Aarestrup, E., Jørgensen, T.R.C., Armitage, P.E.B., Nutman, A.P., Christiansen, O., Szilas, K., 2020. The Mesoarchean Amikoq Layered Complex of SW Greenland: Part 1. Constraints on the P-T evolution from igneous, metasomatic and metamorphic amphiboles. Mineral. Mag.
Link
Garde, A.A., 1997. Accretion and evolution of an Archaean high-grade grey gneiss–amphibolite complex: the Fiskefjord area, southern West Greenland. Geol. Greenl. Surv. Bull. Vol. 177, 115pp.
Norite
Greenland Akia Norite
Garde, A.A., 1991. Post-kinematic diorite intrusions in Archaean basement rocks around outer Fiskefjord, southern West Greenland. Bull. Geol. Soc. Denmark
Garde, A.A., 1997. Accretion and evolution of an Archaean high-grade grey gneiss–amphibolite complex: the Fiskefjord area, southern West Greenland. Geol. Greenl. Surv. Bull. Vol. 177, 115pp.
Garde, A.A., McDonald, I., Dyck, B., Keulen, N., 2012. Searching for giant, ancient impact structures on Earth: The Mesoarchaean Maniitsoq structure, West Greenland. Earth Planet. Sci. Lett. 337–338, 197–210.
Link
Garde, A.A., Pattison, J., Kokfelt, T.F., McDonald, I., Secher, K., 2013. The norite belt in the Mesoarchaean Maniitsoq structure, southern West Greenland: Conduit-type Ni-Cu mineralisation in impact-triggered, mantle-derived intrusions? Geol. Surv. Denmark Greenl. Bull. 45–48.
Scherstén, A., Garde, A.A., 2013. Complete hydrothermal re-equilibration of zircon in the Maniitsoq structure, West Greenland: A 3001 Ma minimum age of impact? Meteorit. Planet. Sci. 48, 1472–1498.
Link
Waterton, P., Hyde, W.R., Tusch, J., Hollis, J.A., Kirkland, C.L., Kinney, C., Yakymchuk, C., Gardiner, N.J., Zakharov, D., Olierook, H.K.H., Lightfoot, P.C., Szilas, K., 2020. Geodynamic Implications of Synchronous Norite and TTG Formation in the 3 Ga Maniitsoq Norite Belt, West Greenland. Front. Earth Sci. 8, 1.
Link(おすすめ)
Aarestrup, E., Jørgensen, T.R.C., Armitage, P.E.B., Nutman, A.P., Christiansen, O., Szilas, K., 2020. The Mesoarchean Amikoq Layered Complex of SW Greenland: Part 1. Constraints on the P-T evolution from igneous, metasomatic and metamorphic amphiboles. Mineral. Mag.
Link
Aarestrup, E., McDonald, I., Armitage, P.E.B., Nutman, A.P., Christiansen, O., Szilas, K., 2021. The Mesoarchean Amikoq Layered Complex of SW Greenland: Part 2. Geochemical evidence for high-Mg noritic plutonism through crustal assimilation. Mineral. Mag. 1–64.
Link
Greenland Ameralik dyke
Gill, R.C.O., Bridgwater, D., 1976. The Ameralik dykes of West Greenland, the earliest known basaltic rocks intruding stable continental crust. Earth Planet. Sci. Lett. 29, 276–282.
Link
Hall, R.P., Hughes, D.J., Friend, C.R.L., 1987. Mid-Archaean basic magmatism of southern West Greenland. Geol. Soc. Spec. Publ. 27, 261–275.
Link
Nielsen, S.G., Baker, J.A., Krogstad, E.J., 2002. Petrogenesis of an early Archaean (3.4 Ga) norite dyke, Isua, West Greenland: Evidence for early Archaean crustal recycling? Precambrian Res. 118, 133–148.
Link
Nutman, Allan P., Friend, C.R.L., Bennett, V.C., McGregor, V.R., 2004. Dating of the Ameralik dyke swarms of the Nuuk district, southern West Greenland; Mafic intrusion events starting from c. 3510 Ma. J. Geol. Soc. London. 161, 421–430.
