Basaltic liquids and harzburgitic residues in the Garrett Transform: a case study at fast-spreading ridges
Identifieur interne : 00CE75 ( Main/Exploration ); précédent : 00CE74; suivant : 00CE76Basaltic liquids and harzburgitic residues in the Garrett Transform: a case study at fast-spreading ridges
Auteurs : Yaoling Niu [Australie] ; Roger Hékinian [France]Source :
- Earth and Planetary Science Letters [ 0012-821X ] ; 1997.
Descripteurs français
- Wicri :
- topic : Essence.
English descriptors
- KwdEn :
- Abundance levels, Abyssal, Abyssal peridotites, Acta, Anomaly, Aphyric, Basalt, Basaltic, Basaltic liquids, Bideau, Clinopyroxene, Cosmochim, Crust, Crustal, Crustal thickness, Earth planet, East Pacific Rise, Excess olivine, Extraction processes, Fertile mantle, Fractional, Fractional crystallization, Garrett, Garrett basaltic liquids, Garrett harzburgites, Geochim, Geophys, Global ocean ridges, Harzburgite, Harzburgites, High extents, Hikinian earth, Hotspot, Impregnation, Impregnation harzburgite, Incompatible, Incompatible element, Incompatible element abundances, Lett, London spec, Major element compositions, Mantle flow, Mantle temperature variation, Morb, Morb genesis, Ocean basins, Ocean ridges, Oceanic, Oceanic crustal thickness, Olivine, Olivine forsterite, Olivine modes, Orthopyroxene, Outcrop, Partition coefficients, Peridotite, Petrol, Phipps morgan, Plagioclase, Planetary science letters, Queensland, Refertilization, Residual, Residual mineral compositions, Residual minerals, Residual peridotites, Ridge basalts, Sample preparation, Science letters, Serpentinization, Shallow levels, Spine1, Talus, Total olivine, Trace elements, harzburgite, mantle, melle, mid-ocean ridge basalts, mid-ocean ridges.
- Teeft :
- Abundance levels, Abyssal, Abyssal peridotites, Acta, Anomaly, Aphyric, Basalt, Basaltic, Basaltic liquids, Bideau, Clinopyroxene, Cosmochim, Crust, Crustal, Crustal thickness, Earth planet, Excess olivine, Extraction processes, Fertile mantle, Fractional, Fractional crystallization, Garrett, Garrett basaltic liquids, Garrett harzburgites, Geochim, Geophys, Global ocean ridges, Harzburgite, Harzburgites, High extents, Hikinian earth, Hotspot, Impregnation, Impregnation harzburgite, Incompatible, Incompatible element, Incompatible element abundances, Lett, London spec, Major element compositions, Mantle flow, Mantle temperature variation, Morb, Morb genesis, Ocean basins, Ocean ridges, Oceanic, Oceanic crustal thickness, Olivine, Olivine forsterite, Olivine modes, Orthopyroxene, Outcrop, Partition coefficients, Peridotite, Petrol, Phipps morgan, Plagioclase, Planetary science letters, Queensland, Refertilization, Residual, Residual mineral compositions, Residual minerals, Residual peridotites, Ridge basalts, Sample preparation, Science letters, Serpentinization, Shallow levels, Spine1, Talus, Total olivine, Trace elements.
Abstract
Abstract: The peridotite-basalt association in the Garrett Transform, ∼ 13°28′S, East Pacific Rise (EPR), provides a prime opportunity for examining mantle melting and melt extraction processes from both melts and residues produced in a common environment beneath fast-spreading ridges. The peridotites are highly depleted, clinopyroxene-poor, harzburgites. Residual spinel, orthopyroxene and clinopyroxene in these harzburgites are extremely depleted in Al2O3, and plot at the most depleted end of the abyssal peridotite array defined by samples from slow-spreading ridges (including samples from hotspot-influenced ridges), suggesting that these harzburgites are residues of very high extents of melting. The residual peridotites from elsewhere at the EPR (i.e., Hess Deep and the Terevaka Transform) also are similarly depleted. This suggests that the extent of melting beneath the EPR is similar to, or even higher than, beneath ridges influenced by hotspots (e.g., Azores hotspot in the Atlantic Ocean and Bouvet hotspot in the Indian Ocean), and is significantly higher than ≤ 10%, a value that has been advocated to be the average extent of melting beneath global ocean ridges. Many of these harzburgite samples, however, show whole-rock incompatible element abundances higher than expected. These same samples also have various amounts of excess olivine with forsterite contents as low as Fo85. The total olivine modes correlate inversely with olivine forsterite contents, and positively with whole-rock incompatible element abundances. These correlations suggest that the excess olivine and incompatible element enrichment are both the result of melt-solid re-equilibration. The buoyant melts that ascend through previously depleted residues crystallize olivine at shallow levels as a result of cooling. Entrapment of these melts leads to whole-rock incompatible element enrichment. These observations contrast with the notion that melts formed at depth experience little low pressure equilibration during ascent.
