共查询到18条相似文献,搜索用时 140 毫秒
1.
扎河坝坳陷位于阿尔泰造山带与准噶尔盆地之间,属于中亚造山带的一部分,自早古生代以来经历了准噶尔洋盆的打开和闭合等阶段,富含煤炭和金属矿产,也具有一定的油气勘探前景。研究区火山岩和含煤层系发育,地表风化剥蚀严重,对研究其地层发育特征和沉积环境起到了一定的制约。对扎河坝坳陷新富地1井岩芯样品开展沉积岩微量元素测试,分析结果表明,扎河坝坳陷上二叠统为温暖湿润的淡水沉积环境,表明扎河坝坳陷晚二叠世经历了火山活动和陆相淡水沉积2个阶段,印证了准噶尔洋由俯冲消减向陆内阶段转换的过程。该研究对恢复研究区构造演化及沉积古地理特征具有重要意义。 相似文献
2.
绥滨坳陷是三江盆地的次一级构造单元,位于三江盆地的西部。军川断裂是绥滨坳陷的主要控盆断裂,控制了其形成和演化。坳陷的主体是西断东超的箕状断陷,具有发育时间长、沉积厚度大、保存好、面积大等特征,有利于油气的生成;坳陷经历了造山后裂陷阶段、断陷阶段、挤压回返阶段、走滑拉分四个演化阶段,强烈的隆升和剥蚀对油气的储集有不利的影响。 相似文献
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通过大量地质、地球物理和地球化学资料论证,笔者认为准噶尔盆地西北前陆坳陷与西准噶尔造山带之间在成因上具有耦合关系,即准噶尔盆地西北前陆拗陷的形成、演化与西准噶尔造山带的上隆、推覆之间存在内在成因联系。准噶尔西北地区的基底为早中古生代洋壳物质,准噶尔盆地西北地区的中泥盆世为残余洋盆,晚泥盆世一晚石炭世为弧前残余洋盆,二叠纪为前陆盆地。根据准噶尔盆地西北地区的前陆坳陷与西准噶尔造山带在盆—山转换过程中地质流体的地球化学特征,认为现克拉玛依油区油气的形成演化与盆—山转换过程中各种地质作用,特别是地质流体的作用具有成因相关性。 相似文献
4.
从古元古代至晚古生代,华北地台西缘经历了坳拉槽、槽后坳和坳陷发育阶段。笔者在大区域地层对比及详细的沉积环境分析基础上,对晚古生代海水进退与聚煤作用关系作了较深入研究。结果表明:晚石炭世晚期至早二叠世早期华北地台西缘主要为潮坪和三角洲沉积发育区,在空间上沉积环境具有东西有别南北分带的特点;西部由泻湖潮坪沉积环境逐渐过渡为河控泻湖三角洲和受潮汐影响的河控滨海三角洲沉积环境;东部为潮坪沉积环境,东侧边缘还出现近山滨海平原沉积环境。研究区在晚石炭世早期-早二叠世早期发生过4次2级海水进退,其中第三、第四次海侵全区发育。早二叠世早期初的第三次2级海侵是最大的一次。最大海侵前夕晚石炭世晚期末是大区域发育厚-巨厚煤层的最好时期。泻湖三角洲平原和陆源碎屑潮上泥炭坪及泥炭沼泽是最佳的聚煤场所。 相似文献
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从古元古代至晚古生代,华北地台西缘经历了坳拉槽、槽后坳和坳陷发育阶段.笔者在大区域地层对比及详细的沉积环境分析基础上,对晚古生代海水进退与聚煤作用关系作了较深入研究.结果表明:晚石炭世晚期至早二叠世早期华北地台西缘主要为潮坪和三角洲沉积发育区,在空间上沉积环境具有东西有别南北分带的特点;西部由潟湖潮坪沉积环境逐渐过渡为河控潟湖三角洲和受潮汐影响的河控滨海三角洲沉积环境;东部为潮坪沉积环境,东侧边缘还出现近山滨海平原沉积环境.研究区在晚石炭世早期一早二叠世早期发生过4次2级海水进退,其中第三、第四次海侵全区发育.早二叠世早期初的第三次2级海侵是最大的一次.最大海侵前夕——晚石炭世晚期末是大区域发育厚—巨厚煤层的最好时期.潟湖三角洲平原和陆源碎屑潮上泥炭坪及泥炭沼泽是最佳的聚煤场所. 相似文献
