新疆及邻区大地构造编图研究

新疆及邻区大地构造1150万的编图范围为北纬34°～50°，东经72°～98°，面积约370×10     

湘东─赣西NNE向走滑构造

湘东─赣西构造岩浆带位于郯庐断裂南延的关键性部位。中生代以来，该区 NNE向左旋走滑构造主要由会聚走滑和 K─ E离散走滑构造叠加而成。会聚走滑作用造就了 NNE向雁列式剪切断裂系、剪切弯曲和旋转构造、压剪性煤盆地以及断层动热变质─剪切重熔型花岗岩；而离散走滑作用则控制了该区广泛发育的张剪性红盆地、盆岭式构造地貌、以及大规模中低温热液矿床的形成。湘东─赣西复杂的平移构造型式很可能与该区地壳结构分层特征、前期断裂构造格局、平移幅度和多期走滑构造作用四个因素有关。     

柴达木盆地北缘赛什腾-锡铁山左行逆冲断裂及地质意义

本文在对赛什腾-锡铁山斜冲断裂构造重点地段详细构造解析的基础上,结合沉积、地球物理资料对该斜冲断裂构造的几何学、运动学及时代进行了研究,探讨了断裂形成与区域地质背景的关系,提出柴达木盆地北缘的赛什腾、绿梁山、锡铁山是向南斜向逆覆于新第三纪沉积岩之上的无根推覆体,并认为该断裂的形成与喜马拉雅造山带陆内俯冲远程效应相关。      

湖南及邻区志留纪兰多弗里世鲁丹期至埃隆期岩相古地理及加里东期板块构造演化

湖南兰多弗里世鲁丹期岩相古地理格局以桃江—白马山—苗儿山一线为界,其南东为华夏洋壳板块兰多弗里统鲁丹阶周家溪组陆屑浊积深水盆地相,陆屑来自更南东的湘中南褶皱山地;其北西为扬子陆壳板块兰多弗里统鲁丹阶龙马溪组沉积洋盆,南东后缘是上陆棚相,北西前缘是下陆棚相,陆屑都由南东湘中南褶皱山地提供。至兰多弗里世埃隆期岩相古地理发生巨变：龙马溪组顶部Coronograptus cyphus笔石带末即大约440.8±1.2 Ma时,发生华夏洋壳板块向扬子陆壳板块俯冲碰撞事件,华夏洋壳板块周家溪组本身褶皱造山为华夏褶皱山地,华夏洋壳板块洋盆关闭。同时华夏洋壳板块以A型俯冲形式下插到扬子陆壳板块之下,并使扬子陆壳板块南东前缘崛起形成加里东期雪峰造山带。后者将扬子陆壳板块南东前缘牵引、挠曲和凹陷成华夏洋壳板块弧后前陆盆地,小河坝组是该弧后前陆盆地的沉积盖层,陆屑都由南东的雪峰造山带提供。该弧后前陆盆地沉积了三角洲相—滨海相的小河坝组,向北东、北西和南西方向相变为台地相石牛栏组,再向北西陕南紫阳相变为盆地相斑鸠关组。小河坝组两次采集的重砂样均出现蓝闪石,它是蓝闪石片岩标志矿物,蓝闪石片岩是确认加里东期华夏洋壳板块与扬子陆壳板块俯冲碰撞及形成雪峰造山带的判别标志。     

地洼学说的理论结构和发展纲领

地洼学说(活化区理论)自1956年诞生以来,经受过35年的实践检验,已发展成为包括五个组成部分和两个衍生学科的理论体系。它的理论结构是以第一个组成部分,即大陆地壳中发生于地台阶段之后,与地槽区不同特征的一种新型活动区—活化区即地洼区概念为内核,保护层为其余的组成部分和衍生学科,即地壳动定转化递进说、递进(地洼)成矿理论、壳体概念和地幔蠕动热能聚散交替假说,以及构造地球化学和成矿构造学。 地洼学说是属于作者建立的“历史—因果论大地构造学”范畴,它的发展纲领应是运用“历史—动力综合分析法”的研究方法,贯彻理论实践并重和切合生产需要的学术路线,采用充实和加固内核以及调整某些保护层的方式,按照自我完善与学百家之长相结合的原则,研究领域包括学说本身的进一步发展和运用它以解决实际问题。 内核的充实和加固包括两个方面;(1)理论方面的研究,例如地洼区的鉴别依据、类型划分、形成时代、分布地区、地壳运动等方面的问题。(2)实用方面的研究,例如运用区域地质、成矿规律及找矿预测、地热、水文地质、地貌、新构造等方面的问题。     

