Fractionation of highly siderophile elements in refertilized mantle: Implications for the Os isotope composition of basalts
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D. Bosch | C. Garrido | F. Gervilla | D. Pearson | J. Bodinier | K. Hidas | C. Marchesi | C. Dale
[1] J. Lassiter,et al. Isotopically ultradepleted domains in the convecting upper mantle: Implications for MORB petrogenesis , 2014 .
[2] T. Meisel,et al. Traces of ancient mafic layers in the Tethys oceanic mantle , 2014 .
[3] J. Lorand,et al. Platinum-group element systematics and petrogenetic processing of the continental upper mantle: A review , 2013 .
[4] D. Bosch,et al. Mantle refertilization by melts of crustal-derived garnet pyroxenite: evidence from the Ronda peridotite massif, southern Spain , 2013 .
[5] A. Hofmann,et al. A global overview of isotopic heterogeneities in the oceanic mantle , 2012 .
[6] R. Arculus,et al. Inter-element fractionation of highly siderophile elements in the Tonga Arc due to flux melting of a depleted source , 2012 .
[7] Richard F. Katz,et al. Consequences of mantle heterogeneity for melt extraction at mid-ocean ridges , 2012 .
[8] A. Provost,et al. Fate of Pyroxenite-derived Melts in the Peridotitic Mantle: Thermodynamic and Experimental Constraints , 2012 .
[9] B. Peucker‐Ehrenbrink,et al. Rhenium-osmium isotope systematics and platinum group element concentrations in oceanic crust , 2012 .
[10] J. Day. Hotspot volcanism and highly siderophile elements , 2011 .
[11] N. Rogers,et al. Mineralogical and geochemical constraints on the shallow origin, ancient veining, and multi-stage modification of the Lherz peridotite , 2011 .
[12] J. Harvey,et al. Osmium mass balance in peridotite and the effects of mantle-derived sulphides on basalt petrogenesis , 2011 .
[13] Shichun Huang,et al. A radiogenic Os component in the oceanic lithosphere? Constraints from Hawaiian pyroxenite xenoliths , 2011 .
[14] R. Walker,et al. 186Os–187Os systematics of Hawaiian picrites revisited: New insights into Os isotopic variations in ocean island basalts , 2011 .
[15] H. Becker,et al. Rhodium, gold and other highly siderophile elements in orogenic peridotites and peridotite xenoliths , 2011 .
[16] D. Pearson,et al. Ancient Os isotope signatures from the Ontong Java Plateau lithosphere: Tracing lithospheric accretion history , 2011 .
[17] R. Walker,et al. Highly siderophile elements and Sr–Nd isotopes in refertilized mantle peridotites — A case study from the Totalp ultramafic body, Swiss Alps , 2010 .
[18] A. Luguet,et al. Formation of the North Atlantic Craton: Timing and mechanisms constrained from Re–Os isotope and PGE data of peridotite xenoliths from S.W. Greenland , 2010 .
[19] W. Griffin,et al. Persistence of mantle lithospheric Re–Os signature during asthenospherization of the subcontinental lithospheric mantle: insights from in situ isotopic analysis of sulfides from the Ronda peridotite (Southern Spain) , 2010 .
[20] R. Ash,et al. Formation of pyroxenite layers in the Totalp ultramafic massif (Swiss Alps) – Insights from highly siderophile elements and Os isotopes , 2010 .
[21] E. Jelínek,et al. Effects of melt percolation on highly siderophile elements and Os isotopes in subcontinental lithospheric mantle: A study of the upper mantle profile beneath Central Europe , 2009 .
[22] D. Pearson,et al. Highly siderophile element behaviour accompanying subduction of oceanic crust : Whole rock and mineral-scale insights from a high-pressure terrain , 2009 .
[23] J. Lorand,et al. Platinum‐group element signature of the primitive mantle rejuvenated by melt‐rock reactions: evidence from Sumail peridotites (Oman Ophiolite) , 2009 .
[24] C. Garrido,et al. Origin of Pyroxenite–Peridotite Veined Mantle by Refertilization Reactions: Evidence from the Ronda Peridotite (Southern Spain) , 2008 .
[25] Albrecht W. Hofmann,et al. Ancient, highly heterogeneous mantle beneath Gakkel ridge, Arctic Ocean , 2008, Nature.