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准噶尔盆地南缘(简称“准南”)的构造-沉积演化历史以及原型盆地性质一直以来备受争议。依据沉积环境分析、地层对比以及沉积演化研究,结合火成岩年代学、大地构造学等研究成果,探讨了该区二叠纪—三叠纪多期次的伸展—挤压环境转换及沉积盆地性质转变。晚石炭世,准南西段处于北天山洋壳向伊犁地体俯冲的末期,沉积环境以滨浅海为主,为残留洋盆地;准南东段以半深海相碳酸盐沉积为主,发育典型的双峰式火成岩,显示为陆内的伸展环境。早二叠世,准南以滨浅海相细粒碎屑岩沉积为主,发育同沉积断裂和伸展垮塌变形构造,表现为陆内裂陷盆地的特征。中二叠世,准南仍以滨浅海相为主,但其沉积速率明显加快,沉积厚度变大,整体上表现为以热力沉降为主的坳陷盆地。晚二叠世,北天山和博格达地区普遍发育冲积扇或扇三角洲,上二叠统泉子街组和中二叠统红雁池组之间呈明显的角度不整合接触,沉积环境发生突变,均显示北天山快速冲断隆升,表明该时期准南为陆内压陷盆地。早三叠世,准南快速冲断结束,该区进入相对稳定的发展阶段,以发育滨浅湖相细粒沉积物为主,表现为弱挤压的陆内压陷盆地的特征。中晚三叠世,由于持续湖侵,沉积盆地范围进一步扩大,北天山被削高补低,准南乃至整个准噶尔盆地进入统一的内陆湖泊演化阶段,整体上以滨浅湖相—半深湖相沉积为主,表现出陆内坳陷盆地的特征。综合上述原型盆地性质和沉积环境分析,可将准南二叠纪—三叠纪构造-沉积演化划分为4个阶段:晚石炭世—中二叠世为后碰撞伸展阶段,晚二叠世为北天山挤压冲断阶段,早三叠世为弱挤压压陷和削高补低阶段,中晚三叠世为稳定拗陷和准平原化阶段。 相似文献
7.
库车坳陷古近系库姆格列木群底砂岩段沉积可划分为北缘砂砾岩带冲积扇粗碎屑沉积-下切辫状水道充填-河流-三角洲沉积、温宿凸起边缘近端冲积扇-扇三角洲沉积和塔北凸起西南缘的下切谷充填-河流三角洲-滨浅湖滩坝3个相带,中部为干旱盐湖-泻湖-海湾沉积.物源体系分析表明,西部的温宿凸起、北边的南天山造山带和塔北隆起上的大陆蚀源区为坳陷提供物源.库车坳陷碎屑物基本上来自于南天山和温宿凸起再循环造山带,坳陷北缘的逆冲造山和隆升作用形成了长期的物源供给区,沿坳陷东北缘发育了巨厚的冲积扇.西部的温宿凸起早期存在物源,沿凸起边缘发育有小型的边缘扇或扇-辫状河三角洲.塔北隆起在古近纪早期提供一定的物源,克拉201井附近结晶基底的剥蚀是南部大陆蚀源区的主要物质来源.却勒1井、羊塔5井等地的碎屑物极可能来自3个物源区.研究区物源体系的分析与总体的古构造、古地理格局相一致,库车坳陷古近系基底东高西低,有大量陆源碎屑由东向西推进,东、西两侧的低凸起带和北缘的前陆前渊带构成的古构造特征决定着物源和岩相分布的总体格局. 相似文献
8.
