Fault system, deep structure and tectonic evolution of the Qilian Orogenic Belt, Northwest China
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摘要:
祁连造山带处在特提斯构造域的北缘,经历了早古生代原特提斯洋发育以来的构造演化,是青藏高原东北缘高原隆升与扩展的关键构造带。本文依据区域地质调查与构造地质填图,结合前人地球物理场资料,阐述了中国西北和祁连造山带断裂构造体系特征。通过超宽频大地电磁测深(MT)剖面数据采集处理,以及浅、中-深层电性剖面反演与构造解释,分析了祁连造山带全地壳深部结构特征与盆山耦合关系,揭示了原特提斯洋构造域北祁连洋板块向南和向北进行双向俯冲的化石俯冲带深部结构特征;俯冲消减的北祁连洋板块的宽度约在600 km以上。其中,北祁连洋向南在柴达木-祁连地块之下的俯冲作用角度较缓,俯冲带向南延伸的距离较远,其俯冲断离的板片可以达到现今柴达木盆地的北缘;北祁连洋向北的俯冲作用产状较陡,其俯冲断离的板片具有向南陡倾的产状倒转特征,可能与中生代以来、特别是印度-亚洲大陆碰撞的远程效应引起的挤压构造变形有关。大地电磁测深剖面的浅层反演与构造解释,验证了祁连山北缘断裂以北发育的榆木山逆冲推覆构造,榆木山构成飞来峰构造,将早白垩世酒泉盆地的一个分支掩盖在外来的逆冲推覆体之下;飞来峰之下具有油气勘查前景。根据早白垩世晚期普遍发育的伸展作用,限定榆木山逆冲推覆构造发育的时间在早白垩世早期,从而提供了青藏高原北缘早白垩世早期高原隆升与扩展的证据。综合前人资料和本研究成果,建立了祁连造山带自新元古代以来的构造演化概念模型。
Abstract:The Qilian Orogenic Belt (QLOB), located on the northern margin of the Tethyan tectonic domain, suffered from the development and evolution of the Early Paleozoic Proto-Tethyan Ocean (i.e., the North Qilian Ocean, NQO), and was the key orogenic belt for the uplift and expansion of the Tibetan Plateau on its northeastern margin. Based on regional geological survey and structure geological mapping and combined with previous geophysical data and newly completed super-broadband magnetotelluric (MT) sounding, this paper expounds the characteristics of the fault system in Northwest China and the QLOB. Through superbroadband MT data acquisition, processing, and inversion, and structural interpretation of shallow, medium and deep electrical structures along the MT profile across the QLOB, the distribution of Mesozoic and Cenozoic basins related to the fault system, and the deep crustal structure underneath the QLOB are analyzed. The deep electrical structure of the QLOB reveals a fossil bidirectional subduction of the NQO plate in the Proto-Tethyan tectonic domain. According to deep electrical structure, the original width of the subducted North Qilian Ocean plate was over 600 km. The southward subducted NQO plate probably reached the north margin of the Qaidam Block (the present Qaidam Basin) in the south, with a gentle subduction angle underneath the Central and South Qilian Block. Then, the melting-broken plate (or slab) might have migrated downward to the depth. In the north, the subducted NQO plate probably reached the southern margin of the Yin'e Basin of the present position, with a steep subduction angle. The dumpling melting-broken NQO plate was separated from the crustal retention plate in the north, through the northward extrusion of the upper mantle. The authors hold that the folding deformation of the subducted ocean plate was probably caused by the compressional tectonics in the Mesozoic and the Cenozoic, especially during the Late Cimmerian orogeny of Early Cretaceous and the India-Asian continental collision in Neogene. The shallow part of the electrical structure proves that the Yumushan thrustnappe structure was developed northward to the North Qilian Fault, with the Yumushan as a klippe in the north. The concealed Early Cretaceous basin underneath the klippe should be a good area for oil and gas prospecting. According to the normal faulting developed in the Early Cretaceous, the authors constrain the main stage thrusting of the North Qilian Fault in the Early Cretaceous, which might provide the evidence for the uplift and expansion of the northern margin of the Tibetan Plateau in the Early Cretaceous. Based on combined data from previous researches and this study, the authors put forward a conceptual tectonic evolution model for the Qilian Orogenic Belt.
