Lithological, rheological, and fluid infiltration control on 40Ar/39Ar ages in polydeformed rocks from the West Cycladic detachment system, Greece
In situ ultraviolet (UV) laser-ablation 40Ar/39Ar dating, microstructural analysis, and stable O, H, and C isotope analyses were performed on white mica-bearing calcite- and quartz-mica schists of the West Cycladic detachment system footwall in order to resolve outstanding uncertainties about the ti...
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| Veröffentlicht in: | Lithosphere 2015-04, Vol.7 (2), p.189-205 |
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| description | In situ ultraviolet (UV) laser-ablation 40Ar/39Ar dating, microstructural analysis, and stable O, H, and C isotope analyses were performed on white mica-bearing calcite- and quartz-mica schists of the West Cycladic detachment system footwall in order to resolve outstanding uncertainties about the timing of deformation and the role of rock rheology on 40Ar/39Ar dating systematics. In both quartz-rich and calcite-rich samples, deformed and chemically zoned white micas form two chemical populations: (1) a high component of Al-celadonite in undeformed portions of grains (high-pressure remnants), and (2) enrichment in muscovite in deformed portions (low-pressure neocrystallization). Micas in the quartz-rich rocks record higher internal strain, illustrated by elongated, sheared grains and boudinaged mica-fish structures. In this lithology, quartz formed a load-bearing framework that transferred strain to the muscovite packets and facilitated the formation of mica-fish structures. Recrystallization was promoted by coeval fluid infiltration, supported by stable isotope analyses and indented boundaries on bulging quartz grains. In rocks containing calcite-muscovite aggregates, the calcite formed an interconnected weak layer, with strain being accommodated by dislocation creep. In these rocks, micas were only partially neocrystallized. Prismatic white micas, largely unaffected by boudinage or kinking, yielded 40Ar/39Ar ages that are up to 10 m.y. older than deformed (kinked or sheared) portions of the same grains. Overall, the ages attest to strong lithological control on deformation- and fluid-controlled white mica neocrystallization. The oldest, undeformed grain ages in the calcite-rich rocks are consistent with the timing of Eocene metamorphism, with the deformed grain ages interpreted as representing the transition to lower-pressure conditions during nascent extension. Completely neocrystallized grains in the quartz-rich rocks are interpreted as defining the minimum age of Miocene ductile extension along the detachment system. The new data show the power of combining in situ laser-ablation 40Ar/39Ar dating, microstructural analysis, mineral chemistry, and stable isotope data for unraveling the timing and time scales of complex deformation histories. |
| doi_str_mv | 10.1130/L416.1 |
| format | Article |
| fullrecord | <record><control><sourceid>geoscienceworld</sourceid><recordid>TN_cdi_geoscienceworld_journals_2015_019919</recordid><sourceformat>XML</sourceformat><sourcesystem>PC</sourcesystem><sourcerecordid>2015_019919</sourcerecordid><originalsourceid>FETCH-LOGICAL-g121t-c275101e08342a74694e960264327f928a83029bb12c779a129a9ef4ac5f3f243</originalsourceid><addsrcrecordid>eNpFj8FKAzEYhHNQsFZ9htzttvmTdHdzLEWrsOBF8VjS7J_d1OxGkhTpa_jELih4mhn4mGEIuQO2BBBs1Ugol3BBZqAkFDUv5RW5TunIWFlWVTUj343LffChc0b7BY09_gc9ttT6k2upG63zOerswkhNGHMMnk5Wsk1cCbWJVHeYJox-Bn9u0YY4YEtjMB-J2hgGmnuk75gy3Z6N160ztMWsTT_gmGk6p4zDgu4iosEbcmm1T3j7p3Py9vjwun0qmpfd83bTFB1wyIXh1RoYIKuF5LqSpZKoSjZdFLyyite6FoyrwwG4qSqlgSut0Ept1lZYLsWc3P_2dhiScTga_ArRt_tjOMVxWt5zBus9A6VAiR_w_WZ5</addsrcrecordid><sourcetype>Publisher</sourcetype><iscdi>true</iscdi><recordtype>article</recordtype></control><display><type>article</type><title>Lithological, rheological, and fluid infiltration control on 40Ar/39Ar ages in polydeformed rocks from the West Cycladic detachment system, Greece</title><source>Free E-Journal (出版社公開部分のみ)</source><creator>Cossette, E ; Schneider, D. A ; Warren, C. J ; Grasemann, B</creator><creatorcontrib>Cossette, E ; Schneider, D. A ; Warren, C. J ; Grasemann, B</creatorcontrib><description>In situ ultraviolet (UV) laser-ablation 40Ar/39Ar dating, microstructural analysis, and stable O, H, and C isotope analyses were performed on white mica-bearing calcite- and quartz-mica schists