Plagioclase-chain networks in slowly cooled basaltic magma

Plagioclase crystals in the slowly cooled interior of the thick Holyoke flood-basalt flow of Connecticut linked to form monomineralic chains at an early crystallization stage. Partial melting experiments reveal that when the quartz tholeiite was only 25% crystallized the chains had already linked to...

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Veröffentlicht in:	The American mineralogist 1999-12, Vol.84 (11-12), p.1819-1829
Hauptverfasser:	Philpotts, Anthony R, Brustman, Caroline M, Shi, Jianyang, Carlson, William D, Denison, Cambria
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Sprache:	eng
Schlagworte:	Basalt basalt flows basalts central Connecticut Connecticut crystal zoning Crystallization Crystals feldspar group fractional crystallization framework silicates Holyoke Basalt igneous and metamorphic rocks igneous rocks Jurassic Lower Jurassic magmas Mesozoic mineral composition Mineralogy partial melting Petrology plagioclase silicates United States volcanic rocks
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container_issue	11-12
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creator	Philpotts, Anthony R Brustman, Caroline M Shi, Jianyang Carlson, William D Denison, Cambria
description	Plagioclase crystals in the slowly cooled interior of the thick Holyoke flood-basalt flow of Connecticut linked to form monomineralic chains at an early crystallization stage. Partial melting experiments reveal that when the quartz tholeiite was only 25% crystallized the chains had already linked to form a continuous 3-D network. At such an early stage of crystallization, the network was weak, highly permeable, and easily deformed. Consequently, the mush of plagioclase-chains and interstitial pyroxene crystals underwent compaction in the lower third of the flow with the expelled liquid rising to the center of the flow where it crystallized to form coarse-grained sheets of fractionated basalt. Plagioclase chains are most easily seen in the basalt after it has been partly melted and the late crystallizing minerals converted to glass. The chains are several crystals wide. The crystals, which are ∼0.5 mm long, are attached together randomly. Normal zoning patterns indicate crystals had a brief period of growth before linking together. The chains branch every few millimeters to form the 3-D network, which was mapped using serial polished sections and X-ray CT scans. The chain frequency measured along vertical and horizontal traverses decreases toward the center of the flow. In the compaction zone, the frequency in the vertical direction is greater than in the horizontal. Making the reasonable assumption that these frequencies were initially the same, the difference is used to calculate the degree of compaction. The resulting pattern through the flow matches almost exactly the pattern indicated by variations in the incompatible elements. Plagioclase chains are also found in some coarser-grained plutonic rocks. If they are common, their fabric may provide a new, direct means of measuring the degree of compaction in crystal mushes.
doi_str_mv	10.2138/am-1999-11-1209
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Partial melting experiments reveal that when the quartz tholeiite was only 25% crystallized the chains had already linked to form a continuous 3-D network. At such an early stage of crystallization, the network was weak, highly permeable, and easily deformed. Consequently, the mush of plagioclase-chains and interstitial pyroxene crystals underwent compaction in the lower third of the flow with the expelled liquid rising to the center of the flow where it crystallized to form coarse-grained sheets of fractionated basalt. Plagioclase chains are most easily seen in the basalt after it has been partly melted and the late crystallizing minerals converted to glass. The chains are several crystals wide. The crystals, which are ∼0.5 mm long, are attached together randomly. Normal zoning patterns indicate crystals had a brief period of growth before linking together. The chains branch every few millimeters to form the 3-D network, which was mapped using serial polished sections and X-ray CT scans. The chain frequency measured along vertical and horizontal traverses decreases toward the center of the flow. In the compaction zone, the frequency in the vertical direction is greater than in the horizontal. Making the reasonable assumption that these frequencies were initially the same, the difference is used to calculate the degree of compaction. The resulting pattern through the flow matches almost exactly the pattern indicated by variations in the incompatible elements. Plagioclase chains are also found in some coarser-grained plutonic rocks. 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Partial melting experiments reveal that when the quartz tholeiite was only 25% crystallized the chains had already linked to form a continuous 3-D network. At such an early stage of crystallization, the network was weak, highly permeable, and easily deformed. Consequently, the mush of plagioclase-chains and interstitial pyroxene crystals underwent compaction in the lower third of the flow with the expelled liquid rising to the center of the flow where it crystallized to form coarse-grained sheets of fractionated basalt. Plagioclase chains are most easily seen in the basalt after it has been partly melted and the late crystallizing minerals converted to glass. The chains are several crystals wide. The crystals, which are ∼0.5 mm long, are attached together randomly. Normal zoning patterns indicate crystals had a brief period of growth before linking together. The chains branch every few millimeters to form the 3-D network, which was mapped using serial polished sections and X-ray CT scans. The chain frequency measured along vertical and horizontal traverses decreases toward the center of the flow. In the compaction zone, the frequency in the vertical direction is greater than in the horizontal. Making the reasonable assumption that these frequencies were initially the same, the difference is used to calculate the degree of compaction. The resulting pattern through the flow matches almost exactly the pattern indicated by variations in the incompatible elements. Plagioclase chains are also found in some coarser-grained plutonic rocks. If they are common, their fabric may provide a new, direct means of measuring the degree of compaction in crystal mushes.