矿床地质
礦床地質
광상지질
MINERAL DEPOSITS
2009年
4期
403-412
,共10页
李晓峰%冯佐海%李容森%唐专红%屈文俊%李军朝
李曉峰%馮佐海%李容森%唐專紅%屈文俊%李軍朝
리효봉%풍좌해%리용삼%당전홍%굴문준%리군조
地球化学%石英脉型钼矿%志留纪%加里东期%花岗岩%白石顶%华南
地毬化學%石英脈型鉬礦%誌留紀%加裏東期%花崗巖%白石頂%華南
지구화학%석영맥형목광%지류기%가리동기%화강암%백석정%화남
geochemistry%quartz vein mineralization%Silurian%Caledonian%granite%Baishiding%South China
白石顶钼矿床位于湘粤桂交界的桂北姑婆山地区,主要以石英辉钼矿脉的形式产于桂岭岩体(角闪石)黑云母二长花岗岩和南华系浅变质浅海相碎屑岩中.桂岭岩体岩石类型以中-细粒斑状(角闪石)黑云母二长花岗岩为主,岩石呈灰白色,似斑状结构.斑晶主要由微斜长石和斜长石组成,基质则由微斜长石、斜长石、石英、黑云母和普通角闪石组成,副矿物有磁铁矿、锆石、褐帘石、绿帘石、磷灰石、榍石等.白石顶钼矿的矿石矿物主要为辉钼矿、黄铁矿、黄铜矿和白钨矿等.围岩蚀变有黄铁矿化、钾长石化、白云母化、绿泥石化等.文章通过对桂岭岩体及其包体中锆石SHRIMP U-Pb年龄和辉钼矿Re-Os年龄的测定,初步揭示了白石顶钼矿床的成矿年代,桂岭岩体(角闪石)黑云母二长花岗岩锆石SHRIMP UP-b年龄为(424.4±5.6)Ma,其中的闪长质包体的SHRIMP U-Pb年龄为(428±4)Ma.6件辉钼矿Re-Os的加权平均年龄为(424.6±5.7)Ma,这表明白石顶钼矿床形成于志留纪.此次工作首次认为在华南地区志留纪也发生了金属钼的富集成矿,该成果对于深入认识华南地区加里东期的构造.岩浆演化及其成矿作用具有重要的科学价值.
白石頂鉬礦床位于湘粵桂交界的桂北姑婆山地區,主要以石英輝鉬礦脈的形式產于桂嶺巖體(角閃石)黑雲母二長花崗巖和南華繫淺變質淺海相碎屑巖中.桂嶺巖體巖石類型以中-細粒斑狀(角閃石)黑雲母二長花崗巖為主,巖石呈灰白色,似斑狀結構.斑晶主要由微斜長石和斜長石組成,基質則由微斜長石、斜長石、石英、黑雲母和普通角閃石組成,副礦物有磁鐵礦、鋯石、褐簾石、綠簾石、燐灰石、榍石等.白石頂鉬礦的礦石礦物主要為輝鉬礦、黃鐵礦、黃銅礦和白鎢礦等.圍巖蝕變有黃鐵礦化、鉀長石化、白雲母化、綠泥石化等.文章通過對桂嶺巖體及其包體中鋯石SHRIMP U-Pb年齡和輝鉬礦Re-Os年齡的測定,初步揭示瞭白石頂鉬礦床的成礦年代,桂嶺巖體(角閃石)黑雲母二長花崗巖鋯石SHRIMP UP-b年齡為(424.4±5.6)Ma,其中的閃長質包體的SHRIMP U-Pb年齡為(428±4)Ma.6件輝鉬礦Re-Os的加權平均年齡為(424.6±5.7)Ma,這錶明白石頂鉬礦床形成于誌留紀.此次工作首次認為在華南地區誌留紀也髮生瞭金屬鉬的富集成礦,該成果對于深入認識華南地區加裏東期的構造.巖漿縯化及其成礦作用具有重要的科學價值.
백석정목광상위우상월계교계적계북고파산지구,주요이석영휘목광맥적형식산우계령암체(각섬석)흑운모이장화강암화남화계천변질천해상쇄설암중.계령암체암석류형이중-세립반상(각섬석)흑운모이장화강암위주,암석정회백색,사반상결구.반정주요유미사장석화사장석조성,기질칙유미사장석、사장석、석영、흑운모화보통각섬석조성,부광물유자철광、고석、갈렴석、록렴석、린회석、설석등.백석정목광적광석광물주요위휘목광、황철광、황동광화백오광등.위암식변유황철광화、갑장석화、백운모화、록니석화등.문장통과대계령암체급기포체중고석SHRIMP U-Pb년령화휘목광Re-Os년령적측정,초보게시료백석정목광상적성광년대,계령암체(각섬석)흑운모이장화강암고석SHRIMP UP-b년령위(424.4±5.6)Ma,기중적섬장질포체적SHRIMP U-Pb년령위(428±4)Ma.6건휘목광Re-Os적가권평균년령위(424.6±5.7)Ma,저표명백석정목광상형성우지류기.차차공작수차인위재화남지구지류기야발생료금속목적부집성광,해성과대우심입인식화남지구가리동기적구조.암장연화급기성광작용구유중요적과학개치.
The Baishiding molybdenum deposit is located in northern Guangxi, and its ore bodies occur mainly as quartz + molybdenite veins in Guiling biotite monzogranite and epimetamorphic neritic facies clastic rocks in Nan-hua System. Ore minerals are composed of molybdenite, pyrite, chalcopyrite and scheelite. The Mo grade ranges from 0.1% to 0.3 % with an average of 0.12 %. With the distance from the quartz vein, the monzogranite has been altered into K-feldspar, sericite and chlorite in succession. Molybdenite is precipitated in the quartz vein, mostly occurring along the boundary between the monzogranite and the quartz vein or assuming disseminations in monzogranite. Scheelite is also intergrown with molybdenite in the quartz vein. Six molybdenite Re-Os ages from six samples indicate that mineralization took place in Silurian. Zircon SHRIMP U-Pb dating of Guling biotite monzogranite shows that the granite was emplaced at (424.4 ± 5.6) Ma, whereas the zircon from the enclave has an age of (428 ±4) Ma. These data suggest that the Baishiding molybdenum deposit was formed in Silurian, implying that Mo mineralization did occur in Silurian in South China.
