The role of feldspar crystals zoning in interpreting the magmatic evolution  of the Goushe granitoid Pluton (SE of Boroujerd)

This volume comprises 17 contributions that address the architecture and geodynamic evolution of the Himalaya–Karakoram–Tibet (HKT) system, covering wide aspects, from the active seismicity of the present day to the remnants of the Proterozoic orogen. The articles investigate the HKT system at different scales, blending field research with laboratory studies. The role of various lithospheric components and their inheritance in the geodynamic and magmatic evolution of the HKT system through time, and their links to global geological events, are studied in the field. The laboratory research focuses on the (sub-)micrometre scale, detailing micro-structural geology, crystal chemistry, geochronology, and the study of circulating fluids, their preservation (trapped in fluid inclusions) and their evolution, distribution, migration and interaction with the solid host. An orogen over 2000 km long can be understood only if the processes at the nanometre and micrometre scales are taken into account. The contributions in this volume successfully combine these scales to enhance our understanding of the HKT system.

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Feldspars and fluids in cooling plutons

Mineralogical Magazine ◽

10.1180/minmag.1978.042.321.01 ◽

1978 ◽

Vol 42 (321) ◽

pp. 1-17 ◽

Cited By ~ 106

Author(s):

Ian Parsons

Keyword(s):

Stable Isotope ◽

Experimental Work ◽

Structural State ◽

Hydrothermal Fluids ◽

Igneous Rocks ◽

Magmatic Evolution ◽

Cooling History ◽

Isotope Studies ◽

Alkali Feldspars

SummaryAlkali feldspars in plutonic igneous rocks vary both in their exsolution textures and in the structural state of their components. The primary factor leading to this diversity is the availability of hydrothermal fluids during their cooling history. In many plutons feldspar variation is related to degree of fractionation as indicated by rock chemistry. The variation reflects build-up of water with magmatic evolution and implies that fluids did not circulate freely in the intrusives in the temperature range of unmixing and ordering. Experimental work bearing on the role of fluids in subsolidus changes in feldspars is reviewed, and points of overlap between crystallographic studies of feldspars and stable isotope studies are discussed.

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The role of garnetization of olivine in olivine-diopside-jadeite system in the ultramafic-mafic evolution of the upper-mantle magmatism (experiment at 6 GPa).

Геохимия ◽

10.31857/s0016-752564101026-1046 ◽

2019 ◽

Vol 64 (10) ◽

pp. 1026-1046

Author(s):

Yu. A. Litvin ◽

A. V. Kuzyura ◽

E. B. Limanov

Keyword(s):

Upper Mantle ◽

Peritectic Reaction ◽

Liquidus Surface ◽

Experimental Physic ◽

Magmatic Evolution ◽

Rock Series ◽

Mantle Material ◽

Univariant Curve ◽

Basic Rocks

Peritectic mechanisms, controlling fractional ultrabasic-basic evolution of the upper mantle magmatism and genesis of the peridotitepyroxeniteeclogite rock series, are substantiated in theory and experiment. Melting phase relations of a differentiated mantle material are studied with polythhermal section method in the multicomponent olivineclinopyroxene/omphacitecorundumcoesite system with boundary compositions duplicated these of peridotitic and eclogitic minerals. The peritectic reaction of orthopyroxene and melt with formation of clinopyroxene (the opthopyroxene clinopyroxenization reaction) has been determined at a liquidus surface of the ultrabasic olivineorthopyroxeneclinopyroxenegarnet system. As a result of the reaction the temperature-regressive univariant curve olivine + clinopyroxene + garnet + melt is formed. A further evolution of magmatism has experimentally studied at 6 GPa in the ultrabasic-basic olivinediopsidejadeitegarnet system with changeable compositions of the diopsidejadeite solid solutions (controlling the clinopyroxene omphacite mineralogy). Peritectic reaction of olivine and melt with formation of garnet was established on the liquidus surface of the ternary olivinediopsidejadeite system as the mechanism of olivine garnetization and going to the univariant curve omphacitegarnetmelt with formation of bimineral eclogites. Structure of the liquidus surface for the olivinediopsidejadeitegarnet system is inferred, and its role as a physic-chemical bridge between ultrabasic olivinebearing peridotitepyroxenitic and basic silica-saturated eclogitic compositions of the garnetperidotite facies matter. The new experimental physic-chemical results reveal the genetic links between ultrabasic and basic rocks as well as mechanisms of the uninterrupted fractional magmatic evolution and petrogenesis from the olivinebearing peridotitepyroxenitic to silica-saturated eclogite-grospyditicrocks. This provides an explanation for the uninterrupted composition trends for rock-forming components in clinopyroxenes and garnets of the differentiated rocks of the garnetperidotite facieis.

