Deformation and Reactive Melt Transport in the Mantle Lithosphere above a Large-scale Partial Melting Domain: the Ronda Peridotite Massif, Southern Spain
1Géosciences Montpellier, Université Montpellier II & CNRS, CC 60, Place E. Bataillon, 34095 Montpellier Cedex 5, France
2Instituto Andaluz De Ciencias De La Tierra (IACT), CSIC & UGR, Facultad De Ciencias, Fuentenueva S/N, 18002 Granada, Spain
RECEIVED MAY 17, 2008; ACCEPTED MAY 6, 2009
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Abstract |
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The Ronda peridotite massif in Southern Spain shows a well-defined ‘recrystallization’ front that separates a large-scale partial melting domain formed at the expense of the continental lithospheric mantle from a ‘preserved’ lithospheric domain. To investigate the processes allowing a transient lithosphere–asthenosphere boundary to propagate in the lithospheric mantle, we performed a joint petrostructural and geochemical study of an 
2·5 km2 zone extending from the melting front to the mylonites that mark the western limit of the massif. This study emphasizes a feedback between heat transfer, melt percolation, and deformation in the lithospheric mantle. Petrographical observations and geochemical data show that heterogeneous reactive percolation of melts produced in the underlying partial melting domain led to refertilization of lithospheric peridotites up to 1·5 km ahead from the melting front, producing metre-scale layering of fertile and refractory mantle rocks. Within 800 m from the front, pre-existing garnet pyroxenite layers were partially molten and the resulting melts probably contributed to the refertilization process. Detailed structural mapping and analysis of the microstructures and crystal preferred orientations highlight the relations between reactive melt transport and deformation, and the control of the temperature gradient on both processes. Parallelism between the recrystallization front, compositional boundaries, and deformation structures, as well as variations in the deformation intensity of pyroxenes and spinels, suggest syn- to late-tectonic melt transport controlled by both the deformation and the thermal gradient. Variations in the strength of olivine crystal preferred orientations as a function of the modal and chemical composition of the spinel tectonites point to a higher contribution of diffusion to deformation in the most fertile rocks, corroborating the hypothesis that deformation occurred in presence of melt. Finally, the systematic dispersion of olivine [100] and orthopyroxene [001] axes in the foliation plane suggests a dominantly transpressive deformation regime.
KEY WORDS: asthenosphere–lithosphere boundary; deformation; lithosphere; melt percolation; microstructure; olivine; CPO; mylonites; partial melting; peridotite; refertilization; transient heating
*Corresponding author. Telephone: +33-(0)467143941. Fax: +33-(0)467143603. E-mail: vsoustel{at}gm.univ-montp2.fr