A Melt Extraction Model Based on Structural Studies in Mantle Peridotites

doi:10.1093/petrology/27.4.999

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Journal of Petrology | Volume 27 | Number 4 | Pages 999-1022 | 1986
© Oxford University Press 1986

research-article

A Melt Extraction Model Based on Structural Studies in Mantle Peridotites

A. NICOLAS

Laboratoire de tectonophysique 2, rue Houssinière, 44072 Nantes, France

Received June 10, 1985; Revised typescript accepted February 20, 1986

ABSTRACT

This study, largely based on field observations in various peridotitemassifs and on basalt xenoliths, traces the successive stagesof melt extraction from mantle diapirs. The first stage, initiatedin the garnet lherzolite field and pursued in the spinel lherzolitefield, creates melt pockets at the sites of the former garnets.During ascent, the melt fraction stable in spinel-lherzolitesis estimated to be $I$ 7 per cent. Above this fraction, but dependingupon plastic strain, permeability is obtained and melt extractionstarts. This occurs at 50 km depth. A network of connected meltveins and gashes, opened by fluid assisted shear fracturingin the deforming peridotites, is first created. When its verticalextension attains $I$ 10 km. the melt pressure fractures the overlyingperidotites (tensional hydrofracturing) creating a conduit formelt extraction. The buoyant forces generate a negative pressureat the base of the conduit. After communication with the earthsurface is achieved, the melt network surrounding the dyke rootis thus drained. This mechanism explains the remarkable efficiencyof melt extraction in residual harzburgites and dunites. Theconduit is a dyke, with a 20cm width at shallow depth. The meltvelocity through such dykes in shallow mantle is 5 cm s^–1.The rate of extraction of melt is so large that melt extractionis necessarily a discontinuous process even in the case of oceaniccrust generation. Each dyke of the dyke swarm in oceanic crustand ophiolites (and possibly each cumulate layer in the underlyingmafic cumulates) corresponds to a melt extraction event. Thuseach event creates 1 m of crust, during the time lapse of afew weeks. The periodicity of such events (5–50 yr) dependson the spreading rate (10–1 cm yr^–1). Each one corresponds,in the rising diapir, to a hydrofracture produced locally inthe area of the mantle melt network.

For spreading rates > 1 cm yr^–1, a 6 km thick oceaniccrust is created with an underlying uppermost mantle composedof residual harzburgites. For smaller rates, the oceanic crustis thinner as a result of smaller degrees of melting, with plagioclaselherzolites as residue. For even smaller rates, no oceanic crustis created (continental rifting) and the residue is a comparativelyfertile spinel lherzolite. This is explained by a direct relationbetween spreading rate and ascent rate of the mantle diapir.For spreading rates < 1 cm yr^–1, the adiabatic meltingin the diapir stops at about 15 km depth in plagioclase lherzolites(except for a final melt extraction just below the Moho) andat > 30km in spinel lherzolites.

This model has implications on melting processes (disequilibriummelting), the nature of primary melts and implies a straighterconnection than generally accepted between the physics and chemistryof volcanism and melting processes in the mantle.

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