[26] A. Luguet,et al. 184Os/188Os and 186Os/188Os measurements by Negative Thermal Ionisation Mass Spectrometry (N-TIMS): Effects of interfering element and mass fractionation corrections on data accuracy and precision , 2008 .
[27] J. Brenan. Re–Os fractionation by sulfide melt–silicate melt partitioning: A new spin , 2008 .
[28] A. Luguet,et al. Extreme platinum-group element fractionation and variable Os isotope compositions in Philippine Sea Plate basalts: Tracing mantle source heterogeneity , 2008 .
[29] A. Luguet,et al. Enriched Pt-Re-Os Isotope Systematics in Plume Lavas Explained by Metasomatic Sulfides , 2008, Science.
[30] R. Fonseca,et al. How chalcophile is rhenium? An experimental study of the solubility of Re in sulphide mattes , 2007 .
[31] O. Alard,et al. The scale and origin of the osmium isotope variations in mid-ocean ridge basalts , 2007 .
[32] A. Vauchez,et al. The Lherz spinel lherzolite: Refertilized rather than pristine mantle , 2007 .
[33] G. Mallmann,et al. The effect of oxygen fugacity on the partitioning of Re between crystals and silicate melt during mantle melting , 2007 .
[34] V. Salters,et al. Ancient recycled mantle lithosphere in the Hawaiian plume: Osmium–Hafnium isotopic evidence from peridotite mantle xenoliths , 2007 .
[35] Tetsu Kogiso,et al. Partial melting experiments of bimineralic eclogite and the role of recycled mafic oceanic crust in the genesis of ocean island basalts , 2006 .
[36] V. Laurenz,et al. Fractionation of the noble metals by physical processes , 2006 .
[37] R. Walker,et al. Highly siderophile element composition of the Earth’s primitive upper mantle: Constraints from new data on peridotite massifs and xenoliths , 2006 .
[38] N. Rogers,et al. Ancient melt extraction from the oceanic upper mantle revealed by Re–Os isotopes in abyssal peridotites from the Mid-Atlantic ridge , 2006 .
[39] L. Reisberg,et al. Re-Os and S systematics of spinel peridotite xenoliths from east central China: Evidence for contrasting effects of melt percolation [rapid communication] , 2005 .
[40] L. Cabri,et al. Partitioning of Cu, Ni, Au, and platinum-group elements between monosulfide solid solution and sulfide melt under controlled oxygen and sulfur fugacities , 2005 .
[41] R. Walker,et al. Evidence for the early differentiation of the core from Pt-Re-Os isotope systematics of 2.8-Ga komatiites , 2005 .
[42] W. Griffin,et al. In situ Os isotopes in abyssal peridotites bridge the isotopic gap between MORBs and their source mantle , 2005, Nature.
[43] S. Escrig,et al. Rhenium–osmium isotope systematics in MORB from the Southern Mid-Atlantic Ridge (40°–50° S) , 2005 .
[44] R. Walker,et al. Platinum-Osmium isotope evolution of the Earth's mantle , 2005 .
[45] R. Walker,et al. The debate over core–mantle interaction , 2005 .
[46] A. Sobolev,et al. An olivine-free mantle source of Hawaiian shield basalts , 2005, Nature.
[47] M. Humayun,et al. Highly siderophile element geochemistry of 187Os-enriched 2.8 Ga Kostomuksha komatiites, Baltic Shield , 2005 .
[48] M. Hirschmann,et al. High-pressure Partial Melting of Mafic Lithologies in the Mantle , 2004 .
[49] Conny Bockrath,et al. Fractionation of the Platinum-Group Elements During Mantle Melting , 2004, Science.
[50] B. Dupré,et al. Osmium isotopic constraints on the nature of the DUPAL anomaly from Indian mid-ocean-ridge basalts , 2004, Nature.
[51] G. Dreibus,et al. Re-Os isotope systematics and platinum group element fractionation during mantle melt extraction: a study of massif and xenolith peridotite suites , 2004 .
[52] R. Carlson,et al. Slab-derived osmium and isotopic disequilibrium in garnet pyroxenites from a Paleozoic convergent plate margin (lower Austria) , 2004 .
[53] T. Meisel,et al. Reference materials for geochemical PGE analysis : new analytical data for Ru, Rh, Pd, Os, Ir, Pt and Re by isotope dilution ICP-MS in 11 geological reference materials , 2004 .
