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Taphonomy and palaeoecology of benthic macroinvertebrates from the Agua de la Mula Member of the Agrio Formation, Neuquén Basin (Neuquén province, Argentina): sequence stratigraphic significance / Taphonomie und Paläoökologie benthischer Makroinvertebraten des Agua de la Mula Member, Agrio Formation, Neuquén-Becken (Neuquén Provinz, Argentinien): Sequenzstratigraphische Relevanz

The taphonomic and paleoecologic aspects of the Upper Hauterivian to Lower Barremian Agua de la Mula Member of the Agrio Formation (Neuquén Basin, Argentina) were studied in the frame of the sequence stratigraphic paradigm. The Agua de la Mula Member, a ca. 600 m thick succession of highly cyclic marine sediments was surveyed at two localities. Detailed bed-by-bed sedimentologic, stratigraphic, ichnologic, taphonomic and paleoecologic data collection allowed a precise paleoenvironmental, stratigraphic, taphonomic and synecologic interpretation, in a controlled sequence stratigraphic framework. The main architectural stratigraphic component is the Starvation-Dilution Sequence, interpreted as a the effect of a sixth-order, Milankovitch precession-driven cycle. Dilution hemisequences are siliciclastic-dominated and show evidence of depth changes. Starvation hemisequences show a diverse variation of mixed carbonate-siliciclastic facies that is linked to sequence stratigraphy. Ammonite-based biostratigraphy was revised and new knowledge proposed. The stratigraphic framework was improved by combining biostratigraphy, sequence stratigraphy and event stratigraphy. Nine main sequences were described, linked to other stratigraphic markers and correlated with other sequence stratigraphic charts. Several orders of cyclicity were inferred. Third- and fourth-order sequences are the major sequences, not subordinated to higher hierarchies (lower order). Precession, obliquity, and short and long eccentricity cycles of the Milankovitch band are proposed. Among the different sequence stratigraphic models the transgression-regression model fits the majority of the sequences described in this work. The depositional-sequence model could be applied only to the first third-order sequence, in which the true sequence boundary is identifiable. Starvation-dilution sequences, however, are composed by to components that are not completely explained by those models. Starvation hemisequences developed in intermediate to deep settings record the transgressive phase as well as the earLy regressive one without visible stratigraphic boundaries. 112 samples with 22,572 individuals were grouped into fifteen fossil associations and one assemblage that reflect the interaction of different factors: age, position in major, medium and starvation dilution sequences and, linked to sequence stratigraphy, depth, oxygen availability, rate of terrigenous input, water agitation, and substrate conditions. Temporary possible reduction in oxygen content is inferred based on all sources of available evidence. Organic buildups are briefly described and their development interpreted in terms of the sequence stratigraphic framework. Vertical patterns of replacement of fossil associations are described and related to sequence stratigraphy. Five types of skeletal concentrations represent the diversity of coquinas decribed in this study. Type 1, 2, 4 and 5 correspond to starvation hemisequences deposited in progressively shallower settings, from basin to inner ramp. Type 3 is embedded into dilution hemisequences and inferred to be linked to shell bed type I of Kidwell (1985). Types 1 and 2 correspond to transgression, maximum flooding and early regression without distinction. Type 4A as well as Type 5 are interpreted as onlap shell beds (Kidwell 1991a) or early TST shell beds (Fürsich and Pandey 2003). Type 4B corresponds to the MFZ shell bed (Fürsich and Pandey 2003) or mid-cycle shell bed (Abbott 1997), while Type 4C to the downlap shell bed (Kidwell 1991a). Time-averaging of shell beds was assessed with precision as the time involved in the deposition of the starvation hemisequences could be inferred. All shell beds comprise within-habitat assemblages forming within a few thousand years, with little environmental condensation. The fossilization of the marine calcareous shells is modelled as a series of steps called windows: environmental, destructional, burial and diagenetic. The “diagenetic window” is the most relevant. Connected to this it is proposed that carbonate dissolution is the primary control on the development of shell beds, as has been proposed before (Fürsich 1982; Fürsich and Pandey 2003). The interpretative power resulting from combining several lines of evidence, e.g., facies analysis, sequence stratigraphy, biostratigraphy, trace fossil analysis, paleoecology and taphonomy, and unravelling their multiple relationships, are the most relevant conclusions of this study.

Identiferoai:union.ndltd.org:uni-wuerzburg.de/oai:opus.bibliothek.uni-wuerzburg.de:2984
Date January 2009
CreatorsArchuby, Fernando
Source SetsUniversity of Würzburg
LanguageEnglish
Detected LanguageEnglish
Typedoctoralthesis, doc-type:doctoralThesis
Formatapplication/pdf
Rightsinfo:eu-repo/semantics/openAccess

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