On Geodynamic Evolution of Simao Region (Southwestern Yunnan, China) during Late Paleozoic and Triassic

ＩＮＴＲＯＤＵＣＴＩＯＮＴｈｅＳｉｍａｏｒｅｇｉｏｎ (ＳＷＹｕｎｎａｎ ,Ｃｈｉｎａ) ,ｓｉｔｕａｔｅｄｂｅ ｔｗｅｅｎｔｈｅＡｉｌａｏｓｈａｎｂｅｌｔｉｎｔｈｅｅａｓｔａｎｄｔｈｅＬａｎｃａｎｇｊｉａｎｇｚｏｎｅｉｎｔｈｅｗｅｓｔ (Ｆｉｇ .1) ,ｉｓａｋｅｙａｒｅａｔｏｃｈｒｏｎｏｌｏｇｉｃａｌｌｙｃｏｎｓｔｒａｉｎｌａｔｅＰａｌｅｏｚｏｉｃｃｏｍｐｒｅｓｓｉｏｎａｌｄｅｆｏｒｍａｔｉｏｎｓａｎｄｔｈｕｓｏｆｐｒｉｍｅｉｎ ｔｅｒｅｓｔｗｈｅｎｄｉｓｃｕｓｓｉｎｇｔｈｅｐｌａｔｅ ｔｅｃｔｏｎｉｃｈｉ…     

计算伸展断层底界面深度的作图法简介

本文简介了计算正断层底界滑脱面深度的3种几何作图法。其中,M.W.Kilsdonk(1989)在Davison(1985)方法基础上作出的修正方法,简便且较准确。运用这种方法计算的鲁西地区深层次滑脱面深度与壳内低速层深度吻合。     

Geologic and tectonic evolution of the Himalaya before and after the India-Asia collision

The geology and tectonics of the Himalaya has been reviewed in the light of new data and recent studies by the author. The data suggest that the Lesser Himalayan Gneissic Basement (LHGB) represents the northern extension of the Bundelkhand craton, Northern Indian shield and the large scale granite magmatism in the LHGB towards the end of the Palæoproterozoic Wangtu Orogeny, stabilized the early crust in this region between 2-1.9 Ga. The region witnessed rapid uplift and development of the Lesser Himalayan rift basin, wherein the cyclic sedimentation continued during the Palæoproterozoic and Mesoproterozoic. The Tethys basin with the Vaikrita rocks at its base is suggested to have developed as a younger rift basin (～ 900 Ma ago) to the north of the Lesser Himalayan basin, floored by the LHGB. The southward shifting of the Lesser Himalayan basin marked by the deposition of Jaunsar-Simla and Blaini-Krol-Tal cycles in a confined basin, the changes in the sedimentation pattern in the Tethys basin during late Precambrian-Cambrian, deformation and the large scale granite activity (～ 500 ± 50 Ma), suggests a strong possibility of late Precambrian-Cambrian Kinnar Kailas Orogeny in the Himalaya. From the records of the oceanic crust of the Neo-Tethys basin, subduction, arc growth and collision, well documented from the Indus-Tsangpo suture zone north of the Tethys basin, it is evident that the Himalayan region has been growing gradually since Proterozoic, with a northward shift of the depocentre induced by N-S directed alternating compression and extension. During the Himalayan collision scenario, the 10–12km thick unconsolidated sedimentary pile of the Tethys basin (TSS), trapped between the subducting continental crust of the Indian plate and the southward thrusting of the oceanic crust of the Neo-Tethys and the arc components of the Indus-Tangpo collision zone, got considerably thickened through large scale folding and intra-formational thrusting, and moved southward as the Kashmir Thrust Sheet along the Panjal Thrust. This brought about early phase (M1) Barrovian type metamorphism of underlying Vaikrita rocks. With the continued northward push of the Indian Plate, the Vaikrita rocks suffered maximum compression, deformation and remobilization, and exhumed rapidly as the Higher Himalayan Crystallines (HHC) during Oligo-Miocene, inducing gravity gliding of its Tethyan sedimentary cover. Further, it is the continental crust of the LHGB that is suggested to have underthrust the Himalaya and southern Tibet, its cover rocks stacked as thrust slices formed the Himalayan mountain and its decollement surface reflected as the Main Himalayan Thrust (MHT), in the INDEPTH profile.     

