Evolution of a mixed siliciclastic-carbonate deep-marine system on an unstable margin: the Cretaceous of the Eastern Greater Caucasus, Azerbaijan

Cumberpatch, Zoë A.; Soutter, Euan; Kane, Ian A.; Casson, Max; Vincent, Stephen J.

doi:10.31223/osf.io/wsvu6

Cited by 5 publications

(13 citation statements)

References 71 publications

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“…Seafloor topography is generated by a variety of geological processes, including relief above mass-transport deposits (MTDs) (e.g., Ortiz-Karpf et al 2015Soutter et al 2018;Cumberpatch et al 2021), syndepositional tectonic deformation (e.g., Hodgson and Haughton 2004;Kane et al 2010) and salt diapirism (Fig. 1; e.g., Hodgson et al 1992;Prather et al 2012;Oluboyo et al 2014).…”

Section: Introductionmentioning

confidence: 99%

Interactions between deep-water gravity flows and active salt tectonics

Cumberpatch

Kane

Soutter

et al. 2021

Journal of Sedimentary Research

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Behavior of sediment gravity flows can be influenced by seafloor topography associated with salt structures; this can modify the depositional architecture of deep-water sedimentary systems. Typically, salt-influenced deep-water successions are poorly imaged in seismic reflection data, and exhumed systems are rare, hence the detailed sedimentology and stratigraphic architecture of these systems remains poorly understood. The exhumed Triassic (Keuper) Bakio and Guernica salt bodies in the Basque–Cantabrian Basin, Spain, were active during deep-water sedimentation. The salt diapirs grew reactively, then passively, during the Aptian–Albian, and are flanked by deep-water carbonate (Aptian–earliest Albian Urgonian Group) and siliciclastic (middle Albian–Cenomanian Black Flysch Group) successions. The study compares the depositional systems in two salt-influenced minibasins, confined (Sollube basin) and partially confined (Jata basin) by actively growing salt diapirs, comparable to salt-influenced minibasins in the subsurface. The presence of a well-exposed halokinetic sequence, with progressive rotation of bedding, beds that pinch out towards topography, soft-sediment deformation, variable paleocurrents, and intercalated debrites indicate that salt grew during deposition. Overall, the Black Flysch Group coarsens and thickens upwards in response to regional axial progradation, which is modulated by laterally derived debrites from halokinetic slopes. The variation in type and number of debrites in the Sollube and Jata basins indicates that the basins had different tectonostratigraphic histories despite their proximity. In the Sollube basin, the routing systems were confined between the two salt structures, eventually depositing amalgamated sandstones in the basin axis. Different facies and architectures are observed in the Jata basin due to partial confinement. Exposed minibasins are individualized, and facies vary both spatially and temporally in agreement with observations from subsurface salt-influenced basins. Salt-related, active topography and the degree of confinement are shown to be important modifiers of depositional systems, resulting in facies variability, remobilization of deposits, and channelization of flows. The findings are directly applicable to the exploration and development of subsurface energy reservoirs in salt basins globally, enabling better prediction of depositional architecture in areas where seismic imaging is challenging.

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Section: Introductionmentioning

confidence: 99%

Interactions between deep-water gravity flows and active salt tectonics

Cumberpatch

Kane

Soutter

et al. 2021

Journal of Sedimentary Research

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“…The eastern Greater Caucasus mountains exclusively expose Middle Jurassic and younger sedimentary rocks (Figures 2b and 3; Alizadeh et al., 2016; Azizbekov, 1968; Bairamov et al., 2008; Nalivkin, 1976). Three broad stratigraphic packages crop out across the range: (a) a northern flank succession of thinly bedded sandstone and shale with massive carbonate intervals (Alizadeh et al., 2016; Bairamov et al., 2008; Cumberpatch et al., 2021; Nalivkin, 1976; Figure 3a); (b) a range‐core succession of thinly bedded sandstone, shale, and carbonate (Alizadeh et al., 2016; Bairamov et al., 2008; Nalivkin, 1976; Figure 3b); and (c) located at the southern toe of the orogen, the Vandam Zone succession, which comprises volcaniclastic sandstone and conglomerate, volcanic tuff and flows, sandstone, shale, and carbonate (Alizadeh et al., 2016; Bairamov et al., 2008; Kopp, 1985; Nalivkin, 1976; Figure 3c). A buried fourth succession has been revealed by deep drilling in the Kura foreland basin to the south, comprising volcanic, volcaniclastic, siliciclastic, and carbonate strata (Alizadeh et al., 2016; Figure 3d), similar to strata exposed within the Vandam Zone.…”

Section: Geological Backgroundmentioning

confidence: 99%

“…The sedimentary facies of the northern flank succession and range‐core succession (Figures 3a and 3b) suggest deposition in continental shelf, slope, and deep marine environments (Alizadeh et al., 2016; Cumberpatch et al., 2021; Gavrilov, 2018). Stratigraphic architecture suggests that these strata were deposited offshore of a south‐facing continental margin (Cumberpatch et al., 2021; Gavrilov, 2018). Detrital zircon U‐Pb age distributions with peaks at ca.…”

Section: Geological Backgroundmentioning

confidence: 99%

Diverse Deformation Mechanisms and Lithologic Controls in an Active Orogenic Wedge: Structural Geology and Thermochronometry of the Eastern Greater Caucasus