准噶尔盆地南缘二叠—三叠纪原型盆地性质与沉积环境演化 总被引:1,自引:0,他引:1
准噶尔盆地南缘(简称"准南")二叠—三叠纪原型盆地性质与沉积环境演化一直以来备受争议。通过准南6个地层小区18条典型剖面野外实测、岩相和沉积环境分析以及区域地层对比,认为准南西部(88°E以西)和准南东部(88°E以东)二叠—三叠纪在岩石组合、地层序列、沉积特征和沉积环境等方面存在差异:准南西部以碎屑岩、火山岩和火山碎屑岩组合为特征;准南东部以碳酸盐岩、火山岩和碎屑岩组合为特征。准南西部早—中二叠世地层普遍缺失或被埋藏,晚二叠世—早三叠世为陆相冲积扇—扇三角洲的粗碎屑岩沉积,中—晚三叠世发育滨浅湖相细碎屑岩。准南东部晚石炭世发育深水浊流,早—中二叠世以滨浅海相细碎屑岩为主,中二叠世后期以芦草沟组潟湖相油页岩和碳酸盐岩发育为特征;晚二叠世,普遍进入河湖相演化阶段,以细至粗碎屑岩为主;中—晚三叠世发生湖泛,主要发育三角洲和滨浅湖相碎屑岩。研究表明,准南及邻区二叠—三叠纪为裂谷盆地,经历了断陷—坳陷沉积演化阶段,准南西部和东部伸展程度的差异性导致沉积特征的不同。 相似文献
9.
库车坳陷沉降与天山中新生代构造活动 总被引:13,自引:0,他引:13
位于塔里木盆地北缘、天山南侧的库车坳陷为中新生代发育的构造单元。坳陷与天山造山带在成因上紧密相连,坳陷的沉降是由于天山山体隆升扩展引起的岩石圈挠曲响应。根据纵横向不同位置盆地沉降史的分析对比,该坳陷为典型的挤压盆地。推测中生代时期天山造山带以走滑和逆冲作用为主,新生代时期至少在库车坳陷北缘,天山造山带以向南冲断作用为主。库车坳陷强烈沉降时期并不对应于粗碎屑沉积,而对应于细碎屑沉积时期,即天山造山带构造强烈活动时期。天山造山带强烈活动造成库车坳陷强烈沉降,其主要原因与塔里木板块南侧的羌塘地体、拉萨地体、科西斯坦杂岩和印度次大陆的增生碰撞有关。 相似文献
10.
以北黄海盆地东部坳陷北部侏罗系为目的层,探讨侏罗纪北部物源-沉积体系的岩矿特征、物源区构造背景和物源方向。研究区侏罗系是一套陆相碎屑岩沉积,主要岩石类型为岩屑石英砂岩和岩屑砂岩。通过对北黄海盆地东部坳陷侏罗系沉积序列的研究,识别出三角洲、扇三角洲和湖泊等3类沉积环境。根据碎屑组分和灰岩丰度可知,北部物源-沉积体系为风化物源,并存在附加的火山物源,物源区为再旋回造山带,沉积体系为自北向南方向的扇三角洲沉积体系。对岩石样品进行微观特征及粒度特征研究,识别出沉积微相类型有扇三角洲前缘亚相的远砂坝、河口坝、水下河道和重力水下河道4种微相。 相似文献
11.
造山带地区构造运动复杂、沉积体系多变,其层序地层划分往往被视为禁区.准噶尔盆地西北缘乌夏前陆冲断带早二叠世发育了一套由火山-火山碎屑岩和正常碎屑岩互层的沉积组合,中晚二叠世主要发育了冲积扇相、扇三角洲相和湖泊相沉积,给层序地层学的研究带来很大难题.对前陆冲断带层序地层划分不能套用稳定地区的模式.本文通过地震、钻测井资料识别各类不整合面,并依据火山喷发方式、火山旋回、沉积旋回分析技术,在经典层序地层学基础上按照不同对比原则,进行层序界面的识别和划分,建立了研究区前陆冲断带地区的层序时空演化模式.结果表明:研究区二叠系层序发育经历了强烈俯冲碰撞造山期-饥饿深水阶段、弱冲断夹短暂伸展火山期-复理石阶段、强烈冲断复活期-磨拉石阶段和冲断活动鼎盛期-水下粗粒沉积阶段(PSS4发育期). 相似文献
12.
准噶尔盆地南缘侏罗纪沉积相演化与盆地格局 总被引:28,自引:4,他引:24
通过对准噶尔盆地南缘侏罗系5条剖面的沉积特征对比,结合钻井资料和地震资料,确定了准噶尔盆地南缘侏罗纪盆地边界、沉积相演化及盆地格局。头屯河剖面和后峡剖面的沉积相对比及古流向测量表明二者在早、中侏罗世形成于同一沉积体系。在早、中侏罗世,沉积相逐渐从以辫状河-三角洲-湖泊相为主过渡到以河流相-湖泊相为主,沉积水体逐渐变浅;其中三工河组沉积时期盆地沉积范围达到最大,西山窑组沼泽相发育,车排子-莫索湾凸起自西山窑组沉积时期开始形成;早、中侏罗世的盆地边界至少位于后峡以南附近,此时不存在地理分割明显的天山山脉。晚侏罗世-早白垩世早期,沉积相从辫状河-滨浅湖相为主迅速演变为以辫状河-冲积扇相为主。在此期间盆地边界明显向北迁移,天山山脉明显隆升并造就天山南北沉积环境的巨大差异,博格达山构成盆地南缘的又一重要物源体系。 相似文献
13.