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1. 引言
祁连造山带地处青藏高原东北缘(图 1),是中国中央造山带或秦祁昆造山系的重要组成部分(杨经绥等,2010;潘桂棠和肖庆辉,2015)。祁连造山带是特提斯构造域最北部典型的增生型造山带,由北祁连造山带、中祁连地块和南祁连造山带等组成(陈宣华等, 2010, 2017)。祁连造山带经历了多期构造变形和复合造山过程,包括中元古代罗迪尼亚(Rodinia)超大陆的裂解(~1.5 Ga; Wang et al., 2016),新元古代大洋俯冲、大陆碰撞与裂解(杨经绥等,2009;夏林圻等,2016;Wu et al., 2016;Zuza et al., 2017),早古生代原特提斯洋(北祁连洋)弧盆系的形成演化与大洋俯冲、大陆俯冲和碰撞造山(杨经绥等, 2009, 2010;Song et al., 2014;潘桂棠和肖庆辉,2015;夏林圻等,2016;Wu et al., 2016),晚古生代碰撞造山后的伸展垮塌(孙廷贵等,2004;吴才来等,2004;杨超等,2010)、大陆裂解与宗务隆有限洋盆的形成演化(郝国杰等,2004;孙娇鹏等,2014),中生代陆内伸展(Chen et al., 2003;李奋其,2003;陈宣华等,2010)和新生代陆内造山(Wu et al., 2016, 2017;Zuza et al., 2016, 2017; Li et al., 2019)等过程,在印度—亚洲大陆碰撞和青藏高原新生代造山过程中起着重要的作用(Yin and Harrison, 2000;Yin, 2010; Zheng et al., 2013a, b; Li et al., 2015; Zhang et al., 2017; Zuza et al., 2017, 2019;Wu et al., 2019),具有复杂造山带地壳结构和深部过程(Wang et al., 2011; Gao et al., 2013;赵文津等,2014;Ye et al., 2015, 2016; 陈宣华等,2019a)。
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Figure 1. Sketch tectonic map of Asia (modified from Ren Jishun et al., 2013; Chen Xuanhua et al., 2017, 2019b)![]()
图 2 中国西北及周边地区断裂构造体系略图(据陈宣华等,2019a修改)TSFS—天山走滑断裂系统;ATF—阿尔金断裂;CZF—成吉斯—准噶尔断裂;KLF—昆仑断裂;CHF—车尔臣河断裂;SQDF—柴达木南缘断裂;NQDF—柴达木北缘断裂;NQLF—祁连山北缘断裂;HYF—海原断裂;图中给出超宽频大地电磁测深剖面(QLAL-2017MT)的位置Figure 2. Sketch map of the fault system of Northwest China and surrounding areas (modified from Chen Xuanhua et al., 2019a)TSFS- Tianshan strike-slip fault system; ATF- Altun Fault; CZF- Chingiz-Junggar Fault; KLF-Kunlun Fault; CHF- Cheerchen Fault; SQDF- South Qaidam Fault; NQDF- North Qaidam Fault; NQLF- North Qilian Fault; HYF- Haiyuan Fault. The location of super-broadband magnetotelluric sounding profile (QLAL-2017MT) is shown in Fig. 2![]()