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Epidote in calcalkaline magmas; an experimental study of stability, phase relationships, and the role of epidote in magmatic evolution

American Mineralogist ◽

10.2138/am-1996-3-420 ◽

1996 ◽

Vol 81 (3-4) ◽

pp. 462-474 ◽

Cited By ~ 98

Author(s):

Max W. Schmidt ◽

Alan B. Thompson

Keyword(s):

Experimental Study ◽

Magmatic Evolution ◽

Phase Relationships

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Synneusis: does its preservation imply magma mixing?

Mineralogia ◽

10.2478/mipo-2018-0009 ◽

2018 ◽

Vol 49 (1-4) ◽

pp. 99-117 ◽

Cited By ~ 2

Author(s):

Bibhuti Gogoi ◽

Ashima Saikia

Keyword(s):

Magma Mixing ◽

Mafic Magma ◽

Textural Features ◽

Magmatic Evolution ◽

Mafic Rocks ◽

Intermediate Rock ◽

Euhedral Crystal ◽

Mineral Compositions ◽

Felsic Rocks

Abstract The Ghansura Felsic Dome (GFD) occurring in the Bathani volcano-sedimentary sequence was intruded by mafic magma during its evolution leading to magma mixing. In addition to the mafic and felsic rocks, a porphyritic intermediate rock occurs in the GFD. The study of this rock may significantly contribute toward understanding the magmatic evolution of the Ghansura dome. The porphyritic rock preserves several textures indicating its hybrid nature, i.e. that it is a product of mafic-felsic magma mixing. Here, we aim to explain the origin of the intermediate rock with the help of textural features and mineral compositions. Monomineralic aggregates or glomerocrysts of plagioclase give the rock its characteristic porphyritic appearance. The fact that the plagioclase crystals constituting the glomerocrysts are joined along prominent euhedral crystal faces suggests the role of synneusis in the formation of the glomerocrysts. The compositions of the glomerocryst plagioclases are similar to those of plagioclases in the mafic rocks. The results from this study indicate that the porphyritic intermediate rock formed by the mixing of a crystal-rich mafic magma and a crystal-poor felsic melt.

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Tracing the chemical evolution of primary pyrochlore from plutonic to volcanic carbonatites: the role of fluorine

Mineralogical Magazine ◽

10.1180/minmag.2012.076.2.07 ◽

2012 ◽

Vol 76 (2) ◽

pp. 377-392 ◽

Cited By ~ 15

Author(s):

A. C. J. M. Bambi ◽

A. Costanzo ◽

A. O. Gonçalves ◽

J. C. Melgarejo

Keyword(s):

Earth Element ◽

Magmatic Evolution ◽

Chemical Zoning ◽

The Core ◽

Core Composition ◽

Plutonic Complex ◽

A Site ◽

Volatile Exsolution ◽

Oscillatory Zonation

AbstractThree Angolan carbonatites were selected to evaluate the change in composition of pyrochlores during magmatic evolution: the Tchivira carbonatites occur in a plutonic complex, the Bonga carbonatites represent hypabyssal carbonatites and the Catanda carbonatites are volcanic in origin. In Tchivira pyrochlore, zoning is poorly developed; fluorine is dominant at the Y site; chemical zoning may arise as a result of substitutions for Nb in the B site; and the rare earth element (REE), U, Th and large-ion lithophile element (LILE) contents are very low. Pyrochlores from Bonga show oscillatory zonation; the F and Na contents are lower than those in the pyrochlores from Tchivira; and as substitution of Na at the A site increases, the Th, U, REE contents and inferred vacancies also increase. Pyrochlores from Catanda display complex textures. They generally have a rounded corroded core, which is mantled by two or three later generations. The core composition is similar to the Bonga pyrochlores. The rims are enriched in Zr, Ta, Th, Ce and U, but depleted in F and Na. In pyrochlores from the Angolan carbonatites, the F and Na contents decrease from plutonic to volcanic settings and there is enrichment of Th, U and REE in the A site and Ta and Zr in the B site. Zoning may be explained by changes in the activity of F, due to the crystallization of fluorite or apatite in the plutonic and hypabyssal carbonatites, or to volatile exsolution in the volcanic carbonatites.

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