An alternative model for positive shifts in shallow‐marine carbonate δ<sup>13</sup>C and δ<sup>18</sup>O

Immenhauser, Adrian; Porta, Giovanna Della; Kenter, J.A.M.; Bahamonde, Juan R.

doi:10.1046/j.1365-3091.2003.00590.x

Cited by 214 publications

(138 citation statements)

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“…The δ 13 C isotope data suggest shallow water realm and more or less continuous diagenesis under marine conditions. Values are comparable with other platform carbonates, especially with Urgonian ones (Immenhauser et al 2003;Godet et al 2006;Föllmi & Godet 2013;Huck et al 2013). The trends in stable isotopes mirror the separation of the succession into three intervals to some degree (the lower and upper parts of the Podhorie Fm and the Manín Fm) (Fig.…”

Section: Geochemistry and Magnetic Susceptibilitysupporting

confidence: 76%

An Albian demise of the carbonate platform in the Manín Unit (Western Carpathians, Slovakia)

Fekete¹,

Soták²,

Boorová³

et al. 2017

Geologica Carpathica

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Abstract:The production of platform carbonates of the Manín Unit (Manín Straits, Central Western Carpathians) belonging to the Podhorie and Manín formations and formed by remains of rudists and benthic foraminifers (Urgonian-type carbonates), was previously assumed to terminate during the Aptian. First, we show that these deposits were primarily formed on the upper slope (Podhorie Formation) and in a fore-reef environment (Manín Formation). Second, biostratigraphic data indicate that the shallow-water production persisted up to the Albian, just as it did in another succession of the Manín Unit. The Podhorie Fm contains colomiellids (Colomiella recta, C. mexicana) and calcareous dinoflagellates (Calcisphaerula innominata) that indicate the Albian age. It also contains planktonic foraminifers (Ticinella roberti, Ticinella cf. primula, Ticinella cf. madecassiana, Ticinella cf. praeticinensis) of the Albian Ticinella primula Zone. The Podhorie Formation passes upwards into peri-reefal facies of the Manín Fm where we designate the Malý Manín Member on the basis of rudists shell fragments and redeposited orbitolinids. Microfacies associations share similarities with the Urgonian-type microfacies from Mediterranean Tethys and allow us to restrict the growth and the demise of the carbonate platform. δ 13 C and δ 18 O isotopes change over a broad range of both formations: δ 13C is in the range +1.03 to +4.20 ‰ V-PDB and δ 18O is in the range −0.14 to −5.55 ‰ V-PDB. Although a close correlation between δ 13 C and δ 18 O indicates diagenetic overprint, a long-term increase of δ 13C can indicate a gradual increase in the aragonite production and/or increasing effects of oceanic water masses in the course of the Albian, prior to the final platform drowning. Carbonate platform evolution was connected with submarine slumps and debris flows leading to redeposition and accumulation of carbonate lithoclasts and bioclastic debris on the slope. Our study confirms that the growth of carbonate platforms in the Central Western Carpathians was stopped and the platform collapsed during the Albian, in contrast to the westernmost Tethys. A hardground formed during the Late Albian is overlain by Albian -Cenomanian marls of the Butkov Formation with calcisphaerulid limestones characterized by planktonic foraminifers of the Parathalmanninella appenninica Zone and calcareous dinoflagellates of the Innominata Acme Zone.

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Section: Geochemistry and Magnetic Susceptibilitysupporting

confidence: 76%

An Albian demise of the carbonate platform in the Manín Unit (Western Carpathians, Slovakia)

Fekete¹,

Soták²,

Boorová³

et al. 2017

Geologica Carpathica

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“…In this case the ␦ 13 C of the sediments would then become more negative, as the site at a particular location would be more inf luenced by oceanic carbonate. Although this hypothesis cannot be proven at all of the sites, it has been established by using seismic data that the western margin of GBB has prograded toward the west Ϸ20 km, over the past [10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25]. At the other locations, where studies have been less detailed, it is clear based on the sediment description that there is a decrease in the proportion of shallow water-derived sediments with increasing depth (28,30), a change consistent with a change in sea level and proximity to the shallow-water source.…”

Section: Discussionmentioning

confidence: 99%

“…However, for older time periods, geologists are forced to use records from macrofossils such as brachiopods, belemnites, and mollusks (11, 12) as well as the ␦ 13 C of bulk sediments associated with carbonate ramps or platforms (13-15) and from epicontinental seas (16). Shallow water carbonate sediments deposited in situ are not reliable recorders of global ␦ 13 C as they are known to be affected by short-term changes in sea level, which subject the deposits to the influences of meteoric diagenesis during which time the ␦ 13 C can be altered substantially (17,18). A more diagenetically stable environment is found on the slopes of carbonate platforms, at depths below glacio-eustatic sea-level changes, where mixtures of pelagic and platform-derived sediments are deposited [so-called periplatform sediments (19)].…”

mentioning

confidence: 99%

“…For example, it has been suggested that variations in the ␦ 13 C of carbonate sediments deposited in epeiric seas are related to local recycling of organic material, rather than to changes in the global carbon cycle (18,(21)(22)(23). Another study has shown that variations in the ␦ 13 C of carbonate sediments surrounding the Bahamas, an oceanic dominated platform, are not related to global changes in the organic carbon cycle, at least over the past 25 Myr.…”

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confidence: 99%

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Global synchronous changes in the carbon isotopic composition of carbonate sediments unrelated to changes in the global carbon cycle

Swart

2008

Proc. Natl. Acad. Sci. U.S.A.