为探讨准噶尔盆地南缘二叠纪-三叠纪盆地构造性质及构造演化过程,笔者对盆地南缘小渠子背斜保存较完整的T/P 不整合进行了几何学、运动学和沉积韵律旋回特征的分析。T/P 不整合具有同构造不整合的特点,表现为不整合之下削蚀、之上超覆,是由于盆地南缘经历晚二叠世-早三叠世区域性挤压作用造成的。通过对小渠子地区深层地质结构的分析,认为晚二叠世-早三叠世的构造演化过程与早石炭世伸展断陷的反转密切相关。 相似文献
14.
根据大地构造环境与沉积组合(建造)类型,地层序列与地层接触关系,古地理格局与古环境条件,古生物类型与生物古地理区系,地层类型与地层的变形、变质和变位特征,地层区划的边界类型与识别标志,地层区划可以区分为综合和断代地层区划2类,都可以分为4级:地层大区(stratomegaregion)、地层区(stratoregion)、地层分区(stratosubregion)和地层小区(stratomicroregion).基于近年来取得的大量新资料、新认识和上述地层区划6方面的判据,西准噶尔地区古生代地层区划自北向南划分为萨吾尔山地层小区、沙尔布尔提山地层小区、玛依力山地层小区和克拉玛依地层小区.在构造古地理上,西准噶尔地区古生代表现为多岛洋和软碰撞的特点,志留纪后期至早石炭世是多岛洋和软碰撞的鼎盛时期,也是西准噶尔地区古生代地层区划的重要形成时期;晚石炭世至二叠纪,西准噶尔地区主体脱离海洋环境,进入陆内造山阶段,西准噶尔地区古生代地层的分区性逐渐消失.在生物古地理上,早古生代西准噶尔地区属于介于太平洋生物大区与大西洋生物大区之间的混生生物大区,不同于东北部西伯利亚板块南部由Tuvaella(图瓦贝)动物群所代表的生物区系;从志留纪至泥盆纪,西准噶尔地区的生物组合面貌明显属于热带-亚热带的古特提斯生物大区;晚石炭世-二叠纪西准噶尔地区陆相地层中的植物群面貌显示出明显的北温带安加拉植物群的特点.在沉积古地理上,西准噶尔地区古生代的作用相包括正常沉积与事件沉积,特别是反映活动构造环境的内力事件沉积特别发育,如火山爆发相、火山溢流相和震积岩相;环境相包括古陆、河流相、滨-浅海相和半深海-深海相. 相似文献
15.
