Genesis of pale microgranular masses in ophiolitic chromite deposits in northern Xinjiang: Analysis of the micro‐area composition of altered minerals using LA‐ICP‐MS

The petrographic characteristics and micro‐area composition of altered minerals in pale microgranular masses (PMMs) that were discovered in the chromite mines of northern Xinjiang, China, were studied via laser ablation inductively coupled plasma mass spectrometry (LA‐ICP‐MS). There are six lithotyp...

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Published inGeological journal (Chichester, England) Vol. 55; no. 3; pp. 2185 - 2207
Main Authors Wang, Yu‐Wang, Xie, Hongjing, Guo, Boran, Shi, Yu, Zhou, Guochao
Format Journal Article
LanguageEnglish
Published Hoboken, USA John Wiley & Sons, Inc 01.03.2020
Wiley Subscription Services, Inc
Subjects
Ablation
Affinity
altered mineral
Chlorite
Chlorites
Chromite
Composition
Gabbro
Garnets
Geochemistry
Inductively coupled plasma mass spectrometry
Laser ablation
Lasers
Lava
LA‐ICP‐MS analysis
Leaching
Magma
Mass spectrometry
Mass spectroscopy
Minerals
northern Xinjiang
Ophiolites
PMM
podiform chromite
Properties
Rocks
rodingite
Serpentine
Trace elements
Tuff
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Summary:The petrographic characteristics and micro‐area composition of altered minerals in pale microgranular masses (PMMs) that were discovered in the chromite mines of northern Xinjiang, China, were studied via laser ablation inductively coupled plasma mass spectrometry (LA‐ICP‐MS). There are six lithotypes of PMMs, namely, rodingitized vitrobasalt, gabbro‐diabase, ultramafite, tuff‐clastic rock, rodingite or skarn, and metasomatite. The texture, composition, and geochemical affinities of a series of altered minerals, such as clinopyroxenes, garnets, serpentines, and chlorites, show that the incompatible elements actively migrate with the Fe, Mg, alkali leaching losses, and Ca aggregates during the course of the alteration process. The geochemical characteristics of the major trace elements in the altered minerals are mostly influenced by the types of protoliths and minerals and have roughly inherited those properties from the protoliths. A marked difference exists between the serpentine geochemical characteristics of the major trace elements in the surrounding peridotites and the PMMs and/or metasomatite. This observation suggests that the two differences are derived from the altered protolith minerals instead of from the fluid metasomatism. Furthermore, the chlorite in the metasomatites inherits the properties of the chlorite component in the PMMs. This study examines the development of PMMs that might undergo two different mechanisms or (at least) two different periods of genesis, i.e., early ultramafic magma xenoliths and metasomatism, as indicated by the rock fabric, and late rodingitization, as indicated by the assemblage of altered minerals and the suite of geochemical affinities. The mechanism by which PMMs develop in peridotites reveals that some podiform chromite in this area may also be xenoliths that formed after chromite was captured by ultramafic magmas in early times.
Bibliography:Funding information
National Key R&D Program of China, Grant/Award Number: 2017YFC0601204
ISSN:0072-1050
1099-1034
DOI:10.1002/gj.3748