地球学报
地毬學報
지구학보
ACTA GEOSCIENTIA SINICA
2013年
1期
75-86
,共12页
钟康惠%姚丹%多吉%郑凡石%徐长昊%黄小雨%陆彪%雷波%蔺吉庆%鲍春辉%闫国强
鐘康惠%姚丹%多吉%鄭凡石%徐長昊%黃小雨%陸彪%雷波%藺吉慶%鮑春輝%閆國彊
종강혜%요단%다길%정범석%서장호%황소우%륙표%뢰파%린길경%포춘휘%염국강
西藏甲玛—驱龙地区%叶巴岩组%构造变形%构造运动学%构造动力学
西藏甲瑪—驅龍地區%葉巴巖組%構造變形%構造運動學%構造動力學
서장갑마—구룡지구%협파암조%구조변형%구조운동학%구조동역학
Jiama(Gyama)-Qulong area in Tibet%Yeba tectonite group%deformation%kinematics%dynamics
通过野外地质调查和定向薄片显微构造研究,对甲玛—驱龙地区叶巴岩组的变形、运动学和动力学进行了初步研究,指出:①原叶巴组实为构造岩,应称“叶巴岩组”,区内可分为四个岩段,构成两个变火山-沉积旋回;②叶巴岩组在宏观上表现为自北而南的轴面总体北倾的复背斜和复向斜;③叶巴岩组经历过两期韧性变形,多期韧脆性变形,且邻甲玛—卡军果推-滑覆构造系主推覆面的 C 岩段还多经历了三期较浅层次的面理置换和一期膝折变形;④叶巴岩组两期韧性变形动向相反,第一期为上层面自南向北的剪切,第二期为上层面自北向南的剪切,第二期韧性剪切与随后的韧脆性变形具多阶段递进特点,在向南推覆褶皱至较浅层次后还经历多期脆-韧性变形,尤其是邻甲玛—卡军果推-滑覆构造系主推覆面部位;⑤叶巴岩组第一期韧性变形发生于94—85 Ma±的晚白垩世土伦期—康尼亚克期,与雅鲁藏布江洋壳向北俯冲导致的弧后裂谷伸展有关;第二期韧性变形及其后主要的韧脆性变形发生于50 Ma±的始新世,与印度-欧亚板块碰撞事件有关,碰撞后的构造作用则导致多期脆-韧性变形的叠加.
通過野外地質調查和定嚮薄片顯微構造研究,對甲瑪—驅龍地區葉巴巖組的變形、運動學和動力學進行瞭初步研究,指齣:①原葉巴組實為構造巖,應稱“葉巴巖組”,區內可分為四箇巖段,構成兩箇變火山-沉積鏇迴;②葉巴巖組在宏觀上錶現為自北而南的軸麵總體北傾的複揹斜和複嚮斜;③葉巴巖組經歷過兩期韌性變形,多期韌脆性變形,且鄰甲瑪—卡軍果推-滑覆構造繫主推覆麵的 C 巖段還多經歷瞭三期較淺層次的麵理置換和一期膝摺變形;④葉巴巖組兩期韌性變形動嚮相反,第一期為上層麵自南嚮北的剪切,第二期為上層麵自北嚮南的剪切,第二期韌性剪切與隨後的韌脆性變形具多階段遞進特點,在嚮南推覆褶皺至較淺層次後還經歷多期脆-韌性變形,尤其是鄰甲瑪—卡軍果推-滑覆構造繫主推覆麵部位;⑤葉巴巖組第一期韌性變形髮生于94—85 Ma±的晚白堊世土倫期—康尼亞剋期,與雅魯藏佈江洋殼嚮北俯遲導緻的弧後裂穀伸展有關;第二期韌性變形及其後主要的韌脆性變形髮生于50 Ma±的始新世,與印度-歐亞闆塊踫撞事件有關,踫撞後的構造作用則導緻多期脆-韌性變形的疊加.
통과야외지질조사화정향박편현미구조연구,대갑마—구룡지구협파암조적변형、운동학화동역학진행료초보연구,지출:①원협파조실위구조암,응칭“협파암조”,구내가분위사개암단,구성량개변화산-침적선회;②협파암조재굉관상표현위자북이남적축면총체북경적복배사화복향사;③협파암조경력과량기인성변형,다기인취성변형,차린갑마—잡군과추-활복구조계주추복면적 C 암단환다경력료삼기교천층차적면리치환화일기슬절변형;④협파암조량기인성변형동향상반,제일기위상층면자남향북적전절,제이기위상층면자북향남적전절,제이기인성전절여수후적인취성변형구다계단체진특점,재향남추복습추지교천층차후환경력다기취-인성변형,우기시린갑마—잡군과추-활복구조계주추복면부위;⑤협파암조제일기인성변형발생우94—85 Ma±적만백성세토륜기—강니아극기,여아로장포강양각향북부충도치적호후렬곡신전유관;제이기인성변형급기후주요적인취성변형발생우50 Ma±적시신세,여인도-구아판괴팽당사건유관,팽당후적구조작용칙도치다기취-인성변형적첩가.
Based on field geological survey and oriented thin section observation, the authors studied deformation, kinematics and dynamics of the Yeba tectonite group, and reached the following conclusions: ① the previously named “Yeba group” is actually a tectonite group and should be called “Yeba tectonite group”, which consists of four lithologic sections and can be divided into two volcano-sedimentary cycles; ② macroscopically, from north to south, Yeba tectonite group shows an inclined anticlinorium and an inclined synclinorium whose axis trends northward; ③ Yeba tectonite group experienced two-stages of ductile deformation and multi-stage brittle-ductile deformation, and the C lithologic section experienced three-stages of foliation replacement and one stage of kink deformation at the superficial level, lying near the main napping plane of Jiama(Gyama)-Kajunguo thrust - gliding nappe tectonic system; ④ in Yeba tectonite group, kinematic direction of two-stages of ductile deformation is on the opposite: in the first stage, the upper layer shearing was from south to the north; in the second stage, the upper layer shearing was from north to south. The second ductile deformation and later multi-stage ductile-brittle deformation had multi-stage progressive deformation characteristics, and after southward nappe-fold lifting to the superficial level, Yeba tectonite group also experienced multi-stage brittle-ductile deformation, especially at the position near the main napping plane of Jiama(Gyama)-Kajunguo thrust-gliding nappe tectonic system; ⑤ the first stage ductile deformation of Yeba tectonite group occurred around 94–85 Ma, belonging to Late Cretaceous Turonian-Coniacian period and related to back-arc rift stretching that resulted from northward subduction of the Brahmaputra oceanic crust; the second stage ductile deformation and the later main brittle-ductile deformation occurred around 50 Ma in Eocene, related to Indo-Asia collision, and the post collision tectonism resulted in the superposition of multi-stage brittle-ductile deformation.