Sedimentary Basins and Crustal Processes at Continental Margins: From Modern Hyper-extended Margins to Deformed Ancient Analogues
Continental margins and their fossilized analogues are important repositories of natural resources. With better processing techniques and increased availability of high-resolution seismic and potential field data, imaging of present-day continental margins and their embedded sedimentary basins has reached unprecedented levels of refinement and definition, as illustrated by examples described in this volume. This, in turn, has led to greatly improved geological, geodynamic and numerical models for the crustal and mantle processes involved in continental margin formation from the initial stages of rifting through continental rupture and break-up to development of a new ocean basin. Further informing these models, and contributing to a better understanding of the features imaged in the seismic and potential field data, are observations made on fossilized fragments of exhumed subcontinental mantle lithosphere and ocean–continent transition zones preserved in ophiolites and orogenic belts of both Palaeozoic and Mesozoic age from several different continents, including Europe, South Asia and Australasia.
Passive rifting and continental splitting in the Jurassic Ligurian Tethys: the mantle perspective
-
Published:January 01, 2015
-
CiteCitation
Giovanni B. Piccardo, 2015. "Passive rifting and continental splitting in the Jurassic Ligurian Tethys: the mantle perspective", Sedimentary Basins and Crustal Processes at Continental Margins: From Modern Hyper-extended Margins to Deformed Ancient Analogues, G. M. Gibson, F. Roure, G. Manatschal
Download citation file:
- Share
Abstract
Based on present knowledge of mantle peridotites from the Ligurian Tethys ophiolites, this paper presents new ideas and a new model for passive rifting to ocean spreading in the slow–ultraslow rifting Europe–Adria realm. Relevant points include: (i) the positive feedback between deformation and melt percolation during passive magmatic rifting; (ii) the positive feedback between natural evidence and experimental data on the behaviour of the mantle lithosphere during passive rifting; (iii) the significance of hidden magmatism and the associated melt thermal advection; (iv) the role of the wedge-shaped weakened and softened axial zone; and (v) the evidence of a transition from passive to active rifting in the Ligurian Tethys.
Passive rifting induced passive asthenospheric upwelling and the onset of partial melting. Fractional melts migrated through the mantle lithosphere and stagnated at shallow levels (the hidden magmatism). Melt thermal advection heated the mantle lithosphere to temperatures (T) of ≥1200°C and formed a wedge-shaped axial zone of rheological softened/weakened mantle peridotites that served as the future locus of continental break-up. The hotter/deeper asthenosphere ascended within this axial zone, underwent partial melting and formed aggregated mid-ocean ridge basalts (MORBs) that migrated within dunite channels to form olivine gabbro intrusions and basaltic lava flows. Rifting evolved from passive to active, and the actively upwelling asthenosphere established a ridge-type system and thermal regime.
- active margins
- advection
- asthenosphere
- basalts
- chemical composition
- continental margin
- crustal thinning
- decompression
- deformation
- emplacement
- extension tectonics
- extrusive rocks
- faults
- heat flow
- igneous rocks
- intrusions
- Jurassic
- Ligurian Sea
- lithosphere
- magmatism
- mantle
- Mediterranean Sea
- melts
- Mesozoic
- mid-ocean ridge basalts
- modern analogs
- paleogeography
- partial melting
- passive margins
- plate tectonics
- rheology
- rifting
- saturation
- sea-floor spreading
- shear zones
- spreading centers
- tectonics
- Tethys
- thermal regime
- upwelling
- volcanic rocks
- volcanism
- West Mediterranean
- stagnation
- Europe-Adria Realm
- Axial Zone