Abstract
Garnet, an uncommon accessory mineral in igneous rocks, occurs in seven small peraluminous granitoid plutons in the southeastern Arabian Shield; textural equilibrium between garnet and other host granitoid minerals indicates that the garnets crystallized from their host magmas. Compositions of the garnets form three groups that reflect host-granitoid compositions, which in turn reflect source compositions and tectonic regimes in which the host magmas were generated. Garnets from the seven plutons have almandine-rich cores and spessartine-rich rims. This reverse zoning depicts host magma compositional evolution; i.e. rimward spessartine enrichment resulted from progressive, host-magma manganese enrichment. The garnets are heavy rare-earth element enriched; (Lu/La) N ranges from 13 to 355 and one of the garnets contains spectacularly elevated abundances of Y, Ta, Th, U, Zn, Zr, Hf, Sn, and Nb. Involvement of garnets with these trace element characteristics in magma genesis or evolution can have dramatic effects on trace element signatures of the resulting magmas. Other researchers suggest that Mn-enriched magmas are most conducive to garnet nucleation. Although the garnetiferous granitoids discussed here are slightly Mn enriched, other genetically similar peraluminous Arabian granitoids lack garnet; Mn enrichment alone does not guarantee garnet nucleation. The presence of excess alumina in the magma may be a prerequisite for garnet nucleation.
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References
Allan BD, Clarke DB (1981) Occurrence and origin of garnets in the South Mountain Batholith, Nova Scotia. Can Mineral 19:19–24
Burnham CW (1979) The importance of volatile constituents. In: Yoder HS Jr (ed) The evolution of the igneous rocks: Fiftieth Anniversary Perspectives. Princeton University Press, Princeton, pp 439–482
Chappell BW, White AJR (1974) Two contrasting granite types. Pac Geol 8:173–174
Christiansen EH, Burt DM, Sheridan MF, Wilson RT (1983) The petrogenesis of topaz rhyolites from the western United States. Contrib Mineral Petrol 83:16–30
Clarke DB (1981) The mineralogy of peraluminous granites: A review. Can Mineral 19:3–17
Collins WJ, Beams SD, White AJR, Chappell BW (1982) Nature and origin of A-type granites with particular reference to southeastern Australia. Contrib Mineral Petrol 80:189–200
Day WC, Weiblen PW (1986) Origin of Late Archean granite: geochemical evidence from the Vermilion Granitic Complex of Northern Minnesota. Contrib Mineral Petrol 93:283–296
Deer WA, Howie RA, Zussman J (1982) Rock-Forming Minerals, Volume 1A-Orthosilicates. Longman, New York, p 919
du Bray EA (1987) Distribution, petrology, and mineral potential of peraluminous granitoid plutons in the eastern and southeastern Arabian Shield, Kingdom of Saudi Arabia. US Geol Surv Bull 1694:13–32
Goldschmidt VM (1954) Geochemistry. Clarendon, Oxford, p 730
Green TH (1978) Garnet in silicic liquids and its possible use as a P-T indicator. Contrib Mineral Petrol 65:59–67
Irving AJ, Frey FA (1978) Distribution of trace elements between garnet megacrysts and host volcanic liquids of kimberlitic to rhyolitic composition. Geochim Cosmochim Acta 42:771–787
Leake BE (1967) Zoned garnets from the Galway granite and its aplites. Earth Planet Sci Lett 3:311–316
Miller CF, Stoddard EF (1981) The role of manganese in the paragenesis of magmatic garnet: an example from the Old Woman-Piute Range, California. J Geol 89:233–246
Pearce JA, Harris NBW, Tindle AG (1984) Trace element discrimination diagrams for the tectonic interpretation of granitic rocks. J Petrol 25:956–983
Philpotts JA, Schnetzler CC (1970) Phenocryst-matrix partition coefficients for K, Rb, Sr, and Ba, with applications to anorthosite and basalt genesis. Geochim Cosmochim Acta 34:307–322
Rickwood PC (1968) On recasting analyses of garnets into end-member molecules. Contrib Mineral Petrol 18:175–198
Schnetzler CC, Philpotts JA (1970) Partition coefficients of rare-earth elements between igneous matrix and rock-forming mineral phenocrysts-II. Geochim Cosmochim Acta 34:331–340
Stacey JS, Stoeser DB (1983) Distribution of oceanic and continental leads in the Arabian-Nubian Shield. Contrib Mineral Petrol 84:91–105
Stoeser DB, Camp VE (1985) Pan-African microplate accretion of the Arabian Shield. Geol Soc Am Bull 96:817–826
Stoeser DB, Stacey JS, Greenwood WR, Fischer LB (1984) U/Pb zircon geochronology of the southern part of the Nabitah mobile belt and Pan-African continental collision in the Saudi Arabian Shield. Saudi Arabian Deputy Ministry for Mineral Resources Technical Record USGS-TR-04-5, p 88
Stuckless JS, VanTrump G Jr, Christiansen EH, Bush CA, Bunker CM, Bartel AJ (1983) Preliminary assessment of the geochemistry and mineral favorability of the postorogenic granites of the southeastern Arabian Shield, Kingdom of Saudi Arabia. Saudi Arabian Deputy Ministry for Mineral Resources Open-File Report USGS-OF-03-64, p 41
Stuckless JS, Vaughn RB, VanTrump G Jr (1986) Trace element contents of postorogenic granites from the eastern Arabian Shield, Kingdom of Saudi Arabia. Saudi Arabian Deputy Ministry for Mineral Resources Open-File Report USGS-OF-06-2, p 49
Stuckless JS, Futa K (1986) Rb-Sr studies of postorogenic granites from the eastern Arabian Shield, Kingdom of Saudi Arabia. Saudi Arabian Deputy Ministry for Mineral Resources Open-File Report USGS-OF-07-8, p 26
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du Bray, E.A. Garnet compositions and their use as indicators of peraluminous granitoid petrogenesis — southeastern Arabian Shield. Contrib Mineral Petrol 100, 205–212 (1988). https://doi.org/10.1007/BF00373586
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DOI: https://doi.org/10.1007/BF00373586