Url:
DOI: 10.1016/S0012-821X(96)00218-X
Affiliations:
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earth</term><term>Hotspot</term><term>Impregnation</term><term>Impregnation harzburgite</term><term>Incompatible</term><term>Incompatible element</term><term>Incompatible element abundances</term><term>Lett</term><term>London spec</term><term>Major element compositions</term><term>Mantle flow</term><term>Mantle temperature variation</term><term>Morb</term><term>Morb genesis</term><term>Ocean basins</term><term>Ocean ridges</term><term>Oceanic</term><term>Oceanic crustal thickness</term><term>Olivine</term><term>Olivine forsterite</term><term>Olivine modes</term><term>Orthopyroxene</term><term>Outcrop</term><term>Partition coefficients</term><term>Peridotite</term><term>Petrol</term><term>Phipps morgan</term><term>Plagioclase</term><term>Planetary science letters</term><term>Queensland</term><term>Refertilization</term><term>Residual</term><term>Residual mineral compositions</term><term>Residual minerals</term><term>Residual peridotites</term><term>Ridge basalts</term><term>Sample preparation</term><term>Science letters</term><term>Serpentinization</term><term>Shallow levels</term><term>Spine1</term><term>Talus</term><term>Total olivine</term><term>Trace elements</term><term>harzburgite</term><term>mantle</term><term>melle</term><term>mid-ocean ridge basalts</term><term>mid-ocean ridges</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Abundance levels</term><term>Abyssal</term><term>Abyssal peridotites</term><term>Acta</term><term>Anomaly</term><term>Aphyric</term><term>Basalt</term><term>Basaltic</term><term>Basaltic liquids</term><term>Bideau</term><term>Clinopyroxene</term><term>Cosmochim</term><term>Crust</term><term>Crustal</term><term>Crustal thickness</term><term>Earth planet</term><term>Excess olivine</term><term>Extraction processes</term><term>Fertile mantle</term><term>Fractional</term><term>Fractional crystallization</term><term>Garrett</term><term>Garrett basaltic liquids</term><term>Garrett harzburgites</term><term>Geochim</term><term>Geophys</term><term>Global ocean ridges</term><term>Harzburgite</term><term>Harzburgites</term><term>High extents</term><term>Hikinian earth</term><term>Hotspot</term><term>Impregnation</term><term>Impregnation harzburgite</term><term>Incompatible</term><term>Incompatible element</term><term>Incompatible element abundances</term><term>Lett</term><term>London spec</term><term>Major element compositions</term><term>Mantle flow</term><term>Mantle temperature variation</term><term>Morb</term><term>Morb genesis</term><term>Ocean basins</term><term>Ocean ridges</term><term>Oceanic</term><term>Oceanic crustal thickness</term><term>Olivine</term><term>Olivine forsterite</term><term>Olivine modes</term><term>Orthopyroxene</term><term>Outcrop</term><term>Partition coefficients</term><term>Peridotite</term><term>Petrol</term><term>Phipps morgan</term><term>Plagioclase</term><term>Planetary science letters</term><term>Queensland</term><term>Refertilization</term><term>Residual</term><term>Residual mineral compositions</term><term>Residual minerals</term><term>Residual peridotites</term><term>Ridge basalts</term><term>Sample preparation</term><term>Science letters</term><term>Serpentinization</term><term>Shallow levels</term><term>Spine1</term><term>Talus</term><term>Total olivine</term><term>Trace elements</term></keywords><keywords scheme="Wicri" type="topic" xml:lang="fr"><term>Essence</term></keywords></textClass><langUsage><language ident="en">en</language></langUsage></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">Abstract: The peridotite-basalt association in the Garrett Transform, ∼ 13°28′S, East Pacific Rise (EPR), provides a prime opportunity for examining mantle melting and melt extraction processes from both melts and residues produced in a common environment beneath fast-spreading ridges. The peridotites are highly depleted, clinopyroxene-poor, harzburgites. Residual spinel, orthopyroxene and clinopyroxene in these harzburgites are extremely depleted in Al2O3, and plot at the most depleted end of the abyssal peridotite array defined by samples from slow-spreading ridges (including samples from hotspot-influenced ridges), suggesting that these harzburgites are residues of very high extents of melting. The residual peridotites from elsewhere at the EPR (i.e., Hess Deep and the Terevaka Transform) also are similarly depleted. This suggests that the extent of melting beneath the EPR is similar to, or even higher than, beneath ridges influenced by hotspots (e.g., Azores hotspot in the Atlantic Ocean and Bouvet hotspot in the Indian Ocean), and is significantly higher than ≤ 10%, a value that has been advocated to be the average extent of melting beneath global ocean ridges. Many of these harzburgite samples, however, show whole-rock incompatible element abundances higher than expected. These same samples also have various amounts of excess olivine with forsterite contents as low as Fo85. The total olivine modes correlate inversely with olivine forsterite contents, and positively with whole-rock incompatible element abundances. These correlations suggest that the excess olivine and incompatible element enrichment are both the result of melt-solid re-equilibration. The buoyant melts that ascend through previously depleted residues crystallize olivine at shallow levels as a result of cooling. Entrapment of these melts leads to whole-rock incompatible element enrichment. These observations contrast with the notion that melts formed at depth experience little low pressure equilibration during ascent.</div></front></TEI><affiliations><list><country><li>Australie</li><li>France</li></country><region><li>Région Bretagne</li></region><settlement><li>Plouzané </li></settlement></list><tree><country name="Australie"><noRegion><name sortKey="Niu, Yaoling" sort="Niu, Yaoling" uniqKey="Niu Y" first="Yaoling" last="Niu">Yaoling Niu</name></noRegion><name sortKey="Niu, Yaoling" sort="Niu, Yaoling" uniqKey="Niu Y" first="Yaoling" last="Niu">Yaoling Niu</name></country><country name="France"><region name="Région Bretagne"><name sortKey="Hekinian, Roger" sort="Hekinian, Roger" uniqKey="Hekinian R" first="Roger" last="Hékinian">Roger Hékinian</name></region></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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