of the West Cycladic detachment system footwall in order to resolve outstanding uncertainties about the timing of deformation and the role of rock rheology on 40Ar/39Ar dating systematics. In both quartz-rich and calcite-rich samples, deformed and chemically zoned white micas form two chemical populations: (1) a high component of Al-celadonite in undeformed portions of grains (high-pressure remnants), and (2) enrichment in muscovite in deformed portions (low-pressure neocrystallization). Micas in the quartz-rich rocks record higher internal strain, illustrated by elongated, sheared grains and boudinaged mica-fish structures. In this lithology, quartz formed a load-bearing framework that transferred strain to the muscovite packets and facilitated the formation of mica-fish structures. Recrystallization was promoted by coeval fluid infiltration, supported by stable isotope analyses and indented boundaries on bulging quartz grains. In rocks containing calcite-muscovite aggregates, the calcite formed an interconnected weak layer, with strain being accommodated by dislocation creep. In these rocks, micas were only partially neocrystallized. Prismatic white micas, largely unaffected by boudinage or kinking, yielded 40Ar/39Ar ages that are up to 10 m.y. older than deformed (kinked or sheared) portions of the same grains. Overall, the ages attest to strong lithological control on deformation- and fluid-controlled white mica neocrystallization. The oldest, undeformed grain ages in the calcite-rich rocks are consistent with the timing of Eocene metamorphism, with the deformed grain ages interpreted as representing the transition to lower-pressure conditions during nascent extension. Completely neocrystallized grains in the quartz-rich rocks are interpreted as defining the minimum age of Miocene ductile extension along the detachment system. The new data show the power of combining in situ laser-ablation 40Ar/39Ar dating, microstructural analysis, mineral chemistry, and stable isotope data for unraveling the timing and time scales of complex deformation histories.</description><identifier>ISSN: 1941-8264</identifier><identifier>DOI: 10.1130/L416.1</identifier><language>eng</language><publisher>Geological Society of America</publisher><subject>absolute age ; Aegean Islands ; Ar/Ar ; Attic-Cycladic Complex ; backscattering ; basement ; blueschist facies ; brittle deformation ; BSE imagery ; C-13/C-12 ; calcite ; carbon ; carbonates ; celadonite ; Cenozoic ; chemical composition ; complexes ; crystal chemistry ; crystalline rocks ; crystallization ; Cyclades ; D/H ; dates ; decollement ; deformation ; ductile deformation ; electron microscopy data ; Eocene ; Europe ; extension tectonics ; facies ; faults ; fluid phase ; foot wall ; framework silicates ; Geochronology ; Greece ; Greek Aegean Islands ; hydrogen ; in situ ; infiltration ; isotope ratios ; isotopes ; Kea Island ; kink-band structures ; laser ablation ; laser methods ; lithosphere ; major elements ; Mediterranean region ; metamorphic rocks ; metamorphism ; mica group ; mica schists ; microstructure ; mineral assemblages ; mineral composition ; Miocene ; mixing ; muscovite ; mylonites ; Neogene ; O-18/O-16 ; overprinting ; oxygen ; Paleogene ; polyphase processes ; pressure ; quartz ; recrystallization ; rheology ; schists ; SEM data ; Serifos Island ; shear zones ; sheet silicates ; silica minerals ; silicates ; Southern Europe ; spectra ; stable isotopes ; strain ; substitution ; systems ; tectonics ; Tertiary ; ultraviolet spectra ; water-rock interaction ; West Cycladic detachment system</subject><ispartof>Lithosphere, 2015-04, Vol.7 (2), p.189-205</ispartof><rights>GeoRef, Copyright 2022, American Geosciences Institute. Reference includes data from GeoScienceWorld @Alexandria, VA @USA @United States. Reference includes data supplied by the Geological Society of America @Boulder, CO @USA @United States</rights><lds50>peer_reviewed</lds50><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>314,780,784,27922,27923</link.rule.ids></links><search><creatorcontrib>Cossette, E</creatorcontrib><creatorcontrib>Schneider, D. A</creatorcontrib><creatorcontrib>Warren, C. J</creatorcontrib><creatorcontrib>Grasemann, B</creatorcontrib><title>Lithological, rheological, and fluid infiltration control on 40Ar/39Ar ages in polydeformed rocks from the West Cycladic detachment system, Greece</title><title>Lithosphere</title><description>In