图 3 祁连造山带及周缘断裂构造体系略图SQLOB—南祁连造山带;CQLB—中祁连地块;NQLOB—北祁连造山带;ATF—阿尔金断裂;KLF—昆仑断裂;NQDF—柴达木盆地北缘断裂;SDNF—党河南山南缘断裂;TDF—土尔根达坂断裂;NZF—北宗务隆山断裂;SQHF—青海南山断裂;SCQLF—中祁连南缘断裂;NCQLF—中祁连北缘断裂;SYNF—野牛沟南缘断裂;CMF—昌马—俄博断裂;NQLF—祁连山北缘断裂;HYF—海原断裂;TJF—天景山断裂;WQF—温泉断裂;RYF—日月山断裂;GHF—共和断裂;LSF—龙首山断裂;JTF—金塔断裂;AYF—阿拉善右旗断裂;YBF—雅布赖断裂;EGF—恩格尔乌苏南缘断裂;SYEF—银额盆地南缘断裂。图中给出超宽频大地电磁测深剖面(QLAL-2017MT)的位置Figure 3. Sketch map of the fault system of the Qilian Mountain Orogenic Belt and its adjacent areasSQLOB-South Qilian Orogenic Belt; CQLB-Central Qilian Block; NQLOB-North Qilian Orogenic Belt. ATF-Altun Fault; KLF-Kunlun Fault; NQDF-North Qaidam Fault; SDNF-South Danghe Nan Shan Fault; TDF-Tuergendaban Fault; NZF-North Zongwulong Shan Fault; SQHF- South Qinghai Fault; SCQLF-South Central Qilian Fault; NCQLF-North Central Qilian Fault; SYNF-South Yeniugou Fault; CMF- Changma-Ebo Fault; NQLF-North Qilian Fault; HYF- Haiyuan Fault; TJF-Tianjingshan Fault; WQF-Wenquan Fault; RYF-Riyueshan Fault; GHF- Gonghe Fault; LSFLongshoushan Fault; JTF- Jinta Fault; AYF-Alxa Right Banner Fault; YBF- Yabulai Fault; EGF-South Engeerwusu Fault; SYEF-South Yin' e Fault. The location of super-broadband magnetotelluric前人在祁连造山带及周缘测制了多条大地电磁测深剖面,包括格尔木—额济纳旗地学断面给出的电性结构,为研究祁连造山带岩石圈电性结构与构造演化提供了重要的科学依据(高锐等,1995;朱仁学和胡祥云,1995;汤吉等,2005;詹艳等,2008;赵国泽等,2010;Xiao et al., 2011, 2012, 2013, 2015, 2016)。本文在中国地质调查局深部地质调查工程支持下(吕庆田等,2019),依据区域地质调查与构造地质填图,结合前人地球物理场资料,通过超宽频大地电磁测深(MT)剖面数据采集处理与浅、深层反演剖面的构造解释,阐述了祁连造山带断裂构造体系与深部结构特征,提出了构造演化的综合模型。
