地质通报
地質通報
지질통보
GEOLOGICAL BULLETIN OF CHINA
2014年
11期
1750-1758
,共9页
陈景文%李才%胡培远%解超明%彭虎%江庆源
陳景文%李纔%鬍培遠%解超明%彭虎%江慶源
진경문%리재%호배원%해초명%팽호%강경원
羌塘%龙木错-双湖-澜沧江板块缝合带%花岗闪长岩%LA-ICP-MS锆石U-Pb年龄%地球化学
羌塘%龍木錯-雙湖-瀾滄江闆塊縫閤帶%花崗閃長巖%LA-ICP-MS鋯石U-Pb年齡%地毬化學
강당%룡목착-쌍호-란창강판괴봉합대%화강섬장암%LA-ICP-MS고석U-Pb년령%지구화학
Qiangtang%Lungmu Co-Shuanghu-Lancang River suture zone%granodiorite%LA-ICP-MS zircon U-Pb age%geochemistry
报道了藏北羌塘中部日湾茶卡地区花岗闪长岩体锆石U-Pb年龄和岩石地球化学特征。该花岗闪长岩位于龙木错-双湖-澜沧江板块缝合带西段。岩石样品中的锆石具有较好的晶形,可见典型的岩浆振荡环带结构,具有较高的Th/U值,为典型的岩浆成因锆石。样品锆石LA-ICP-MS技术测得的锆石年龄为211.0Ma±1.8Ma,表明其时代为晚三叠世。全岩地球化学分析表明,该花岗闪长岩具有高SiO2、Al2O3,富碱,低TFe2O3、TiO2的特征,A/CNK值为0.97~1.04,为准铝质-弱过铝质岩石。稀土元素配分模式显示,配分曲线右倾,伴随较弱的Eu负异常;微量元素蛛网图表现出Nb、Ta、Ti、P亏损和Rb、Th、U、K、Pb富集的特征;样品点在构造环境判别图解上均落入碰撞型花岗岩区。初步分析,其岩浆来源可能为幔源岩浆底侵使古老地壳发生熔融。此碰撞型花岗闪长岩对龙木错-双湖-澜沧江洋碰撞的时限提供了一定的岩石学约束,为龙木错-双湖-澜沧江洋的演化提供了基础地质资料。
報道瞭藏北羌塘中部日灣茶卡地區花崗閃長巖體鋯石U-Pb年齡和巖石地毬化學特徵。該花崗閃長巖位于龍木錯-雙湖-瀾滄江闆塊縫閤帶西段。巖石樣品中的鋯石具有較好的晶形,可見典型的巖漿振盪環帶結構,具有較高的Th/U值,為典型的巖漿成因鋯石。樣品鋯石LA-ICP-MS技術測得的鋯石年齡為211.0Ma±1.8Ma,錶明其時代為晚三疊世。全巖地毬化學分析錶明,該花崗閃長巖具有高SiO2、Al2O3,富堿,低TFe2O3、TiO2的特徵,A/CNK值為0.97~1.04,為準鋁質-弱過鋁質巖石。稀土元素配分模式顯示,配分麯線右傾,伴隨較弱的Eu負異常;微量元素蛛網圖錶現齣Nb、Ta、Ti、P虧損和Rb、Th、U、K、Pb富集的特徵;樣品點在構造環境判彆圖解上均落入踫撞型花崗巖區。初步分析,其巖漿來源可能為幔源巖漿底侵使古老地殼髮生鎔融。此踫撞型花崗閃長巖對龍木錯-雙湖-瀾滄江洋踫撞的時限提供瞭一定的巖石學約束,為龍木錯-雙湖-瀾滄江洋的縯化提供瞭基礎地質資料。
보도료장북강당중부일만다잡지구화강섬장암체고석U-Pb년령화암석지구화학특정。해화강섬장암위우룡목착-쌍호-란창강판괴봉합대서단。암석양품중적고석구유교호적정형,가견전형적암장진탕배대결구,구유교고적Th/U치,위전형적암장성인고석。양품고석LA-ICP-MS기술측득적고석년령위211.0Ma±1.8Ma,표명기시대위만삼첩세。전암지구화학분석표명,해화강섬장암구유고SiO2、Al2O3,부감,저TFe2O3、TiO2적특정,A/CNK치위0.97~1.04,위준려질-약과려질암석。희토원소배분모식현시,배분곡선우경,반수교약적Eu부이상;미량원소주망도표현출Nb、Ta、Ti、P우손화Rb、Th、U、K、Pb부집적특정;양품점재구조배경판별도해상균락입팽당형화강암구。초보분석,기암장래원가능위만원암장저침사고로지각발생용융。차팽당형화강섬장암대룡목착-쌍호-란창강양팽당적시한제공료일정적암석학약속,위룡목착-쌍호-란창강양적연화제공료기출지질자료。
This paper reports new zircon U-Pb age and whole-rock major and trace element data of the granodiorite body in the Riwanchaka area, central Qiangtang, northern Tibetan Plateau. The granodiorite lies in the western part of the Lungmu Co-Shuanghu-Lancang River suture zone. Its zircons show no euhedral crystals and have clear oscillatory zones as well as high Th/U ratios, suggesting a magmatic origin. Zircon LA-ICP-MS dating of the granodiorite yielded a weighted mean age of 211.0Ma ± 1.8Ma, implying that the crystallization of the granodiorite body took place in late Triassic. Petrological and geochemical studies show that it is characterized by high silicon and aluminum, abundant alkali, low TFe2O3 and TiO2, with A/CNK being 0.97-1.04. Hence the granodiorite body belongs to aluminous-peraluminous series. The REE model is characterized by enrichment of light REE with negative Eu anomaly. In addition, it is enriched in Rb, Th, U, K, Pb with negative anomalies of Nb, Ta, Ti, P. These features suggest that the granodiorite has the characteristics of collision volcanics. A preliminary analysis shows that it was probably generated from partial melting of ancient crust through underplating of the mantle-derived magma. The collision-type granodiorite provides important petrologic constraints for the Lungmu Co-Shuanghu-Lancang River Ocean and the data for the study of the evolution of the Lungmu Co-Shuanghu-Lancang River Ocean.