</description><subject>Basalt</subject><subject>basalt flows</subject><subject>basalts</subject><subject>central Connecticut</subject><subject>Connecticut</subject><subject>crystal zoning</subject><subject>Crystallization</subject><subject>Crystals</subject><subject>feldspar group</subject><subject>fractional crystallization</subject><subject>framework silicates</subject><subject>Holyoke Basalt</subject><subject>igneous and metamorphic rocks</subject><subject>igneous rocks</subject><subject>Jurassic</subject><subject>Lower Jurassic</subject><subject>magmas</subject><subject>Mesozoic</subject><subject>mineral composition</subject><subject>Mineralogy</subject><subject>partial melting</subject><subject>Petrology</subject><subject>plagioclase</subject><subject>silicates</subject><subject>United States</subject><subject>volcanic rocks</subject><issn>0003-004X</issn><issn>1945-3027</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>1999</creationdate><recordtype>article</recordtype><recordid>eNp1kL1PwzAQxS0EEqUws0asyHBnO2nMBhVfUiUYQGKz_JWSktTFTlX1vyehSLAw3Rvee3f3I-QU4YIhLy91S1FKSREpMpB7ZIRS5JQDm-yTEQBwCiDeDslRSgsAxnguR-TqudHzOthGJ0_tu66X2dJ3mxA_Utbr1IRNs81sCI13mdFJN11ts1bPW31MDirdJH_yM8fk9e72ZfpAZ0_3j9PrGdVCYkdFbgQTaE1eaV4KV_Gq4lxC6dBJKIyRiF5L48rKSC-8c7ljoLnhVpbGT_iYnO16VzF8rn3q1CKs47JfqRgHKCZY5r3pcmeyMaQUfaVWsW513CoENfBRulUDH4WoBj594maX2PQ_-ej8PK63vfht_ydZim-BJQ4l57uSuQ_J1n5pfc-ucX9O7MkrYEUuC_4FPgp8ug</recordid><startdate>19991201</startdate><enddate>19991201</enddate><creator>Philpotts, Anthony R</creator><creator>Brustman, Caroline M</creator><creator>Shi, Jianyang</creator><creator>Carlson, William D</creator><creator>Denison, Cambria</creator><general>Mineralogical Society of America</general><general>Walter de Gruyter GmbH</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7TN</scope><scope>F1W</scope><scope>H96</scope><scope>L.G</scope></search><sort><creationdate>19991201</creationdate><title>Plagioclase-chain networks in slowly cooled basaltic magma</title><author>Philpotts, Anthony R ; Brustman, Caroline M ; Shi, Jianyang ; Carlson, William D ; Denison, Cambria</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a491t-45b4241cb5fa384df3ff33908d1d906bb911ea9bd8fb9e4edd5d20a3b3c98be73</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>1999</creationdate><topic>Basalt</topic><topic>basalt flows</topic><topic>basalts</topic><topic>central Connecticut</topic><topic>Connecticut</topic><topic>crystal zoning</topic><topic>Crystallization</topic><topic>Crystals</topic><topic>feldspar group</topic><topic>fractional crystallization</topic><topic>framework silicates</topic><topic>Holyoke Basalt</topic><topic>igneous and metamorphic rocks</topic><topic>igneous rocks</topic><topic>Jurassic</topic><topic>Lower Jurassic</topic><topic>magmas</topic><topic>Mesozoic</topic><topic>mineral composition</topic><topic>Mineralogy</topic><topic>partial melting</topic><topic>Petrology</topic><topic>plagioclase</topic><topic>silicates</topic><topic>United States</topic><topic>volcanic rocks</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Philpotts, Anthony R</creatorcontrib><creatorcontrib>Brustman, Caroline M</creatorcontrib><creatorcontrib>Shi, Jianyang</creatorcontrib><creatorcontrib>Carlson, William D</creatorcontrib><creatorcontrib>Denison, Cambria</creatorcontrib><collection>CrossRef</collection><collection>Oceanic Abstracts</collection><collection>ASFA: Aquatic Sciences and Fisheries Abstracts</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) 2: Ocean Technology, Policy & Non-Living Resources</collection><collection>Aquatic Science & Fisheries Abstracts (ASFA) Professional</collection><jtitle>The American mineralogist</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Philpotts, Anthony R</au><au>Brustman, Caroline M</au><au>Shi, Jianyang</au><au>Carlson, William D</au><au>Denison, Cambria</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Plagioclase-chain networks in slowly cooled basaltic magma</atitle><jtitle>The American mineralogist</jtitle><date>1999-12-01</date><risdate>1999</risdate><volume>84</volume><issue>11-12</issue><spage>1819</spage><epage>1829</epage><pages>1819-1829</pages><issn>0003-004X</issn><eissn>1945-3027</eissn><coden>AMMIAY</coden><abstract>Plagioclase crystals in the slowly cooled interior of the thick Holyoke flood-basalt flow of Connecticut linked to form monomineralic chains at an early crystallization stage. Partial melting experiments reveal that when the quartz tholeiite was only 25% crystallized the chains had already linked to form a continuous 3-D network. At such an early stage of crystallization, the network was weak, highly permeable, and easily deformed. Consequently, the mush of plagioclase-chains and interstitial pyroxene crystals underwent compaction in the lower third of the flow with the expelled liquid rising to the center of the flow where it crystallized to form coarse-grained sheets of fractionated basalt. Plagioclase chains are most easily seen in the basalt after it has been partly melted and the late crystallizing minerals converted to glass. The chains are several crystals wide. The crystals, which are ∼0.5 mm long, are attached together randomly. Normal zoning patterns indicate crystals had a brief period of growth before linking together. 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subjects	Basalt basalt flows basalts central Connecticut Connecticut crystal zoning Crystallization Crystals feldspar group fractional crystallization framework silicates Holyoke Basalt igneous and metamorphic rocks igneous rocks Jurassic Lower Jurassic magmas Mesozoic mineral composition Mineralogy partial melting Petrology plagioclase silicates United States volcanic rocks
title	Plagioclase-chain networks in slowly cooled basaltic magma
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