situ ultraviolet (UV) laser-ablation 40Ar/39Ar dating, microstructural analysis, and stable O, H, and C isotope analyses were performed on white mica-bearing calcite- and quartz-mica schists of the West Cycladic detachment system footwall in order to resolve outstanding uncertainties about the timing of deformation and the role of rock rheology on 40Ar/39Ar dating systematics. In both quartz-rich and calcite-rich samples, deformed and chemically zoned white micas form two chemical populations: (1) a high component of Al-celadonite in undeformed portions of grains (high-pressure remnants), and (2) enrichment in muscovite in deformed portions (low-pressure neocrystallization). Micas in the quartz-rich rocks record higher internal strain, illustrated by elongated, sheared grains and boudinaged mica-fish structures. In this lithology, quartz formed a load-bearing framework that transferred strain to the muscovite packets and facilitated the formation of mica-fish structures. Recrystallization was promoted by coeval fluid infiltration, supported by stable isotope analyses and indented boundaries on bulging quartz grains. In rocks containing calcite-muscovite aggregates, the calcite formed an interconnected weak layer, with strain being accommodated by dislocation creep. In these rocks, micas were only partially neocrystallized. Prismatic white micas, largely unaffected by boudinage or kinking, yielded 40Ar/39Ar ages that are up to 10 m.y. older than deformed (kinked or sheared) portions of the same grains. Overall, the ages attest to strong lithological control on deformation- and fluid-controlled white mica neocrystallization. The oldest, undeformed grain ages in the calcite-rich rocks are consistent with the timing of Eocene metamorphism, with the deformed grain ages interpreted as representing the transition to lower-pressure conditions during nascent extension. Completely neocrystallized grains in the quartz-rich rocks are interpreted as defining the minimum age of Miocene ductile extension along the detachment system. The new data show the power of combining in situ laser-ablation 40Ar/39Ar dating, microstructural analysis, mineral chemistry, and stable isotope data for unraveling the timing and time scales of complex deformation histories.</description><subject>absolute age</subject><subject>Aegean Islands</subject><subject>Ar/Ar</subject><subject>Attic-Cycladic Complex</subject><subject>backscattering</subject><subject>basement</subject><subject>blueschist facies</subject><subject>brittle deformation</subject><subject>BSE imagery</subject><subject>C-13/C-12</subject><subject>calcite</subject><subject>carbon</subject><subject>carbonates</subject><subject>celadonite</subject><subject>Cenozoic</subject><subject>chemical composition</subject><subject>complexes</subject><subject>crystal chemistry</subject><subject>crystalline rocks</subject><subject>crystallization</subject><subject>Cyclades</subject><subject>D/H</subject><subject>dates</subject><subject>decollement</subject><subject>deformation</subject><subject>ductile deformation</subject><subject>electron microscopy data</subject><subject>Eocene</subject><subject>Europe</subject><subject>extension tectonics</subject><subject>facies</subject><subject>faults</subject><subject>fluid phase</subject><subject>foot wall</subject><subject>framework silicates</subject><subject>Geochronology</subject><subject>Greece</subject><subject>Greek Aegean Islands</subject><subject>hydrogen</subject><subject>in situ</subject><subject>infiltration</subject><subject>isotope ratios</subject><subject>isotopes</subject><subject>Kea Island</subject><subject>kink-band structures</subject><subject>laser ablation</subject><subject>laser methods</subject><subject>lithosphere</subject><subject>major elements</subject><subject>Mediterranean region</subject><subject>metamorphic rocks</subject><subject>metamorphism</subject><subject>mica group</subject><subject>mica schists</subject><subject>microstructure</subject><subject>mineral assemblages</subject><subject>mineral composition</subject><subject>Miocene</subject><subject>mixing</subject><subject>muscovite</subject><subject>mylonites</subject><subject>Neogene</subject><subject>O-18/O-16</subject><subject>overprinting</subject><subject>oxygen</subject><subject>Paleogene</subject><subject>polyphase processes</subject><subject>pressure</subject><subject>quartz</subject><subject>recrystallization</subject><subject>rheology</subject><subject>schists</subject><subject>SEM