2. 大地构造背景
祁连造山带位于青藏高原东北缘,处在特提斯构造域的最北部,其北部以祁连山北缘断裂(NQLF)与河西走廊盆地为界,并通过阿拉善地块与古亚洲洋构造域接壤;南部以柴达木盆地北缘断裂(简称“柴北缘断裂”,NQDF)与柴达木盆地为界,西北部被阿尔金断裂(ATF)所切,东部与秦岭造山带等相接(图 1,图 2,图 3)。祁连造山带是典型的增生型造山带,具有很厚的陆壳(可达72 km左右)和典型山根(由花岗质榴辉岩组成)特征(邓晋福等,1995);主要由复杂变形的早古生界岛弧和岩浆弧等组成,由南向北可分为南祁连造山带(褶皱带)、中祁连地块(隆起)和北祁连造山带(褶皱带)等3个近北西向展布的构造单元(图 3;陈宣华等,2010;胡道功等,2018)。祁连造山带发育多条蛇绿混杂岩带,构造运动复杂多样。祁连造山带及邻区地层发育齐全,自太古宙至新生代地层普遍发育,记录了早期大陆地壳的形成、大陆岩石圈的伸展、裂解、大洋岩石圈俯冲消减和陆内造山与构造变形等系列过程中的地质信息。
南祁连造山带(SQLOB)处在柴北缘断裂(NQDF)与中祁连南缘断裂(SCQLF)之间(图 3),主要由南祁连岩浆弧、滩间山岩浆弧、宗务隆山构造带裂谷和蛇绿混杂岩带等组成(王立全等,2013;潘桂棠和肖庆辉,2015)。南祁连造山带发育新太古代末期—古元古代早期构造岩浆活动(裴先治等,2007)。南祁连党河南山地区早古生代发育岛弧岩浆活动(赵虹等,2004)。柴达木盆地北缘发育沙柳河蛇绿岩组合(宋述光等,2009)。天峻南山地区经历了从晚古生代俯冲作用(246 Ma)到中生代后碰撞(215 Ma)的花岗岩类岩浆活动(郭安林等,2009)。宗务隆山构造带西起阿尔金山,向东经苏干湖盆地被第四系覆盖后,于土尔根大坂、达肯大坂又出露,继续东延,经南祁连南侧的宗务隆山延至青海南山的野马湖一带,呈北西西走向的窄条楔入南祁连加里东构造带与柴达木地块之间;主要为石炭—二叠纪裂谷(潘桂棠和肖庆辉,2015)。宗务隆山构造带石炭系为浅海碎屑岩-碳酸盐岩-火山岩沉积组合。
中祁连地块(CQLB)处在中祁连南缘断裂(SCQLF)与中祁连北缘断裂(NCQLF)之间(图 3),由中祁连—湟源地块以及叠置在其上的中祁连岩浆弧、党河南山—拉脊山蛇绿混杂岩带北带(大道尔吉—拉脊山—永靖蛇绿混杂岩带;Є-S)等组成(王立全等,2013;潘桂棠和肖庆辉,2015);主要为前寒武系片麻岩基底,其东段的马衔山岩群是祁连造山带古老变质基底岩系之一。中祁连东段(湟源)经历了新元古代岩浆活动;中祁连西段(野马南山)发育早古生代Ⅰ型花岗岩类岩浆活动(黄增保等,2015)。早志留世(441~434 Ma)进入后碰撞的伸展环境。
北祁连造山带(NQLOB)呈狭长带状展布于托莱南山与河西走廊之间,处在祁连山北缘断裂(NQLF)与中祁连北缘断裂(NCQLF)之间(图 3);主要由北祁连蛇绿混杂岩带主带(熬油沟—玉石沟—柏木峡蛇绿混杂岩带;Є-S)、走廊南山岛弧(O)、北祁连蛇绿混杂岩带北带(九个泉—大岔大坂—老虎山蛇绿混杂岩带;Є-S)和走廊弧后盆地(O-S)等组成(王立全等,2013;潘桂棠和肖庆辉,2015;张义平等,2015),其基底主要由太古宇和古元古界的结晶变质岩系组成。