Link
Norite (Others)
Costa, F., Dungan, M.A., Singer, B.S., 2002. Hornblende- and phlogopite-bearing gabbroic xenoliths from volcán San Pedro (36°S), Chilean Andes: Evidence for melt and fluid migration and reactions in subduction-related plutons. J. Petrol. 43, 219–241.
Link
Oliveira, E.P., Tarney, J., 1995. Genesis of the Precambrian copper-rich Caraiba hypersthenite-norite complex, Brazil. Miner. Depos. 30, 351–373.
Link
Page, N.J., Moring, B.C., 1990. Petrology of the noritic and gabbronoritic rocks below the J-M Reef in the Mountain View area, Stillwater Complex, Montana, Bulletin.
Link
Papike, J.J., Fowler, G.W., Shearer, C.K., Layne, G.D., 1996. Ion microprobe investigation of plagioclase and orthopyroxene from lunar Mg-suite norites: Implications for calculating parental melt REE concentrations and for assessing postcrystallization REE redistribution. Geochim. Cosmochim. Acta 60, 3967–3978.
Link
Piccardo, G.B., Guarnieri, L., 2011. Gabbro-norite cumulates from strongly depleted MORB melts in the Alpine-Apennine ophiolites. Lithos 124, 200–214.
Link
Smith, J.W., Holwell, D.A., McDonald, I., 2014. Precious and base metal geochemistry and mineralogy of the Grasvally Norite–Pyroxenite–Anorthosite (GNPA) member, northern Bushveld Complex, South Africa: implications for a multistage emplacement. Miner. Depos. 49, 667–692.
Link
Srivastava, R.K., 2008. Global intracratonic boninite-norite magmatism during the Neoarchean-Paleoproterozoic: Evidence from the central Indian Bastar craton. Int. Geol. Rev. 50, 61–74.
Link(おすすめ)
Olivine Trace
Multi
Demouchy and Alard, 2021. Hydrogen, trace, and ultra‐trace element distribution in natural olivines. CMP (特にTi, H2O)
Link
De Hoog et al., 2010. Trace-element geochemistry of mantle olivine and application to mantle petrogenesis and geothermobarometry. Chem.Geol. (特にAl,Cr,Ca, Grt-Peridotite)
Link
Demouchy , 2021. Defects in olivine. Eur.J.Min. (欠陥と微量元素の関係)
Link
Foley et al., 2013. Minor and trace elements in olivines as probes into early igneous and mantle melting processes. EPSL. (カンラン石の起源の分類)
Link
Ni etc
Cordier et al., 2015. Metasomatism of the Lithospheric Mantle Immediately Precedes Kimberlite Eruption: New Evidence from Olivine Composition and Microstructures. JPetro
Link
Endo et al., 2015. Orthopyroxene-rich Rocks from the Sanbagawa Belt (SW Japan): Fluid–Rock Interaction in the Forearc Slab–Mantle Wedge Interface. JPetro (OPXnite, Cpx-Mgtラメラ有り)
Link
Foley et al., 2011. Trace element variations in olivine phenocrysts from Ugandan potassic rocks as clues to the chemical characteristics of parental magmas. CMp (Phenocryst)
Link
Phosphorus
Welsch et al., 2014. Phosphorus zoning reveals dendritic architecture of olivine. Geology
Link
Ca
Aoki et al., 2020. Thermal and decompression history of the Lanzo Massif, northern Italy: Implications for the thermal structure near the lithosphere–asthenosphere boundary. Lithos
Link
Arai et al., 2021. Dehydrogenation of deep-seated hydrous olivine in “black-colored” dunites of arc origin. Lithos (Cpx-Magラメラ有り)
Link
Brey and Kolher, 1990. Geothermobarometry in Four-phase Lherzolites II. New Thermobarometers, and Practical Assessment of Existing Thermobarometers. JPetro
Link
Al
D'Souza et al., 2020. Geobarometry for spinel peridotites using Ca and Al in olivine. CMP
Link
Coogan et al., 2014. Aluminum-in-olivine thermometry of primitive basalts: Evidence of an anomalously hot mantle source for large igneous provinces. Chem.Geol. (Pheno)