[54] A. Hofmann,et al. Os mobilization during melt percolation: The evolution of Os isotope heterogeneities in the mantle sequence of the troodos ophiolite, Cyprus , 2004 .
[55] M. Humayun,et al. Precise Pt-Re-Os isotope systematics of the mantle from 2.7-Ga komatiites , 2004 .
[56] J. Baker,et al. Coupled 186Os–187Os enrichments in the Earth’s mantle – core–mantle interaction or recycling of ferromanganese crusts and nodules? , 2004 .
[57] D. Pearson,et al. Re--- Os and Lu--- Hf Isotope Constraints on the Origin and Age of Pyroxenites from the Beni Bousera Peridotite Massif: Implications for Mixed Peridotite--- Pyroxenite Mantle Sources , 2004 .
[58] M. Norman,et al. Tungsten isotope evidence that mantle plumes contain no contribution from the Earth's core , 2004, Nature.
[59] I. Parkinson,et al. Osmium Isotope Heterogeneity in the Constituent Phases of Mid-Ocean Ridge Basalts , 2004, Science.
[60] V. Salters,et al. Composition of the depleted mantle , 2003 .
[61] W. McDonough,et al. Experimental constraints on the partitioning of rhenium and some platinum-group elements between olivine and silicate melt , 2003 .
[62] L. Reisberg,et al. Platinum-group elements and melt percolation processes in Sidamo spinel peridotite xenoliths, Ethiopia, East African Rift , 2003 .
[63] J. Lorand,et al. Sulfide petrology and highly siderophile element geochemistry of abyssal peridotites: a coupled study of samples from the Kane Fracture Zone (45°W 23°20N, MARK area, Atlantic Ocean) , 2003 .
[64] R. Walker,et al. 186 Os^ 187 Os systematics of Gorgona Island komatiites: implications for early growth of the inner core , 2003 .
[65] J. Brenan,et al. The solubility of ruthenium in sulfide liquid: implications for platinum group mineral stability and sulfide melt–silicate melt partitioning , 2002 .
[66] A. Hofmann,et al. Melt percolation monitored by Os isotopes and HSE abundances: a case study from the mantle section of the Troodos Ophiolite , 2002 .
[67] J. Morgan,et al. Comparative 187Re-187Os systematics of chondrites: Implications regarding early solar system processes , 2002 .
[68] Cindy Lee. Platinum-group element geochemistry of peridotite xenoliths from the Sierra Nevada and the Basin and Range, California , 2002 .
[69] J. Lorand,et al. Platinum-group element abundances in the upper mantle: New constraints from in situ and whole-rock analyses of Massif Central xenoliths (France) , 2001 .
[70] R. Carlson,et al. Effects of melt percolation on the Re–Os systematics of peridotites from a Paleozoic convergent plate margin , 2001 .
[71] R. Walker,et al. Osmium isotopic compositions of mantle xenoliths: A global perspective , 2001 .
[72] W. Griffin,et al. Non-chondritic distribution of the highly siderophile elements in mantle sulphides , 2000, Nature.
[73] K. Kratz,et al. Highly siderophile element geochemistry of the Earth''s mantle: New data for the Lanzo (Italy) and R , 2000 .
[74] G. Yaxley. Experimental study of the phase and melting relations of homogeneous basalt + peridotite mixtures and implications for the petrogenesis of flood basalts , 2000 .
[75] D. Pearson. Solvent extraction/anion exchange separation and determination of PGEs (Os, Ir, Pt, Pd, Ru) and Re-Os isotopes in geological samples by isotope dilution ICP-MS , 2000 .
[76] Evans,et al. Osmium isotope constraints on ore metal recycling in subduction zones , 1999, Science.
[77] C. Garrido,et al. Diversity of Mafic Rocks in the Ronda Peridotite: Evidence for Pervasive Melt–Rock Reaction during Heating of Subcontinental Lithosphere by Upwelling Asthenosphere , 1999 .
[78] J. Mavrogenes,et al. THE RELATIVE EFFECTS OF PRESSURE, TEMPERATURE AND OXYGEN FUGACITY ON THE SOLUBILITY OF SULFIDE IN MAFIC MAGMAS , 1999 .