data</subject><subject>Serifos Island</subject><subject>shear zones</subject><subject>sheet silicates</subject><subject>silica minerals</subject><subject>silicates</subject><subject>Southern Europe</subject><subject>spectra</subject><subject>stable isotopes</subject><subject>strain</subject><subject>substitution</subject><subject>systems</subject><subject>tectonics</subject><subject>Tertiary</subject><subject>ultraviolet spectra</subject><subject>water-rock interaction</subject><subject>West Cycladic detachment system</subject><issn>1941-8264</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2015</creationdate><recordtype>article</recordtype><sourceid/><recordid>eNpFj8FKAzEYhHNQsFZ9htzttvmTdHdzLEWrsOBF8VjS7J_d1OxGkhTpa_jELih4mhn4mGEIuQO2BBBs1Ugol3BBZqAkFDUv5RW5TunIWFlWVTUj343LffChc0b7BY09_gc9ttT6k2upG63zOerswkhNGHMMnk5Wsk1cCbWJVHeYJox-Bn9u0YY4YEtjMB-J2hgGmnuk75gy3Z6N160ztMWsTT_gmGk6p4zDgu4iosEbcmm1T3j7p3Py9vjwun0qmpfd83bTFB1wyIXh1RoYIKuF5LqSpZKoSjZdFLyyite6FoyrwwG4qSqlgSut0Ept1lZYLsWc3P_2dhiScTga_ArRt_tjOMVxWt5zBus9A6VAiR_w_WZ5</recordid><startdate>20150401</startdate><enddate>20150401</enddate><creator>Cossette, E</creator><creator>Schneider, D. A</creator><creator>Warren, C. J</creator><creator>Grasemann, B</creator><general>Geological Society of America</general><scope/></search><sort><creationdate>20150401</creationdate><title>Lithological, rheological, and fluid infiltration control on 40Ar/39Ar ages in polydeformed rocks from the West Cycladic detachment system, Greece</title><author>Cossette, E ; Schneider, D. A ; Warren, C. J ; Grasemann, B</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-g121t-c275101e08342a74694e960264327f928a83029bb12c779a129a9ef4ac5f3f243</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2015</creationdate><topic>absolute age</topic><topic>Aegean Islands</topic><topic>Ar/Ar</topic><topic>Attic-Cycladic Complex</topic><topic>backscattering</topic><topic>basement</topic><topic>blueschist facies</topic><topic>brittle deformation</topic><topic>BSE imagery</topic><topic>C-13/C-12</topic><topic>calcite</topic><topic>carbon</topic><topic>carbonates</topic><topic>celadonite</topic><topic>Cenozoic</topic><topic>chemical composition</topic><topic>complexes</topic><topic>crystal chemistry</topic><topic>crystalline rocks</topic><topic>crystallization</topic><topic>Cyclades</topic><topic>D/H</topic><topic>dates</topic><topic>decollement</topic><topic>deformation</topic><topic>ductile deformation</topic><topic>electron microscopy data</topic><topic>Eocene</topic><topic>Europe</topic><topic>extension tectonics</topic><topic>facies</topic><topic>faults</topic><topic>fluid phase</topic><topic>foot wall</topic><topic>framework silicates</topic><topic>Geochronology</topic><topic>Greece</topic><topic>Greek Aegean Islands</topic><topic>hydrogen</topic><topic>in situ</topic><topic>infiltration</topic><topic>isotope ratios</topic><topic>isotopes</topic><topic>Kea Island</topic><topic>kink-band structures</topic><topic>laser ablation</topic><topic>laser methods</topic><topic>lithosphere</topic><topic>major elements</topic><topic>Mediterranean region</topic><topic>metamorphic rocks</topic><topic>metamorphism</topic><topic>mica group</topic><topic>mica schists</topic><topic>microstructure</topic><topic>mineral assemblages</topic><topic>mineral composition</topic><topic>Miocene</topic><topic>mixing</topic><topic>muscovite</topic><topic>mylonites</topic><topic>Neogene</topic><topic>O-18/O-16</topic><topic>overprinting</topic><topic>oxygen</topic><topic>Paleogene</topic><topic>polyphase processes</topic><topic>pressure</topic><topic>quartz</topic><topic>recrystallization</topic><topic>rheology</topic><topic>schists</topic><topic>SEM data</topic><topic>Serifos Island</topic><topic>shear zones</topic><topic>sheet silicates</topic><topic>silica minerals</topic><topic>silicates</topic><topic>Southern Europe</topic><topic>spectra</topic><topic>stable isotopes</topic><topic>strain</topic><topic>substitution</topic><topic>systems</topic><topic>tectonics</topic><topic>Tertiary</topic><topic>ultraviolet spectra</topic><topic>water-rock interaction</topic><topic>West Cycladic detachment