Rock physics modelling of siliciclastic shallow-marine clinoforms on the New Jersey continental shelf using 3D seismic data and well logs

Aali, Masoud; Nedimović, M. R.; Fulthorpe, Craig S.; Mountain, Gregory S.; Richards, Bill; Austin, James A.

doi:10.5194/egusphere-egu2020-12238

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“…Steckler et al., 2007) can generate a difference between the conceptual model of two‐dimensional sedimentation and reality. For example, the direction of sediment supply and the azimuth of clinoforms on the New Jersey margin show significant rotation from the Oligocene to present (Aali, 2020). This difference will generate uncertainty in the answers the model provides in fitting real‐world data.…”

Section: Resultsmentioning

confidence: 99%

Sensitivity of modelled passive margin stratigraphy to variations in sea level, sediment supply and subsidence

Schmelz,

Miller,

Mountain

et al. 2024

Basin Research

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We produced a 10 Myr synthetic stratigraphic section using a forward stratigraphic model that generates marine deltaic stratigraphy over geological timescales. We recursively fit the model using a Bayesian inversion algorithm to test: (1) if it could be accurately reconstructed; (2) if the parameters used to create it could be recovered; and (3) the sensitivity of the model output to given model parameters and the attendant physical processes. The original synthetic stratigraphic section was produced with cyclical sea‐level variations of 40 and 30 m with 2.4 and 10 Myr periods respectively. Sediment was also supplied cyclically, in 2.4 and 10 Myr cycles with amplitudes of 30 and 80 tons/100 kyr, respectively, varying from a mean of 232 tons/100 kyr. Parameter values were sampled to fit the model using a Markov chain Monte Carlo algorithm, resulting in a ±5 m (1σ) variation between the experimental output and the original. Sea level varied by ±7 m (1σ) within the posterior distribution of parameters. As a result, both the 10 Myr and 2.4 Myr sea‐level cycles could be extracted from the original output. The variation in sediment supply was approximately ±38 tons/100 kyr (1σ) and, as a result, only the larger long‐term supply variations could be accurately recovered in refitting the model. The variation in thermal, flexural and total subsidence across those parameter sets is less than ±10 m (1σ). The original section experienced 150 m of total subsidence at the depocentre. Our results demonstrate the distinct and interpretable imprint of sea level and subsidence on continental margin stratigraphy can be quantified. Moreover, we conclude that sea‐level change produces a defined effect on the geometries of stratigraphic architecture, and that techniques applied for the purpose of delineating sea‐level variation from continental margin strata have a well‐founded conceptual basis.

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Section: Resultsmentioning

confidence: 99%