北祁连造山带是在新元古代Rodinia联合大陆(Pangen-850 Ma)基础上裂解,经由寒武纪裂谷盆地、奥陶纪初期成熟洋盆(北祁连洋)、奥陶纪中晚期北祁连活动大陆边缘、志留纪—早、中泥盆世碰撞造山而形成的。奥陶纪中、晚期,北祁连、河西走廊地区发育中、上奥陶统洋壳-岛弧-弧后火山岩,形成典型的沟-弧-盆构造-沉积体系。主造山阶段北祁连洋俯冲消减、增生,洋盆闭合、弧-陆碰撞,形成早古生代造山楔,下古生界发生强烈构造变形变质;伴随有大量的花岗岩类(500~400 Ma)侵位(许志琴等,1999;吴才来等,2006)。北祁连洋盆地接受了巨厚的寒武—奥陶系沉积,发育蛇绿岩套。下、中志留统为典型复理石浊流沉积,上志留统为滨浅海相磨拉石沉积;志留纪末期为北祁连的主造山期。泥盆系主要为典型的前陆盆地磨拉石建造;晚泥盆世进入后碰撞(造山)的伸展作用环境,造山带地壳开始减薄。石炭系以滨海沼泽相沉积为主。
北祁连造山带和祁连山南侧的柴达木北缘构造带发育以榴辉岩为代表的高压-超高压变质带,是国际地学研究的热点地区之一(Yang et al., 1998, 2002; 杨经绥等,2000;张建新,2000;Song et al., 2003a, 2003b, 2005, 2006, 2009, 2013, 2014)。北祁连中段清水沟—百经寺一带发育早古生代高压超高压变质作用,俯冲-增生杂岩带中的低温榴辉岩以透镜体形式产于蓝片岩和多硅白云母片岩中;榴辉岩相变质时代为463~468 Ma。柴北缘构造带中的榴辉岩及其围岩片麻岩中发育超高压变质矿物,如柯石英、金刚石和超高压微结构等(杨经绥等, 2001; Song et al., 2005),成为早古生代原特提斯洋壳俯冲和陆-陆碰撞的重要记录。
3. 断裂构造体系特征
3.1 总体特征
中国西北地区以显著的逆冲推覆构造和走滑断裂系的发育为特征,断裂构造体系错综复杂(图 2)。其中,逆冲推覆构造主要发育在祁连山和天山造山带的内部和山前,是青藏高原向NE扩展和祁连山、天山等山脉隆升的构造主因;走滑断裂系主要有天山走滑断裂系统(TSFS)和阿尔金走滑断裂系(ATF;Yin et al., 2002; Chen et al., 2004),前者与古亚洲洋构造域及中亚造山带的演化有关,后者与特提斯构造域及喜马拉雅—青藏高原造山带的演化有关。西北地区发育大量的蛇绿混杂岩带,一般与大型断裂构造相伴出现,是该地区从古亚洲洋和特提斯洋构造环境向大陆转换以及大陆显著增生的重要标志。
祁连造山带及其盆山结合带以发育显著的前新生代和新生代逆冲断裂系为特征,最主要的断裂系统包括祁连南山—柴北缘、中祁连和北祁连等逆冲断层系,以及走滑断裂系统等(图 3;陈宣华等,2010)。
祁连造山带及其盆山结合带以发育显著的新生代逆冲断裂系为特征,最主要的断裂带包括北祁连山山前断裂带、北祁连山南缘断裂带、中祁连山南缘断裂带、北宗务隆山断裂带、南祁连山山前断裂带(即柴北缘逆冲断层系的柴达木山逆冲断层带)、欧龙布鲁克山—牦牛山断裂带和赛什腾山—锡铁山断裂带等。其中,南祁连山—柴达木盆地北缘断裂系统为一组呈带状分布的断裂带,总体走向为NW—NWW向,以向柴达木盆地内部的逆冲推覆断裂为主,控制着祁连山和柴达木盆地北缘新生代盆-山构造的发育(陈宣华等,2010)。
3.2 祁连南山—柴北缘逆冲断层系
