Numerical forward modelling of peritidal carbonate parasequence development: implications for outcrop interpretation

Burgess, Peter M.; Wright, V. Paul; Emery, David

doi:10.1046/j.1365-2117.2001.00130.x

Cited by 70 publications

(54 citation statements)

References 17 publications

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“…Flemings & Grotzinger, 1996) and rules-based (e.g. Drummond & Dugan, 1999;Burgess, Wright & Emery, 2001) process models.…”

Section: Discussionmentioning

confidence: 99%

“…Evaluation of the mechanisms by which geomorphic variability is propagated across spatial and temporal scales has become a growing focus of research in the earth sciences (Howard, 1997;Paola et al 2001;Dietrich et al 2003) with potential application to carbonate depositional systems (Drummond & Dugan, 1999;Burgess, 2001;Burgess, Wright, & Emery, 2001;Rankey, 2002;Burgess & Wright, 2003). Pattern formation in these systems at scale 'n' characteristically results from interactions between intrinsic component subsystems at scale 'n − 1' (self organization), perhaps modulated by processes at scale 'n + 1' (extrinsic forcing).…”

Section: Introductionmentioning

confidence: 99%

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Geomorphic evolution of a storm-dominated carbonate ramp (c. 549 Ma), Nama Group, Namibia

DiBenedetto

Grotzinger

2005

Geol. Mag.

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-The well-exposed Hoogland Member (c. 549 Ma) of the northern Nama Group (Kuibis Subgroup), Namibia, represents a storm-dominated carbonate ramp developed in a foreland basin of terminal Proterozoic age. The ramp displays facies gradients involving updip grainstones which pass downdip into broad, spatially extensive tracts of microbial laminites and finely laminated mudstones deposited above and below storm wave base. Trough cross-bedded, coarse grainstones are shown to transit downdip into finer-grained calcarenites, irregular microbial laminites and mottled laminites. Siliciclastic siltstones and shales were deposited further downdip. Platform growth was terminated through smothering by orogen-derived siliciclastic deposits. Ramp morphology was controlled by several different processes which acted across many orders of magnitude (millimetres to kilometres), including in situ growth of mats and reefs, scouring by wave-produced currents, and transport and infilling of coarse-grained carbonates and fine-grained carbonates and clastics. At the smallest scale, 'roughening' of the sea-floor through heterogeneous trapping and binding by microbial mats was balanced by smoothing of the sea-floor through accumulation of loose sediment to fill the topographic lows within the upward-propagating mat. At the next scale up, parasequence development involved roughening of the sea-floor through shoal growth and grainstone progradation, balanced by sea-floor smoothing through shale infilling of resulting downdip accommodation, as well as the metre-scale topographic depressions within the mosaic of shoal-water facies. At even larger (sequence/platform) scales, roughening of the sea-floor occurred through aggradation and progradation of thick carbonates, balanced by infilling of the foreland basin with orogen-derived siliciclastic sediments. At all scales a net balance was achieved between sea-floor roughening and sea-floor smoothing to maintain a more or less constant ramp profile.

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“…Flemings & Grotzinger, 1996) and rules-based (e.g. Drummond & Dugan, 1999;Burgess, Wright & Emery, 2001) process models.…”

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Geomorphic evolution of a storm-dominated carbonate ramp (c. 549 Ma), Nama Group, Namibia

DiBenedetto

Grotzinger

2005

Geol. Mag.

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“…In all other respects, the model is unchanged from that described in Burgess et al (2001) and Burgess & Wright (2003); steady subsidence, carbonate production, and landward sediment transport create progradational shorelines and islands that, in turn, create shallowing-upward carbonate parasequences in a manner similar to that initially described by Ginsburg (1971). Although no tidal processes are calculated in the model, a tidal range of 1 m is assumed in order to apply supratidal, intertidal and subtidal classifications to deposited sediments and thus to simulate peritidal strata.…”