system</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Cossette, E</creatorcontrib><creatorcontrib>Schneider, D. A</creatorcontrib><creatorcontrib>Warren, C. J</creatorcontrib><creatorcontrib>Grasemann, B</creatorcontrib><jtitle>Lithosphere</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Cossette, E</au><au>Schneider, D. A</au><au>Warren, C. J</au><au>Grasemann, B</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Lithological, rheological, and fluid infiltration control on 40Ar/39Ar ages in polydeformed rocks from the West Cycladic detachment system, Greece</atitle><jtitle>Lithosphere</jtitle><date>2015-04-01</date><risdate>2015</risdate><volume>7</volume><issue>2</issue><spage>189</spage><epage>205</epage><pages>189-205</pages><issn>1941-8264</issn><abstract>In situ ultraviolet (UV) laser-ablation 40Ar/39Ar dating, microstructural analysis, and stable O, H, and C isotope analyses were performed on white mica-bearing calcite- and quartz-mica schists of the West Cycladic detachment system footwall in order to resolve outstanding uncertainties about the timing of deformation and the role of rock rheology on 40Ar/39Ar dating systematics. In both quartz-rich and calcite-rich samples, deformed and chemically zoned white micas form two chemical populations: (1) a high component of Al-celadonite in undeformed portions of grains (high-pressure remnants), and (2) enrichment in muscovite in deformed portions (low-pressure neocrystallization). Micas in the quartz-rich rocks record higher internal strain, illustrated by elongated, sheared grains and boudinaged mica-fish structures. In this lithology, quartz formed a load-bearing framework that transferred strain to the muscovite packets and facilitated the formation of mica-fish structures. Recrystallization was promoted by coeval fluid infiltration, supported by stable isotope analyses and indented boundaries on bulging quartz grains. In rocks containing calcite-muscovite aggregates, the calcite formed an interconnected weak layer, with strain being accommodated by dislocation creep. In these rocks, micas were only partially neocrystallized. Prismatic white micas, largely unaffected by boudinage or kinking, yielded 40Ar/39Ar ages that are up to 10 m.y. older than deformed (kinked or sheared) portions of the same grains. Overall, the ages attest to strong lithological control on deformation- and fluid-controlled white mica neocrystallization. The oldest, undeformed grain ages in the calcite-rich rocks are consistent with the timing of Eocene metamorphism, with the deformed grain ages interpreted as representing the transition to lower-pressure conditions during nascent extension. Completely neocrystallized grains in the quartz-rich rocks are interpreted as defining the minimum age of Miocene ductile extension along the detachment system. The new data show the power of combining in situ laser-ablation 40Ar/39Ar dating, microstructural analysis, mineral chemistry, and stable isotope data for unraveling the timing and time scales of complex deformation histories.</abstract><pub>Geological Society of America</pub><doi>10.1130/L416.1</doi><tpages>17</tpages><oa>free_for_read</oa></addata></record> |
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| subjects | absolute age Aegean Islands Ar/Ar Attic-Cycladic Complex backscattering basement blueschist facies brittle deformation BSE imagery C-13/C-12 calcite carbon carbonates celadonite Cenozoic chemical composition complexes crystal chemistry crystalline rocks crystallization Cyclades D/H dates decollement deformation ductile deformation electron microscopy data Eocene Europe extension tectonics facies faults fluid phase foot wall framework silicates Geochronology Greece Greek Aegean Islands hydrogen in situ infiltration isotope ratios isotopes Kea Island kink-band structures laser ablation laser methods lithosphere major elements Mediterranean region metamorphic rocks metamorphism mica group mica schists microstructure mineral assemblages mineral composition Miocene mixing muscovite mylonites Neogene O-18/O-16 overprinting oxygen Paleogene polyphase processes pressure quartz recrystallization rheology schists SEM data Serifos Island shear zones sheet silicates silica minerals silicates Southern Europe spectra stable isotopes strain substitution systems tectonics Tertiary ultraviolet spectra water-rock interaction West Cycladic detachment system |
| title | Lithological, rheological, and fluid infiltration control on 40Ar/39Ar ages in polydeformed rocks from the West Cycladic detachment system, Greece |
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