carbonate concretion formation around decaying organic matter in early diagenesis

Looking for the key to preservation of fossil marine vertebrates in the Pisco Formation of Peru: new insights from a small dolphin skeleton

Preservation of overmature, ancient, sedimentary organic matter in carbonate concretions during outcrop weathering

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