Cowgill

et al. 2022

Tectonics

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Orogenic wedges are common at convergent plate margins and deform internally to maintain a self‐similar geometry during growth. New structural mapping and thermochronometry data illustrate that the eastern Greater Caucasus mountain range of western Asia undergoes deformation via distinct mechanisms that correspond with contrasting lithologies of two sedimentary rock packages within the orogen. The orogen interior comprises a package of Mesozoic thin‐bedded (<10 cm) sandstones and shales. These strata are deformed throughout by short‐wavelength (<1 km) folds that are not fault‐bend or fault‐propagation folds. In contrast, a coeval package of thick‐bedded (up to 5 m) volcaniclastic sandstone and carbonate, known as the Vandam Zone, has been accreted and is deformed via imbrication of coherent thrust sheets forming fault‐related folds of 5–10 km wavelength. Structural reconstructions and thermochronometric data indicate that the Vandam Zone package was accreted between ca. 13 and 3 Ma. Following Vandam Zone accretion, thermal modeling of thermochronometric data indicates rapid exhumation (∼0.3–1 mm/yr) in the wedge interior beginning between ca. 6 and 3 Ma, and a novel thermochronometric paleo‐rotation analysis suggests out‐of‐sequence folding of wedge‐interior strata after ca. 3 Ma. Field relationships suggest that the Vandam Zone underwent syn‐convergent extension following accretion. Together, the data record spatially and temporally variable deformation, dependent on both the mechanical properties of deforming lithologies and perturbations such as accretion of material from the down‐going to the overriding plate. The diverse modes of deformation are consistent with the maintenance of critical taper.

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“…Sea‐level change is commonly interpreted as the primary driver for alternating carbonate and siliciclastic deposition (Chiarella et al., 2012; Cumberpatch et al., 2020; D'agostini et al., 2015; Hentz & Ambrose, 2019; Hurd et al., 2018; Miller & Heller, 1994; Rankey & Lehrmann, 1996; Yose & Heller, 1989; Zecchin & Catuneanu, 2017), although other drivers controlling mixed deposition, such as tectonics, reefal buildups, hydrodynamic factors and shelf width are also reported (Chiarella et al., 2019; Ćosović et al., 2018; Le Roy et al., 2019; Vieira et al., 2019). Although a few cases of highstand siliciclastics are reported (Brachert et al., 2003; Hentz et al., 2017), in the sea‐level driven model, carbonate sediment is typically deposited during transgressive/highstand eustatic conditions, whereas siliciclastic sediment is deposited during lowstand conditions, a phenomenon known as ‘reciprocal sedimentation’ (Van Siclen & Merriam, 1964).…”

Section: Introductionmentioning

confidence: 99%

Tectonic controls on the evolution of mixed carbonate‐siliciclastic systems: Insights from the late Palaeozoic Ouachita‐Marathon Foreland, United States

et al. 2021

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Sea level is thought to be the primary driver of alternating deposition of carbonate and siliciclastic sediment in shelf settings, with carbonates dominating during transgressive/highstands and siliciclastics during lowstands. Although sediment supply is critically important for shelf-margin growth in siliciclastic systems, few studies demonstrate its impact on mixed carbonate-siliciclastic systems. The Permian Basin in Texas, United States, provides an opportunity to investigate the basin evolution regarding the source, sediment routing and particularly shelf/slope growth from synto postorogenic phases during alternating carbonate and siliciclastic sedimentation.Published detrital zircon data show that the proportion of orogen-related sources decreased significantly from an earliest Permian synorogenic phase (ca. 298 Ma) to a Leonardian (ca. 280-271 Ma) postorogenic phase, in concert with a grain-size change from fine-to medium-grained sand to silt. Although along-strike lateral variabilities exist on the shelf margin, the shelf-margin evolution characteristics show a significant difference among the Northern Shelf, Eastern Shelf and Central Basin Platform. The synorogenic Eastern Shelf exhibits a significant higher progradation rate than does the postorogenic Northern Shelf. The progradation and aggradation ratio of siliciclastic-rich intervals in the Eastern Shelf is significantly higher than those of carbonate-rich intervals in the Eastern Shelf and carbonate-or siliciclasticrich intervals in the Northern Shelf. In contrast, the Central Basin Platform, with no siliciclastic sediment supply, records almost no progradation regardless of orogenic phases. There is an increase in slope gradient with decreasing sediment supply during this second-order sequence from the Permian Cisuralian Series to the end of the Guadalupian Series. This study demonstrates that tectonically driven siliciclastic sediment supply was the main mechanism controlling the shelf and slope evolution in alternating siliciclastic and carbonate deposition.

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Evolution of a mixed siliciclastic-carbonate deep-marine system on an unstable margin: the Cretaceous of the Eastern Greater Caucasus, Azerbaijan

Cited by 5 publications

References 71 publications

Interactions between deep-water gravity flows and active salt tectonics

Interactions between deep-water gravity flows and active salt tectonics

Diverse Deformation Mechanisms and Lithologic Controls in an Active Orogenic Wedge: Structural Geology and Thermochronometry of the Eastern Greater Caucasus

Tectonic controls on the evolution of mixed carbonate‐siliciclastic systems: Insights from the late Palaeozoic Ouachita‐Marathon Foreland, United States

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