The modern Tianshan Mountains and their surrounding basins have mainly been shaped by the far field effects of the Cenozoic India-Asia collision. However, precollision topographic evolution of the Tianshan Mountains and its impacts on the Junggar and Turpan Basins remain unclear due to the scarcity of data. Detrital zircon U-Pb dating of 14 new and 23 published samples from Permian to Neogene strata in the northern Western Tianshan Mountains, northern and southern Bogda Mountains and Central Turpan Basin, are combined with sedimentary characteristics (lithofacies, petrofacies and paleocurrent data) to investigate the temporal and spatial changes in sediment provenances. Based on the age characteristics of the source rocks in the Tianshan Mountains, the detrital zircons are divided into three groups: pre-Carboniferous zircons, mainly from the Central Tianshan Mountains; Carboniferous to Permian zircons, mainly from the North Tianshan and Bogda Mountains; and Mesozoic zircons, mainly from syn-depositional volcanic activity. The topographic evolution of the Tianshan Mountains and their relation to the Junggar and Turpan Basins can be generally divided into six stages. (1) Positive-relief Tianshan and Bogda Mountains and a rifted marine basin formed during the Early Permian to early Middle Permian following late Carboniferous orogenesis, as evidenced by interbedded alluvial fan conglomerates and postcollisional extension-related volcanic rocks along the basin margins, by marine deposits far from the basin margins and by the predominance of Carboniferous to Permian detrital zircons. (2) Fluvial to lacustrine deposits in the modern southern Junggar and Turpan Basins are characterized by abundant pre-Carboniferous zircons and consistently northward-flowing paleocurrents, indicating the submergence of the Bogda Mountains and a contiguous Junggar-Turpan continental depression basin during the late Middle Permian to the Triassic. (3) The Bogda Mountains began to uplift in the Early Jurassic, resulting in opposing paleocurrent directions, a sudden increase in sedimentary lithic detritus and the dominance of Carboniferous to Permian detrital zircons along the southern and northern margins of this range. (4) In contrast to the uplift of the Bogda Mountains, the other parts of the Tianshan Mountains experienced gradual peneplanation from the Early Jurassic to the Middle Jurassic, as confirmed by widespread fluvial to lacustrine deposits, even inside the modern Tianshan Mountains, and by the dominance of pre-Carboniferous detrital zircons. (5) The dominance of Carboniferous to Permian zircons in the southern Junggar Basin suggests the West Tianshan Mountains were uplifted during the Late Jurassic, while the dominance of pre-Carboniferous zircons in the Central Turpan Basin indicates continuous peneplanation in the Eastern Tianshan Mountains. (6) The initial shape of the Tianshan Mountains-Junggar Basin-Turpan Basin system was constructed in the Late Jurassic but was modified in the Cenozoic by the India-Asia collision, resulting in much higher Western Tianshan and Bogda Mountains, low Eastern Tianshan Mountains and well-developed foreland basins. These Cenozoic changes were recorded by the rapid cooling of apatites, the dominance of Carboniferous to Permian zircons in the southern Junggar Basin and northern Turpan Basin, and the dominance of pre-Carboniferous zircons in the Central Turpan Basin. 相似文献
16.
乌伦古坳陷位于准噶尔盆地东北部、阿尔泰山南缘,由北西-南东走向的红岩断阶带、索索泉凹陷和南部斜坡带组成。坳陷内上三叠统直接覆盖在石炭系基底之上,上三叠统和侏罗系发育生长地层,白垩系向红岩断阶带方向超覆沉积在侏罗系顶削蚀不整合面之上,古近系、新近系和第四系较稳定地沉积在白垩系顶小角度不整合面之上。索索泉凹陷中生界底面最深,往南部斜坡带逐渐抬高。红岩断阶带中生界被抬升剥蚀,古生界之上直接覆盖新生界。根据生长地层、不整合面、卷入变形的地层时代判断:早-中三叠世乌伦古坳陷延续了二叠纪的隆升剥蚀格局,地层缺失;晚三叠世-侏罗纪陆梁隆起隆升,在坳陷内沉积生长地层,局部发育逆冲断层;白垩纪为红岩断阶带主形成期,白垩系朝着红岩断阶带超覆沉积于侏罗系之上;古近纪构造变形微弱,沉积较为稳定;新近纪-第四纪发育挤压构造和正断层。乌伦古坳陷中生代受阿尔泰陆内造山作用制约,属于阿尔泰中生代陆内前陆盆地系统的一部分:楔顶带从阿尔泰山不断往南扩展,到白垩纪扩展到乌伦古坳陷红岩断阶带;前隆带位于陆梁隆起,并于晚三叠世-侏罗纪挠曲隆升。古近纪造山作用减弱,乌伦古坳陷区域沉降,地层较稳定沉积。新近纪-第四纪受印度-欧亚板块碰撞作用的远程效应影响,北天山发生陆内造山作用,乌伦古坳陷远离北天山,挤压构造变形相对较弱。新近纪-第四纪正断层为造山间歇期形成的区域性伸展构造,代表了中亚地区晚新生代脉动式冲断作用的一个间歇期。 相似文献
17.
