Origins, Timing, and Implications of Miocene to Pleistocene Turbidites, Debris Flows, and Slump Deposits of the Queensland Trough, Northeastern Australia (Site 823)

Watts, K. F.; Varga, Lisa L.

doi:10.2973/odp.proc.sr.133.248.1993

Cited by 15 publications

(12 citation statements)

References 13 publications

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“…Numerous authors have classified slope-failure deposits and mechanisms (Kuenen and Migliorini 1975;Bouma 1962;Dott 1963;Stanley and Silverberg 1969;Schuster 1978;Lowe 1979;Eberli 1991;Einsele 1991;Watts et al 1993;Martinsen 1994;Hampton and Lee 1996;Reading 1996). These definitions, however, are difficult to apply to seismic data because they are based on attributes, such as flow rheology, transport mechanisms, internal geometry, and fabric and composition of the deposits, which are normally not detectable in seismic displays.…”

Section: Terminologymentioning

confidence: 98%

3-D Seismic Characterization of Submarine Landslides on a Miocene Carbonate Platform (Luconia Province, Malaysia)

Zampetti

Schlager

Konijnenburg

et al. 2004

Journal of Sedimentary Research

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3-D seismic reflection data and a variance cube are used to determine the architecture and investigate the triggering processes of submarine landslides affecting the flanks of a Miocene carbonate platform in the Luconia Province, Malaysia. The slide masses exhibit, in time-slice displays, chaotic, patchy seismic patterns, in otherwise smooth reflections. They lie basinward of the slide scar, tend to widen in the transport direction, and end in indistinct lobes. Slide scars appear as crescent-shaped embayments in otherwise straight or oval platform-edge contours. However, slide scars show planar morphology where they coincide with a fault zone. In vertical sections, the basal surfaces of the slides are steep concave slope segments (slide scar) that rapidly flatten where they dip under the slide masses. Slide masses appear as zones of discontinuous wavy reflections that wedge out in both upslope and downslope directions, extend for 1.5 km into the basin, and have a maximum thickness of 130 m. The slide deposit on the western flank is the result of at least two individual sliding events. Two seismically chaotic bodies are separated by a smooth reflection interpreted as an intercalation of hemipelagic mud between carbonaterich slide masses. Syndepositional faulting affects the geometry of the platform and the platform margins, particularly at the time of slope failure. We suggest that the slides were generated by the interplay of steep-slope progradation and faulting accompanied by seismic shocks.

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Section: Terminologymentioning

confidence: 98%

3-D Seismic Characterization of Submarine Landslides on a Miocene Carbonate Platform (Luconia Province, Malaysia)

Zampetti

Schlager

Konijnenburg

et al. 2004

Journal of Sedimentary Research

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“…Site 823 is located in 1600 m of water within the Queensland Trough that separates the epiconti- (Shipboard Scientific Party, 1991;Watts et al, 1993; this study) as well as sampling notation.…”

Section: Geological Setting and Stratigraphy A T S I T E 823mentioning

confidence: 99%

“…The stratigraphic succession records deep-water sedimentation at Site 823 since at least Middle Miocene time (Katz 81 Miller, 1993 other Leg 133 sites, Site 823 is unique for the abundance of turbidites, debrites and folded slump masses admixed and interbedded with periplatform carbonate and mixed sediment mud, hemipelagic mixed sediment and pelagic carbonate ( Fig. 2; Watts et al, 1993). An increased abundance of shelf-derived detritus at depths of >880m in Middle to Upper Miocene strata, and <250m in Upper Pliocene and Quaternary sediments (Gartner et a]., 1993), marks active shelf-margin reef development (McKenzie & Davies, 1993;Watts et al, 1993).…”

Section: Geological Setting and Stratigraphy A T S I T E 823mentioning

confidence: 99%

“…2; Watts et al, 1993). An increased abundance of shelf-derived detritus at depths of >880m in Middle to Upper Miocene strata, and <250m in Upper Pliocene and Quaternary sediments (Gartner et a]., 1993), marks active shelf-margin reef development (McKenzie & Davies, 1993;Watts et al, 1993). Hairline fractures and microfaults are common in strata below about 500m and are abundant below 700m, within lower Pliocene and Miocene strata, respectively.…”

Section: Geological Setting and Stratigraphy A T S I T E 823mentioning

confidence: 99%

“…Hairline fractures and microfaults are common in strata below about 500m and are abundant below 700m, within lower Pliocene and Miocene strata, respectively. Fracturing and mass wasting are believed to be coeval with episodic faulting along the margins of the Queensland Trough (Watts et al, 1993).…”

Section: Geological Setting and Stratigraphy A T S I T E 823mentioning

confidence: 99%

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Origin of anhedral Sr‐rich calcite in deep‐water mixed sediment, north‐east Australia

Dix

1995

Sedimentology

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At burial depths of 800‐1000 m, within the epicontinental Queensland Trough of north‐east Australia (ODP Site 823), microcrystalline inter‐ and intraskeletal mosaics of anhedral (loaf‐shaped, rounded) calcite have Sr2+ values ranging from below microprobe detection limits (<150 ppm) to 8100 ppm. Host rocks are well lithified, fine‐grained mixed sediment to clayey wackestone and packstone of Middle and Late Miocene age. Petrography demonstrates that calcite precipitation has spanned shallow to deep burial, overlapping formation of framboidal pyrite in the upper 50 m; shallow‐burial dolomitization (<300 m); and dedolomitization during sediment consolidation and incipient chemical compaction at greater (>400–500 m) depths. Petrographic observations illustrate that the calcite microfabric formed through coalescing crystal growth resulting from one or a combination of displacive growth in clay, porphyroid neomorphism of aragonite/vaterite, and clay replacement by calcite. Sr2+ mean concentrations in calcite between depths of 800 and 1000 m are similar to an expected equilibrium pore‐water concentration, using a Dsr of 0.06, and may indicate active calcite precipitation. However, Sr2+ variation (2000–5000 ppm) within and among crystals, and concentrations that range well above predicted equilibrium values for a given depth, illustrate either variable Sr2+ retention during recrystallization of shelf‐derived aragonite (and authigenic local vaterite) or relative uptake of Sr2+ during calcite precipitation with burial. Within the context of calcite formation during burial to 1 km, diagenetic attributes that affect the latter process include increased concentrations of pore‐water Sr2+ with depth associated with aragonite recrystallization/dissolution; upward migration of Sr‐rich pore water; and increased DSr related to local variation in precipitation/recrystallization rates, differential crystal sector growth rates and/or microvariation in aragonite distribution.

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Submarine Landslides Along the Mixed Siliciclastic‐Carbonate Margin of the Great Barrier Reef (Offshore Australia)

Puga‐Bernabéu

Webster

Beaman

et al. 2019

Submarine Landslides

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Origins, Timing, and Implications of Miocene to Pleistocene Turbidites, Debris Flows, and Slump Deposits of the Queensland Trough, Northeastern Australia (Site 823)

Cited by 15 publications

References 13 publications

3-D Seismic Characterization of Submarine Landslides on a Miocene Carbonate Platform (Luconia Province, Malaysia)

3-D Seismic Characterization of Submarine Landslides on a Miocene Carbonate Platform (Luconia Province, Malaysia)

Origin of anhedral Sr‐rich calcite in deep‐water mixed sediment, north‐east Australia

Submarine Landslides Along the Mixed Siliciclastic‐Carbonate Margin of the Great Barrier Reef (Offshore Australia)

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