Effects of trench‐perpendicular ridge subduction on accretionary wedge deformation: Clues from analogue modelling

Wang, Chunyang; Ding, Weiwei; Li, Jiabiao; Dong, Chao; Fang, Yuefa; Tang, Leiwen; Ma, Lukuo; Zhao, Yanghui; Cheng, Zhizhong

doi:10.1002/gj.3317

Cited by 5 publications

(2 citation statements)

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“…Symmetrical igneous rock sequences, such as adakite-granitoid-adakite sequences, along the MOR are formed on the overriding plate (Ling et al, 2009;Isozaki et al, 2010). Analog model experiments further show that ridge subduction has a strong impact on the accumulation and migration of the accretionary wedge and the shape of the subduction zone edge (Wang et al, 2019). On the other hand, for trench-parallel MOR subduction, large-scale MORB-like igneous rocks erupt at the trench, which has a large influence range but a relatively short duration (Gutiérrez et al, 2005;Müller et al, 2016;Liu et al, 2020).…”

Section: Introductionmentioning

confidence: 89%

The Mode of Trench-Parallel Subduction of the Middle Ocean Ridge

Shen

Leng

2021

Front. Earth Sci.

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Trench-parallel subduction of mid-ocean ridges occurs frequently in plate motion history, such as along the western boundary of the Pacific plate in the early Cenozoic and along the eastern boundary of the Pacific plate at present. Such subduction may strongly alter the surface topography, volcanic activity and slab morphology in the mantle, whereas few studies have been conducted to investigate its evolutionary process. Here, we construct a 2-D viscoelastoplastic numerical model to study the modes and key parameters controlling trench-parallel subduction of mid-ocean ridges. Our model results show that the subduction modes of mid-ocean ridges can be primarily categorized into three types: the fast spreading mode, the slow spreading mode, and the extinction mode. The key factor controlling these subduction modes is the relative motion between the foregoing and the following oceanic plates, which are separated by the mid-ocean ridge. Different subduction modes exert different surface geological expressions, which may explain specific evolutionary processes related to mid-ocean ridge subduction, such as topographic deformation and the eruption gap of volcanic rocks in East Asia within 55–45 Ma and in the western North American plate during the late Cenozoic.

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Section: Introductionmentioning

confidence: 89%

The Mode of Trench-Parallel Subduction of the Middle Ocean Ridge

Shen

Leng

2021

Front. Earth Sci.

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“…The sandbox physical simulation experiment has unique advantages in the structural analysis of complex areas, because it can reproduce the structural deformation process of the natural prototype during complex geological evolution and reveal its dynamic mechanisms (Grokholskii & Dubinin, 2006;C. Wang et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

Structural characteristics and formation mechanisms of Bayanhushu Sag in Hailar Basin, north‐east China: A study based on structural physical simulation

Liu

Yang

et al. 2021

Geological Journal

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The Hailar Basin, located in north‐east China, is a typical continental rifted basin that contains oil and gas. The basin formation process comprised several stages of construction and reformation with complex formation mechanisms. The Bayanhushu (BYHS) Sag is a secondary structural unit in the south‐west Hailar Basin with a significant resource potential, but its current poor exploration and insufficient understanding of the structural evolution characteristics are restricting further oil and gas exploration. Therefore, the study of the structural evolution of the BYHS Sag plays a pivotal role in the future exploration and development of oil and gas. There are different hypotheses on the formation mechanisms and structural evolution of the BYHS Sag. To further understand the evolutionary history of the BYHS Sag, a structural physical simulation experiment was used based on the structural interpretation and geometric analysis of a seismic section. Inversion validation was then undertaken by the 2DMove equilibrium profile recovery technology. It was found that the formation process of the BYHS Sag was mainly controlled by the western Adunchulu Fault. Faults on the section developed in succession from top to bottom. The fault plane experienced multiple changes, thus forming a special seat‐shaped structural pattern. Structural inversion occurred twice during the evolution of the sag. The compressive stress during the tectonic inversion mainly acted in a SE direction. It is inferred that this was related to the subduction of the Palaeo‐Pacific Plate under the Eurasian Plate and the intermittent compression caused by the transmission of stress of the arc–continent collision.

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