Link
Bussweiler et al., 2017. The aluminum-in-olivine thermometer for mantle peridotites — Experimental versus empirical calibration and potential applications. Lithos (Grt-Peridotite)
Link
Li
Chen et al., 2020. Formation process of dunites and chromitites in Orhaneli and Harmancık ophiolites (NW Turkey): Evidence from in-situ Li isotopes and trace elements in olivine. Lithos
Link
Xiong et al., 2020. Multistage origin of dunite in the Purang ophiolite, southern Tibet, documented by composition, exsolution and Li isotope characteristics of constituent minerals. EJM (Dunite形成,Cpx-Magラメラ有り)
Link
Diffusion/Partition
Spandler et al., 2007. Survival times of anomalous melt inclusions from element diffusion in olivine and chromite. Nature
Link
Spandler and O'Neill, 2010. Diffusion and partition coefficients of minor and trace elements in San Carlos olivine at 1,300°C with some geochemical implications. CMP
Link
Bedard et al., 2005. Partitioning coefficients between olivine and silicate melts. Lithos
Link
Bodinier et al., 1987. Distribution of trace transition elementsin olivine and p)'roxenes from ultramafic xenoliths: Application of microprobeanalysis. American Mineralogist
Link
Dohmen et al., 2010. Diffusion of Li in olivine. Part I: Experimental observations and a multi species diffusion model. GCA
Link
Mallmann et al., 2009. The Crystal/Melt Partitioning of V during Mantle Melting as a Function of Oxygen Fugacity Compared with some other Elements (Al, P, Ca, Sc, Ti, Cr, Fe, Ga, Y, Zr and Nb). JPetro.
Link
Analysis
Bussweiler et al., 2019. Trace element analysis of high-Mg olivine by LA-ICP-MS – Characterization of natural olivine standards for matrix-matched calibration and application to mantle peridotites. Chem.Geol.
Link
Metamorphic
De Hoog et al., 2014. Titanium- and water-rich metamorphic olivine in high-pressure serpentinites from the Voltri Massif (Ligurian Alps, Italy): evidence for deep subduction of high-field strength and fluid-mobile element. CMP (Ti, Li, B)
Link
Debret et al., 2013. Trace element behavior during serpentinization/de-serpentinization of an eclogitized oceanic lithosphere: A LA-ICPMS study of the Lanzo ultramafic massif (Western Alps). Chem.Geol.
Link
Dilissen et al., 2021. Morphological transition during prograde olivine growth formed by high-pressure dehydration of antigorite-serpentinite to chlorite-harzburgite in a subduction setting. Lithos.
Link
Crust
Drouin et al., 2009. Geochemical and petrographic evidence for magmatic impregnation in the oceanic lithosphere at Atlantis Massif, Mid-Atlantic Ridge (IODP Hole U1309D, 30°N). Chem.Geol. (Troctolite)
Link
Ferrando et al., 2020. Retrieving timescales of oceanic crustal evolution at Oceanic Core Complexes: Insights from diffusion modelling of geochemical profiles in olivine. Lithos.
Link
FRTE
Lee et al., 2012. Copper Systematics in Arc Magmas and Implications for Crust-Mantle Differentiation. Science. (Cu)
Link
Le Roux et al., 2015. Recommended mineral-melt partition coefficients for FRTEs (Cu), Ga, and Ge during mantle melting. Ame. Min.
Link
Locmelis et al., 2019. Transition metals in komatiitic olivine: Proxies for mantle composition, redox conditions, and sulfide mineralization potential. Ame. Min.
Link
Wang et al., 2019. Oxidation State of Arc Mantle Revealed by Partitioning of V, Sc, and Ti Between Mantle Minerals and Basaltic Melts. JGR. (Vの分配係数がコンパイルされている)
Link