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Al-Fe (super 3+) and Ca-Sr (super 2+) epidotes in metagreywacke-quartzofeldspathic schist, Southern Alps, New Zealand

Rodney Grapes and Teruo Watanabe
Al-Fe (super 3+) and Ca-Sr (super 2+) epidotes in metagreywacke-quartzofeldspathic schist, Southern Alps, New Zealand
American Mineralogist (June 1984) 69 (5-6): 490-498

Abstract

Al-Fe (super 3+ or -) and Sr (super 2+ or -) -bearing epidotes are a common constituent in chlorite and biotite-albite zone metagreywacke-quartzofeldspathic schist in the Southern Alps of New Zealand. On the basis of electron microprobe backscattered electron scanning of complexly zoned grains five generations of epidote growth are recognized. First generation epidotes (Ps (sub 29-25) ) are typically fractured as a result of cataclasis during D1 deformation and presumably represent relics of prehnite-pumpellyite and or pumpellyiteactinolite facies conditions of metamorphism. Second generation epidote (Ps (sub 25-20) ) rims first generation epidote and replaces fragmented grains. Third generation epidote involved Sr replacement, up to 8.5 wt. % SrO, of earlier grains along fracture planes and grain margins. Single grains exhibit a range of Sr = Ca replacement that can vary by up to 4 wt. % SrO. Fourth generation (post D (sub 1) ) epidote (Ps (sub 20-9) ) occurs as overgrowths on earlier generation epidotes and as continuously zoned grains. Within the lowest grade part of the biotite-albite-oligoclase zone fourth generation epidote cores (Ps (sub 10-13) ) are overgrown by slightly more Fe-rich fifth generation rims (Ps (sub 16-14) ) suggesting involvement of the epidote Ca (sub 2) Al (sub 3) Si (sub 3) O (sub 12) (OH) component in an oligoclase-producing reaction. In quartzofeldspathic lithologies epidote disappears at higher grades than the appearance of oligoclase. Epidote compositions plot within the miscibility gap defined, and a discontinuity between compositions of Ps (sub 20) and Ps (sub 16) in chlorite zone rocks is attributed to the persistence of relic cores due to incomplete Fe (super 3+) = Al diffusional exchange at low temperature and textural grade. With increasing grade there is a decrease in the range of zoning in individual epidote grains resulting in a more homogeneous population of epidote compositions with the most Al-rich epidotes becoming Fe (super 3+ or -) -rich and the most Fe (super 3+ or -) -rich epidotes becoming more Al-rich. The formation of Sr epidote appears to be related to the release of Sr into the fluid phase from the breakdown of detrital plagioclase over the pumpellyite clinozoisite isograd during D1 deformation. Early formed oligoclase in the biotite-albite-oligoclase zone resulting from the disappearance of epidote contains up to 0.4% SrO. Mobility of Sr (and Ca) is indicated by veins containing Sr-bearing epidote and calcite. The complex zoning of epidotes is a function of bulk composition, time, variation in fluid composition, temperature, pressure and deformation of the rocks.


ISSN: 0003-004X
EISSN: 1945-3027
Coden: AMMIAY
Serial Title: American Mineralogist
Serial Volume: 69
Serial Issue: 5-6
Title: Al-Fe (super 3+) and Ca-Sr (super 2+) epidotes in metagreywacke-quartzofeldspathic schist, Southern Alps, New Zealand
Affiliation: Victoria Univ. Wellington, Jonit Miner. Sci. Res. Lab., Wellington, Netherlands
Pages: 490-498
Published: 198406
Text Language: English
Publisher: Mineralogical Society of America, Washington, DC, United States
Accession Number: 1986-019508
Categories: Igneous and metamorphic petrologyMineralogy of silicates
Document Type: Serial
Bibliographic Level: Analytic
Illustration Description: illus. incl. 2 tables
S47°30'00" - S34°30'00", E166°30'00" - E178°30'00"
Country of Publication: United States
Secondary Affiliation: GeoRef, Copyright 2017, American Geosciences Institute. Reference includes data supplied by Institute of Geological and Nuclear Sciences Limited (GNS Science), Lower Hutt, New Zealand
Update Code: 1986
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