Petrogenesis of mid-Carboniferous volcanics and granitic intrusions from western Junggar Basin boreholes: geodynamic implications for the Central Asian Orogenic Belt in Northwest China

The western Junggar Basin is located on the southeastern margin of the West Junggar terrane, Northwest China. Its sedimentary fill, magma petrogenesis, tectonic setting, and formation ages are important for understanding the Carboniferous tectonic evolution and continental growth of the Junggar terrane and the Central Asian Orogenic Belt. This paper documents a set of new zircon secondary ion mass spectrometry U–Pb geochronological and Hf isotopic data and whole-rock elemental and Sr–Nd isotopic analytical results for the Carboniferous strata and associated intrusions obtained from boreholes in the western Junggar Basin. The Carboniferous strata comprise basaltic andesite, andesite, and dacite with minor pyroclastic rocks, intruded by granitic intrusions with zircon secondary ion mass spectrometry U–Pb ages of 327–324 Ma. The volcanic rocks are calc-alkaline and show low high ε_Nd(t) values (5.3–5.6) and initial ⁸⁷Sr/⁸⁶Sr (0.703561–0.703931), strong enrichment in LREEs, and some LILEs and depletion in Nb, Ta, and Ti. Furthermore, they also display high (La/Sm)_N (1.36–1.63), Zr/Nb, and La/Yb, variable Ba/La and Ba/Th and constant Th/Yb ratios. These geochemical data, together with low Sm/Yb (1.18–1.38) and La/Sm (2.11–2.53) ratios, suggest that these volcanic rocks were derived from a 5–8% partial melting of a mainly spinel Iherzolite-depleted mantle metasomatized by slab-derived fluids and melts of some sediments in an island-arc setting. In contrast, the granitic intrusions represent typical adakite geochemical features of high Sr and low Y and Yb contents, with no significant Eu anomalies, high Mg#, and depleted ε_Nd(t) (5.6–6.4) and ε_Hf(t) (13.7–16.2) isotopic compositions, suggesting their derivation from partial melting of hot subducted oceanic crust. In combination with the previous work, the West Junggar terrane and adjacent western Junggar Basin are interpreted as a Mariana-type arc system driven by northwestward subduction of the Junggar Ocean, possibly with a tectonic transition from normal to ridge subduction commencing ca. at 331–327 Ma.     

青藏高原南部与东南部重要成矿带的大地构造定格与找矿前景

印度/亚洲汇聚-碰撞过程经历了新特提斯洋盆滋生、消减和俯冲、亚洲南缘增生造山以及印度/亚洲碰撞造山和青藏高原的隆升,在青藏高原南部和东南部造就了"冈底斯火山岩浆带"、"雅鲁藏布江缝合带"、"喜马拉雅碰撞造山带"和大量物质向南东逃逸的"三江侧向挤出地体群",以及相应形成具有重大找矿突破战略前景的"冈底斯成矿带"、"雅鲁藏布江成矿带"、"特提斯喜马拉雅成矿带"和"三江成矿带"。本文通过对四大成矿带的大地构造定格讨论了与资源前景相关的科学问题,提出"冈底斯成矿带"中的岛弧型斑岩铜金矿具有找矿的重大潜力、重视藏东—滇西地区的俯冲-碰撞型岩浆成矿专属性研究;提出扩大西藏罗布莎铬铁矿矿集区的开发规模,以及在西部阿里地区的大型超基性岩体中寻找新的铬铁矿远景地的思路;在三江多阶段成矿作用的叠合型矿床中,集中古特提斯和新特提斯成矿类型,关注与斜向碰撞有关的走滑剪切带对成矿作用的制约机制;需进一步确定特提斯喜马拉雅矿化带与藏南拆离系关系和重视始—中新世高Sr/Y花岗(斑)岩的成矿专属性及找矿前景。