准噶尔盆地二叠纪盆地属性的再认识及其构造意义 总被引:10,自引:0,他引:10
准噶尔盆地及其邻区野外剖面、钻井剖面的系统对比和地震剖面的精细解释表明,二叠系沉积演化、断裂控制沉积、箕状断-超反射特征及大地构造背景均显示,二叠纪准噶尔盆地是形成于张性背景下的断陷-裂陷盆地。准噶尔盆地及邻区火山岩地化特征、年代学数据及区域构造研究成果也证明,二叠纪是张性的大地构造背景。早二叠世—中二叠世早期以发育冲积扇沉积为特征,各构造部位的沉积环境差异较大,强烈断陷并逐渐形成坳隆相间的沉积格局,为断陷盆地的裂陷期;中二叠统中晚期由早二叠世隆坳分割的局面逐渐转化为统一的大型内陆湖盆,吐哈盆地与准噶尔盆地水体相通,形成统一的沉积体系,为断陷盆地扩张期;晚二叠世时期以出现冲积-河流相红色粗碎屑沉积为特征,准噶尔盆地和吐哈盆地分割自成沉积体系,是断陷盆地的萎缩期。因此,中生代盆地演化是建立在二叠纪张性背景的基础之上,二叠纪断陷-裂陷盆地的提出对重新认识中生代盆地演化历程将具有重要启示意义,也将对今后的油气勘探具有重要指导意义,值得进一步研究。 相似文献
18.
Jia-Fu Chen Bao-Fu Han Jian-Qing Ji Lei Zhang Zhao Xu Guo-Qi He Tao Wang 《Lithos》2010,115(1-4):137-152
North Xinjiang, Northwest China, is made up of several Paleozoic orogens. From north to south these are the Chinese Altai, Junggar, and Tian Shan. It is characterized by widespread development of Late Carboniferous–Permian granitoids, which are commonly accepted as the products of post-collisional magmatism. Except for the Chinese Altai, East Junggar, and Tian Shan, little is known about the Devonian and older granitoids in the West Junggar, leading to an incomplete understanding of its Paleozoic tectonic history. New SHRIMP and LA-ICP-MS zircon U–Pb ages were determined for seventeen plutons in northern West Junggar and these ages confirm the presence of Late Silurian–Early Devonian plutons in the West Junggar. New age data, combined with those available from the literature, help us distinguish three groups of plutons in northern West Junggar. The first is represented by Late Silurian–Early Devonian (ca. 422 to 405 Ma) plutons in the EW-striking Xiemisitai and Saier Mountains, including A-type granite with aegirine–augite and arfvedsonite, and associated diorite, K-feldspar granite, and subvolcanic rocks. The second is composed of the Early Carboniferous (ca. 346 to 321 Ma) granodiorite, diorite, and monzonitic and K-feldspar granites, which mainly occur in the EW-extending Tarbgatay and Saur (also spelled as Sawuer in Chinese) Mountains. The third is mainly characterized by the latest Late Carboniferous–Middle Permian (ca. 304 to 263 Ma) granitoids in the Wuerkashier, Tarbgatay, and Saur Mountains.As a whole, the three epochs of plutons in northern West Junggar have different implications for tectonic evolution. The volcano-sedimentary strata in the Xiemisitai and Saier Mountains may not be Middle and Late Devonian as suggested previously because they are crosscut by the Late Silurian–Early Devonian plutons. Therefore, they are probably the eastern extension of the Early Paleozoic Boshchekul–Chingiz volcanic arc of East Kazakhstan in China. It is uncertain at present if these plutons might have been generated in either a subduction or post-collisional setting. The early Carboniferous plutons in the Tarbgatay and Saur Mountains may be part of the Late Paleozoic Zharma–Saur volcanic arc of the Kazakhstan block. They occur along the active margin of the Kazakhstan block, and their generation may be related to southward subduction of the Irtysh–Zaysan Ocean between Kazakhstan in the south and Altai in the north. The latest Late Carboniferous–Middle Permian plutons occur in the Zharma–Saur volcanic arc, Hebukesaier Depression, and the West Junggar accretionary complexes and significantly postdate the closure of the Irtysh–Zaysan Ocean in the Late Carboniferous because they are concurrent with the stitching plutons crosscutting the Irtysh–Zaysan suture zone. Hence the latest Late Carboniferous–Middle Permian plutons were generated in a post-collisional setting. The oldest stitching plutons in the Irtysh–Zaysan suture zone are coeval with those in northern West Junggar, together they place an upper age bound for the final amalgamation of the Altai and Kazakhstan blocks to be earlier than 307 Ma (before the Kaslmovian stage, Late Carboniferous). This is nearly coincident with widespread post-collisional granitoid plutons in North Xinjiang. 相似文献