Ridge Jumps and Mantle Exhumation in Back-Arc Basins

Valentina Magni,John Naliboff,Manel Prada,Carmen Gaina

doi:10.3390/geosciences11110475

Abstract

Back-arc basins in continental settings can develop into oceanic basins, when extension lasts long enough to break up the continental lithosphere and allow mantle melting that generates new oceanic crust. Often, the basement of these basins is not only composed of oceanic crust, but also of exhumed mantle, fragments of continental crust, intrusive magmatic bodies, and a complex mid-ocean ridge system characterised by distinct relocations of the spreading centre. To better understand the dynamics that lead to these characteristic structures in back-arc basins, we performed 2D numerical models of continental extension with asymmetric and time-dependent boundary conditions that simulate episodic trench retreat. We find that, in all models, episodic extension leads to rift and/or ridge jumps. In our parameter space, the length of the jump ranges between 1 and 65 km and the timing necessary to produce a new spreading ridge varies between 0.4 and 7 Myr. With the shortest duration of the first extensional phase, we observe a strong asymmetry in the margins of the basin, with the margin further from trench being characterised by outcropping lithospheric mantle and a long section of thinned continental crust. In other cases, ridge jump creates two consecutive oceanic basins, leaving a continental fragment and exhumed mantle in between the two basins. Finally, when the first extensional phase is long enough to form a well-developed oceanic basin (>35 km long), we observe a very short intra-oceanic ridge jump. Our models are able to reproduce many of the structures observed in back-arc basins today, showing that the transient nature of trench retreat that leads to episodes of fast and slow extension is the cause of ridge jumps, mantle exhumation, and continental fragments formation.

Highlights

Back-arc basins are common features associated with subduction zones; they develop behind volcanic arcs as a consequence of extensional stresses in the overriding plates.Rifting of the lithosphere yields to crustal thinning accompanied by normal faulting and, in some cases, can lead to continental breakup, seafloor spreading, and formation of new oceanic basins [1]
Results from our parametric study can be divided in three main groups according to their evolution: asymmetric margins, continental fragment formation, and intra-oceanic ridge jump
The largest asymmetry is not due to the boundary conditions, but it is created by the fact that jumps in extension location happens before the continent is fully broken up and the second extensional phase continues stretching continental material only at one margin

Summary

Introduction

Back-arc basins are common features associated with subduction zones; they develop behind volcanic arcs as a consequence of extensional stresses in the overriding plates.Rifting of the lithosphere yields to crustal thinning accompanied by normal faulting and, in some cases, can lead to continental breakup, seafloor spreading, and formation of new oceanic basins [1]. Back-arc basins are common features associated with subduction zones; they develop behind volcanic arcs as a consequence of extensional stresses in the overriding plates. The process of seafloor spreading in back-arc basins is similar to that happening at mid-ocean ridges in large oceanic basins, the morphology of back-arc basins is often quite complicated, reflecting the complex regional tectonic history. The relationship between extensional processes in the back-arc and subduction dynamics is key to understanding morphologies, structures, and evolution of back-arc basins [2]. Trench velocity and upper-plate stresses, which directly affect the evolution of the basins, are not steady-state features, but can significantly vary within a few millions 4.0/). How changes in trench velocity affect the formation and evolution of back-arc basins is the main focus of this work

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Discussion

Conclusion