[79] E. Hauri,et al. Osmium-isotope variations in Hawaiian lavas: evidence for recycled oceanic lithosphere in the Hawaiian plume , 1998 .
[80] H. G. David,et al. Reactions between eclogite and peridotite; mantle refertilisation by subduction of oceanic crust , 1998 .
[81] Hauri,et al. Compatibility of rhenium in garnet during mantle melting and magma genesis , 1998, Science.
[82] H. Prichard,et al. Coupled 186Os and 187Os evidence for core-mantle interaction , 1998, Science.
[83] J. Morgan,et al. Applications of the 190Pt186Os isotope system to geochemistry and cosmochemistry , 1997 .
[84] J. Birck,et al. Re‐Os Isotopic Measurements at the Femtomole Level in Natural Samples , 1997 .
[85] J. Amossé,et al. Differentiation of platinum-group elements (PGE) and of gold during partial melting of peridotites in the lherzolitic massifs of the Betico-Rifean range (Ronda and Beni Bousera) , 1996 .
[86] A. Cohen,et al. Separation of osmium from geological materials by solvent extraction for analysis by thermal ionisation mass spectrometry , 1996 .
[87] M. Fleet,et al. Partitioning of platinum-group elements (Os, Ir, Ru, Pt, Pd) and gold between sulfide liquid and basalt melt , 1996 .
[88] E. Makovicky,et al. Partitioning of nickel, copper, iridium, rhenium, platinum, and palladium between monosulfide solid solution and sulfide liquid: Effects of composition and temperature , 1996 .
[89] L. Reisberg,et al. A major and trace element and strontium, neodymium, and osmium isotopic study of a thick pyroxenite layer from the Beni Bousera Ultramafic Complex of northern Morocco , 1996 .
[90] L. Reisberg,et al. Os isotopic systematics of the MORB mantle: results from altered abyssal peridotites , 1995 .
[91] H. Staudigel,et al. Os isotope systematics of La Palma, Canary Islands: Evidence for recycled crust in the mantle source of HIMU ocean islands , 1995 .
[92] L. Reisberg,et al. Longevity of sub-continental mantle lithosphere from osmium isotope systematics in orogenic peridotite massifs , 1995, Nature.
[93] R. Vissers,et al. Uplift and emplacement of upper mantle rocks in the western Mediterranean , 1993 .
[94] D. Wyman,et al. Os isotope systematics in ocean island basalts , 1993 .
[95] C. Weisener,et al. Partitioning of platinum-group elements and Au in the Fe−Ni−Cu−S system: experiments on the fractional crystallization of sulfide melt , 1993 .
[96] P. H. Nixon,et al. Geochemical constraints on the petrogenesis of diamond facies pyroxenites from the Beni Bousera Peridotite Massif, North Morocco , 1993 .
[97] L. Reisberg,et al. The ReOs systematics of the Ronda Ultramafic Complex of southern Spain , 1991 .
[98] R. Keays,et al. Sulfide melt-silicate melt distribution coefficients for noble metals and other chalcophile elements as deduced from MORB: Implications for partial melting , 1990 .
[99] Donald L. Turcotte,et al. Implications of a two-component marble-cake mantle , 1986, Nature.
[100] R. Batiza,et al. Isotope and trace element geochemistry of young Pacific seamounts: implications for the scale of upper mantle heterogeneity , 1984 .
[101] S. Hart. K, Rb, Cs, Sr and Ba contents and Sr isotope ratios of ocean floor basalts , 1971, Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences.
[102] B. Mason. Composition of the Earth , 1966, Nature.
[103] C. Garrido,et al. The Recrystallization Front of the Ronda Peridotite: Evidence for Melting and Thermal Erosion of Subcontinental Lithospheric Mantle beneath the Alboran Basin , 2001 .
[104] S. Hart,et al. Re–Os Isotopes in the Horoman Peridotite: Evidence for Refertilization? , 2001 .
[105] M. Hirschmann,et al. A possible role for garnet pyroxenite in the origin of the “garnet signature” in MORB , 1996 .
[106] C. Allègre,et al. 187Os/186Os in oceanic island basalts: tracing oceanic crust recycling in the mantle , 1995 .
[107] S. Hart,et al. ReOs isotope systematics of HIMU and EMII oceanic island basalts from the south Pacific Ocean , 1993 .