Analogue modelling of the inversion of multiple extensional basins in foreland fold-and-thrust belts

Molnar, Nicolás; Buiter, Susanne

doi:10.5194/se-14-213-2023

Cited by 5 publications

(2 citation statements)

References 74 publications

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“…Dry quartz sand has been proven as a suitable material and has often been used to model brittle inversion tectonics (e.g. Koopman et al, 1987;Buchanan and McClay, 1991;McClay and Buchanan, 1992;Yamada and McClay, 2004;Gomes et al, 2010;Molnar and Buiter, 2023). For a more detailed review of the inversion model set-ups and materials, see Zwaan et al (2022).…”

Section: Materials Scaling and Monitoringmentioning

confidence: 99%

Does the syn- versus post-rift thickness ratio have an impact on the inversion-related structural style?

Tămaș¹,

Tămaș²,

Tari³

et al. 2023

Solid Earth

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Abstract. Many extensional basins worldwide are modified by subsequent compressional episodes, which lead to inverted structures. The structures associated with the reactivation of pre-existing faults are critically important in the formation of suitable subsurface traps for hydrocarbons. Major concerns regarding inverted structures are the trap integrity and fault seal. In general, the preferred structures have simple four-way closures due to the minor forced folding of the post-rift cover, as opposed to (reverse) fault-related structures, which have a higher risk of breaching. Such reverse-fault-bounded structures have been generally observed in basins with a thick syn-rift fill and a relatively thin post-rift sequence at the time of inversion (Mode I). In contrast, gentle/open forced folds have been described in basins with thicker post-rift sequences than the syn-rift basin fill (Mode II). Five physical sandbox models, coupled with particle image velocimetry (PIV) analysis, have been performed to address the influence of the syn- versus post-rift thickness ratio on the inversion-related structural style of the post-rift cover. The main control on the development of Mode I or Mode II inversion structures within the post-rift sequence appears to be different due to the amount of compressional displacement accommodated by the inherited listric fault and the thickness of the post-rift cover. These observations do have a direct impact on the understanding of the geo-energy systems associated with inverted structures and are broadly comparable with natural data examples from Aotearoa/New Zealand, Israel, Romania, and the Republic of Türkiye.

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Section: Materials Scaling and Monitoringmentioning

confidence: 99%

Does the syn- versus post-rift thickness ratio have an impact on the inversion-related structural style?

Tămaș¹,

Tămaș²,

Tari³

et al. 2023

Solid Earth

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show abstract

“…Analogue modelling to date has focused on the role of crustal-scale exten-sional structures in accommodating strain during shortening, from the scale of the basin to that of individual basin-forming faults (e.g. Bonini et al, 2012;Molnar and Buiter, 2023; also see reviews by McClay, 1995, andZwaan et al, 2022). Many analogue experiments on basin inversion have examined the influence of pre-existing normal faults or shear zones (e.g.…”

Section: Introductionmentioning

confidence: 99%

Selective inversion of rift basins in lithospheric-scale analogue experiments

Samsu,

Gorczyk,

Schmid

et al. 2023

Solid Earth

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Abstract. Basin inversion is commonly attributed to the reverse reactivation of basin-bounding normal faults. This association implies that basin uplift and inversion-related structures are mainly controlled by the frictional behaviour of pre-existing faults and associated damage zones. In this study, we use lithospheric-scale analogue experiments of orthogonal extension followed by shortening to explore how the flow behaviour of ductile layers underneath rift basins promote or suppress basin inversion. Our experiments show that the rheology of the ductile lower crust and lithospheric mantle, modulated by the imposed bulk strain rate, determine (1) basin distribution in a wide rift setting and (2) strain accommodation by fault reactivation and basin uplift during subsequent shortening. When the ductile layers deform uniformly during extension (i.e. stretching) and shortening (i.e. thickening), all of the basins are inverted. When deformation in the ductile layers is localised during extension (i.e. necking) and shortening (i.e. folding), only some basins – which are evenly spaced apart – are inverted. We interpret the latter as selective basin inversion, which may be related to the superposition of crustal-scale and lithospheric-scale boudinage during the previous basin-forming extensional phase and/or folding of the ductile layers during shortening.

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The Juxtaposition of Thick-Skinned Structures and Their Role on the Present-Day Configuration of the Frontal Cordillera of Northern Chile

MARTINEZ,

Arriagada,

Díaz

et al. 2024

Preprint

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Analogue modelling of the inversion of multiple extensional basins in foreland fold-and-thrust belts

Cited by 5 publications

References 74 publications

Does the syn- versus post-rift thickness ratio have an impact on the inversion-related structural style?

Does the syn- versus post-rift thickness ratio have an impact on the inversion-related structural style?

Selective inversion of rift basins in lithospheric-scale analogue experiments

The Juxtaposition of Thick-Skinned Structures and Their Role on the Present-Day Configuration of the Frontal Cordillera of Northern Chile

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