岩矿测试
巖礦測試
암광측시
ROCK AND MINERAL ANALYSIS
2014年
6期
900-907
,共8页
李文良%夏锐%卿敏%李超%张栋%孙昊%路英川%刘鹏%周奥博
李文良%夏銳%卿敏%李超%張棟%孫昊%路英川%劉鵬%週奧博
리문량%하예%경민%리초%장동%손호%로영천%류붕%주오박
辉钼矿%Re-Os定年%矽卡岩矿床%成矿时代%地球动力学背景%青海什多龙
輝鉬礦%Re-Os定年%矽卡巖礦床%成礦時代%地毬動力學揹景%青海什多龍
휘목광%Re-Os정년%석잡암광상%성광시대%지구동역학배경%청해십다룡
molybdenite%Re-Os aging%skarn deposit%rock-forming time%geodynamic framework%Shiduolong in Qinghai Province
青海什多龙矽卡岩型Mo-Pb-Zn矿床位于鄂拉山多金属成矿带,该矿床成矿时代制约了成矿过程、动力学背景的探讨。前人通过对矿区及外围岩体的K-Ar法间接取得了188~208 Ma和368 Ma的数据,由于分析测试手段限制,时间跨度较大,对于成岩成矿时代的厘定尚缺乏精确的同位素年龄数据。本文采用辉钼矿Re-Os同位素定年方法测定该矿床的成矿时代,为矿床模型的建立和反演成矿地球动力学背景研究提供可靠的基础资料。分析结果显示,6件辉钼矿样品Re-Os同位素模式年龄的变化范围小,集中在234.2~240.1 Ma之间,加权平均年龄值为(236.2±2.1)Ma,与等时线回归计算得到的年龄值(233.4±9.6)Ma在误差范围内相吻合,表明成矿时代为(236.2±2.1)Ma。辉钼矿的铼含量为0.3939×10-6~0.6621 × 10-6,反映了成矿物质以壳源为主,且变质流体参与了成矿作用。本研究Re-Os定年结果显示什多龙矽卡岩型Mo-Pb-Zn矿床与鄂拉山造山带成岩年龄(约220~230 Ma)接近,表明成岩成矿受控于相同的动力学背景,是在鄂拉山造洋裂谷体制向碰撞-伸展造山体制转变的过程中,导致加厚下地壳的部分熔融而引起的印支晚期岩浆-热液事件。
青海什多龍矽卡巖型Mo-Pb-Zn礦床位于鄂拉山多金屬成礦帶,該礦床成礦時代製約瞭成礦過程、動力學揹景的探討。前人通過對礦區及外圍巖體的K-Ar法間接取得瞭188~208 Ma和368 Ma的數據,由于分析測試手段限製,時間跨度較大,對于成巖成礦時代的釐定尚缺乏精確的同位素年齡數據。本文採用輝鉬礦Re-Os同位素定年方法測定該礦床的成礦時代,為礦床模型的建立和反縯成礦地毬動力學揹景研究提供可靠的基礎資料。分析結果顯示,6件輝鉬礦樣品Re-Os同位素模式年齡的變化範圍小,集中在234.2~240.1 Ma之間,加權平均年齡值為(236.2±2.1)Ma,與等時線迴歸計算得到的年齡值(233.4±9.6)Ma在誤差範圍內相吻閤,錶明成礦時代為(236.2±2.1)Ma。輝鉬礦的錸含量為0.3939×10-6~0.6621 × 10-6,反映瞭成礦物質以殼源為主,且變質流體參與瞭成礦作用。本研究Re-Os定年結果顯示什多龍矽卡巖型Mo-Pb-Zn礦床與鄂拉山造山帶成巖年齡(約220~230 Ma)接近,錶明成巖成礦受控于相同的動力學揹景,是在鄂拉山造洋裂穀體製嚮踫撞-伸展造山體製轉變的過程中,導緻加厚下地殼的部分鎔融而引起的印支晚期巖漿-熱液事件。
청해십다룡석잡암형Mo-Pb-Zn광상위우악랍산다금속성광대,해광상성광시대제약료성광과정、동역학배경적탐토。전인통과대광구급외위암체적K-Ar법간접취득료188~208 Ma화368 Ma적수거,유우분석측시수단한제,시간과도교대,대우성암성광시대적전정상결핍정학적동위소년령수거。본문채용휘목광Re-Os동위소정년방법측정해광상적성광시대,위광상모형적건립화반연성광지구동역학배경연구제공가고적기출자료。분석결과현시,6건휘목광양품Re-Os동위소모식년령적변화범위소,집중재234.2~240.1 Ma지간,가권평균년령치위(236.2±2.1)Ma,여등시선회귀계산득도적년령치(233.4±9.6)Ma재오차범위내상문합,표명성광시대위(236.2±2.1)Ma。휘목광적래함량위0.3939×10-6~0.6621 × 10-6,반영료성광물질이각원위주,차변질류체삼여료성광작용。본연구Re-Os정년결과현시십다룡석잡암형Mo-Pb-Zn광상여악랍산조산대성암년령(약220~230 Ma)접근,표명성암성광수공우상동적동역학배경,시재악랍산조양렬곡체제향팽당-신전조산체제전변적과정중,도치가후하지각적부분용융이인기적인지만기암장-열액사건。
The Shiduolong skarn Mo-Pb-Zn deposit is located in the multi-metal metallogenic belt of E’lashan.The precise age of the ore deposit limits our understanding of the ore-forming processes and geodynamical setting.In spite of the K-Ar methods of analysis and testing in the Shiduolong mining area and the periphery of intrusives (1 88-208 Ma and 368 Ma),whether or not thest ages can represent real mineralization times requires to be tested further.In this study,we carried out a Re-Os study of molybdenite from the Shuangqing deposit,providing fundamental data to build the mineral deposit model and reflect the geodynamical setting in this area.6 molybdenite samples of the deposit yield Re-Os isotopic model ages ranging from 234.2 Ma to 240.1 Ma,with a weighted mean age of (236.2 ±2.1 )Ma.A similar isochron age of (233.4 ±9.6 )Ma is also obtained by the isochron regression.This result suggests that the Mo mineralization occurred in last Triassic.The Re contents of molybdenite indicate that ore-forming materials are derived from crust and aqueous fluids involved in the ore-forming stage. Based on the same of rock-forming in E ’lashan and mineralization in Shiduolong Mo-Pb-Zn deposit,rock-forming and ore-forming were regarded as the same geodynamic background of India-Eurasia collision.The tectonic regime changing from developing oceanic rift to collision-extension make the thickened lower crust melt partially in the Indosinian magmatic-tectonic-metallogenic event.