191

119

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The carbon isotopic (␦ 13 C) composition of bulk carbonate sediments deposited off the margins of four carbonate platforms/ramp systems (Bahamas, Maldives, Queensland Plateau, and Great Australian Bight) show synchronous changes over the past 0 to 10 million years. However, these variations are different from the established global pattern in the ␦ 13 C measured in the open oceans over the same time period. For example, from 10 Ma to the present, the ␦ 13 C of open oceanic carbonate has decreased, whereas platform margin sediments analyzed here show an increase. It is suggested that the ␦ 13 C patterns in the marginal platform deposits are produced through admixing of aragonite-rich sediments, which have relatively positive ␦ 13 C values, with pelagic materials, which have lower ␦ 13 C values. As the more isotopically positive shallowwater carbonate sediments are only produced when the platforms are flooded, there is a connection between changes in global sea level and the ␦ 13 C of sediments in marginal settings. These data indicate that globally synchronous changes in ␦ 13 C can take place that are completely unrelated to variations in the global carbon cycle. Fluctuations in the ␦ 13 C of carbonate sediments measured during previous geological periods may also be subject to similar processes, and global synchroniety of ␦ 13 C can no longer necessarily be considered an indicator that such changes are related to, or caused by, variations in the burial of organic carbon. Inferences regarding the interpretation of changes in the cycling of organic carbon derived from ␦ 13 C records should be reconsidered in light of the findings presented here.isotope ͉ organics ͉ shallow-water platform V ariations in the stable carbon isotopic composition (␦ 13 C) of calcium carbonate sediments throughout geological time have been an invaluable aid in unraveling changes in the global carbon cycle (1, 2). In addition, such variations in ␦ 13 C have provided information on the transfer of carbon between reservoirs during major geological events such as bolide impacts or catastrophic climate changes (3, 4). Generally speaking, increases in the ␦ 13 C of carbonates are considered indicative of increased burial and preservation of isotopically negative organic carbon, whereas decreases in the ␦ 13 C suggest transfer of carbon from the organic into the inorganic reservoir (5-7). Hence, variation in the ␦ 13 C of carbonate material should be a proxy for the amount of buried organic carbon. For example, the ␦ 13 C of the oceanic record has become increasingly more negative over the past 50 million years (Myr) (8, 9), suggesting that as much as 10 20 g of organic carbon have been transferred from the organic to the inorganic carbon reservoir (6).The most reliable archives of changes in the ␦ 13 C of the oceans over the past 100 Myr to 200 Myr are contained in the skeletons of planktic and benthic foraminifera (9, 10). Not only are these organisms relatively diagenetically stable, but the ␦ 13 C values can be corrected for any species-spe...

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“…Very good geochemical, biostratigraphical, and paleoecological documentation exists for the Lau excursion, and it is often used as a model to study positive CIEs, which are widely used as chemostratigraphic markers and as indicators of perturbations of the global carbon cycle (Jeppsson 1990;Aldridge et al 1993;Bickert et al 1997;Jeppsson and Aldridge 2000;Munnecke et al 2003;Calner 2005a;Melchin and Holmden 2006;Cramer and Saltzman 2007a, b;Fanton and Holmden 2007;Calner et al 2008;Małkowski et al 2009;Kozłowski and Sobień 2012). Studies of recent and sub-fossil carbonate sediments indicate that sea-level forcing, restricted circulation and laterally variable sediment composition can significantly influence the d 13 C carb values, leading to amplification of positive excursions in carbonate platform interiors during flooding intervals (Immenhauser et al 2003;Swart and Eberli 2005;Swart 2008;Gischler et al 2009;Oehlert et al 2012). The small-scale spatial variability of d 13 C values results from a combination of generic marine-water signal and local factors such as facies, restricted circulation, and diagenetic overprint.…”

Section: Introductionmentioning

confidence: 99%

Facies development and sequence stratigraphy of the Ludfordian (Upper Silurian) deposits in the Zbruch River Valley, Podolia, western Ukraine: local facies overprint on the δ13Ccarb record of a global stable carbon isotope excursion

Jarochowska

Kozłowski

2013

Facies

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An alternative model for positive shifts in shallow‐marine carbonate δ¹³C and δ¹⁸O

Cited by 214 publications

References 31 publications

An Albian demise of the carbonate platform in the Manín Unit (Western Carpathians, Slovakia)

An Albian demise of the carbonate platform in the Manín Unit (Western Carpathians, Slovakia)

Global synchronous changes in the carbon isotopic composition of carbonate sediments unrelated to changes in the global carbon cycle

Facies development and sequence stratigraphy of the Ludfordian (Upper Silurian) deposits in the Zbruch River Valley, Podolia, western Ukraine: local facies overprint on the δ13Ccarb record of a global stable carbon isotope excursion

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An alternative model for positive shifts in shallow‐marine carbonate δ13C and δ18O

Cited by 214 publications

References 31 publications

An Albian demise of the carbonate platform in the Manín Unit (Western Carpathians, Slovakia)

An Albian demise of the carbonate platform in the Manín Unit (Western Carpathians, Slovakia)

Global synchronous changes in the carbon isotopic composition of carbonate sediments unrelated to changes in the global carbon cycle

Facies development and sequence stratigraphy of the Ludfordian (Upper Silurian) deposits in the Zbruch River Valley, Podolia, western Ukraine: local facies overprint on the δ13Ccarb record of a global stable carbon isotope excursion

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An alternative model for positive shifts in shallow‐marine carbonate δ¹³C and δ¹⁸O