Section: Value Of Production Number Of Occupied Mosaic Element (M) Nementioning

confidence: 86%

“…In contrast to previous versions of the model described in Burgess et al (2001) and Burgess & Wright (2003), spatial distribution of carbonate production in the model is controlled by a production mosaic calculated using deterministic cellular automata. A cellular automaton is a grid of values with simple rules specifying how the value at each point is calculated for the next time-step according to the value of adjacent points (e.g.…”

Section: Model Rationale and Formulationmentioning

confidence: 99%

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Sensitive dependence, divergence and unpredictable behaviour in a stratigraphic forward model of a carbonate system

Burgess

Emery

2004

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Although conceptual models of carbonate systems typically assume a dominance of external forcing and linear behaviour to generate metre-scale carbonate parasequences, there is no reason to preclude autocyclic and non-linear behaviour in such systems. Component parts of the carbonate system represented in this numerical forward model are entirely deterministic, but several parts are non-linear and exhibit complex interactions. Onshore sediment transport during relative sea-level rise generates autocyclic quasi-periodic shallowing upward parasequences but model behaviour is sufficiently complex that water depth evolution and parasequence thickness distributions are not predictable in any detail. The model shows sensitive dependence on initial conditions, resulting in divergence of two model cases, despite only a small difference in starting topography. Divergence in water-depth history at one point takes ~ 10ka, and for the whole model grid takes ,-~ 100 ka. Fischer plots from the two cases show that divergence leads to entirely different parasequence thickness evolution in each case. Chaotic behaviour is a specific type of sensitive dependence, and calculation of trajectory divergence in a 3-D pseudo-phase space indicates that water depth evolution is not truly chaotic. If sensitive dependence, divergence and complex processes generating random products turn out to be common in real carbonate systems, predictions should be limited to elements of the system unaffected by these phenomena, or limited to cases where an element of periodic external forcing over-rides their affects. These results also suggest that increasingly complex and sophisticated stratigraphic forward models are not necessarily going to lead directly to more deterministic predictive power, although they may well be useful sources of statistical data on carbonate strata.

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Rapid Recycling of Organic‐Rich Carbonates during Transgression: A Complex Coastal System in Southwest Florida

Vlaswinkel

Wanless

2009

Perspectives in Carbonate Geology

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Coastal and shallow marine environments are actively responding to accelerated rise in sea-level, eroding in some areas and rapidly accreting in others. Cape Sable in southwest Florida, with several natural and anthropogenic triggering events in the past century, illustrates the nearly instantaneous response that can occur in a sediment-rich coastal system. This paper presents results of a field study that documents a shallowing-upwards sediment package as a response to a transgressive phase. Patterns and rate of sedimentation are reported, the different sediment sources identified and the governing processes which control sedimentation style determined. The study integrates sedimentological and geochemical data with hydrodynamic time series measurements of water level, currents, suspended sediment concentration and salinity. Results show a rapid, sequential infilling of the intertidal zone from the most seaward marine, to transitional marine-freshwater sub-environments, as accommodation space becomes available due to sea-level rise, increased flood tidal volume and collapse of interior freshwater marshes. Average in situ sedimentation rates of 6.2 cm/yr are reported on the intertidal mudflats and daily tides are the most important agent responsible for the erosion, transportation and deposition of the fine-grained sediment. A significant amount of sediment is sourced from one coastal compartment and transported to another within the intracoastal system. The shallowing-upwards sediment package contains organic-rich carbonates with 15-35% total organic matter. In contrast to common stratigraphic wisdom, the shallowing-upwards peritidal sediments as recorded in southwest Florida, are the depositional response to several small, rapid pulses of sea-level instead of being diagnostic single high-stand lithofacies such as commonly described in ancient epeiric sequences.

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Numerical forward modelling of peritidal carbonate parasequence development: implications for outcrop interpretation

Cited by 70 publications

References 17 publications

Geomorphic evolution of a storm-dominated carbonate ramp (c. 549 Ma), Nama Group, Namibia

Geomorphic evolution of a storm-dominated carbonate ramp (c. 549 Ma), Nama Group, Namibia

Sensitive dependence, divergence and unpredictable behaviour in a stratigraphic forward model of a carbonate system

Rapid Recycling of Organic‐Rich Carbonates during Transgression: A Complex Coastal System in Southwest Florida

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