祁连南山—柴北缘逆冲断裂系为一组呈带状分布的断裂带,主要包括柴北缘和祁连南山等逆冲断层系,总体走向为NW—NWW向,以向柴达木盆地内部的逆冲推覆断裂为主,控制着祁连南山和柴北缘新生代盆-山构造的发育。祁连南山—柴北缘逆冲断层系构成由现今柴达木盆地与可可西里盆地构成的古柴达木盆地的北部边界,其启动时间不晚于始新世早期(Wu et al., 2019)。其中,柴北缘逆冲断层系形成于~49 Ma(Yin et al., 2002);祁连南山逆冲断层系可能形成于~33 Ma之前(Yin et al., 2002)。
柴达木盆地北缘可能是在奥陶纪晚期俯冲闭合的早古生代古洋盆(崔军文等,1999)和碰撞造山带(王惠初等,2005)基础上发育而来的。新生代柴北缘逆冲断层系由一系列北倾的基底卷入叠瓦状逆冲断层组成,主要断裂(带)为柴北缘断裂、大赛什腾山北逆冲断层、小赛什腾山北逆冲断层、赛南逆冲断层带、鱼卡—绿梁山断裂带(包括西绿梁山和东绿梁山等逆冲断层)、锡铁山断裂带和欧龙布鲁克山—牦牛山断裂带(包括欧龙布鲁克和埃姆尼克山等逆冲断层带)等,将古生代变质沉积岩、变质火山岩和含超高压(UHP)榴辉岩的片麻岩逆冲推覆到新生代地层之上,是祁连南山—柴北缘逆冲断裂系的南缘部分(陈宣华等,2010)。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近纪沉积岩之上的无根推覆体(王根厚等,2001)。
祁连南山逆冲断层系主要由党河南山南缘断裂(SDNF)、土尔根达坂断裂(TDF)、北宗务隆山断裂(NZF)和青海南山断裂(SQHF)等组成(图 3)。其中,党河南山南缘断裂和土尔根达坂断裂均为北倾的逆冲断层,将达肯大坂岩群和古生代地层逆冲推覆在新近系之上,与柴北缘断裂一起构成祁连南山—柴北缘逆冲断裂系的主体。北宗务隆山断裂为南倾的韧性剪切带,具有左行剪切特征;其将达肯大坂岩群和宗务隆蛇绿混杂岩逆冲推覆在三叠系隆务河群之上(郭安林等,2009)。青海南山断裂可能具有与北宗务隆山断裂类似的逆冲极性,它们同时构成祁连南山—柴北缘逆冲断裂系的反向逆冲断层。
3.3 中祁连逆冲断层系
主要由中祁连南缘断裂(SCQLF)和中祁连北缘断裂(NCQLF)等组成,分别构成中祁连地块的南、北边界(图 3)。
中祁连南缘断裂:主断裂由SW向NE方向逆冲,倾角50°~70°;其逆冲方向与祁连造山带断裂构造体系的主逆冲方向相一致。局部可见前寒武纪基底和古生界强烈逆冲推覆在中—新生界(新近系)之上。在疏勒南山的东南端,由于受到野马山—疏勒南山南缘断裂自NE向SW方向的逆冲推覆作用影响,该断裂表现为自NE向SW的反向逆冲。在构造地貌方面,该断裂可能是形成党河谷地地貌的主因。由于新生代阿尔金断裂和海原断裂、天景山断裂等左行走滑断裂活动的影响和改造,该断裂兼具左行走滑性质。
中祁连北缘断裂:西起野马山北麓,向东经托莱南山北麓、托莱河谷至托莱山一线展布,主断裂由SW向NE方向逆冲。向东或继续向大坂山延伸,或归并到祁连山北缘断裂之中,并在经过冷龙岭南坡之后,发散为海原断裂和天景山断裂构成的左行走滑断裂系。该断裂显著的构造地貌特征是形成野马山、托莱南山和托莱河谷,将中祁连地块前寒武纪变质岩系逆冲推覆在北祁连蛇绿混杂岩带之上。在托莱南山北麓,可见前寒武纪变质岩系逆冲推覆在白垩系之上。
3.4 北祁连逆冲断层系
主要由野牛沟南缘断裂(SYNF)、昌马—俄博断裂(CMF)、祁连山北缘断裂(NQLF)、榆木山逆冲推覆构造系统(YMTS)和河西走廊活动断裂系等组成(国家地震局地质研究所、国家地震局兰州地震研究所,1993;陈宣华等, 2010, 2019a;Zuza et al., 2019)。
野牛沟南缘断裂:西起镜铁山西侧,向东横穿北大河而进入黑河流域,沿托莱山北麓展布,在祁连县南东一侧归并到中祁连北缘断裂。它与中祁连北缘断裂分别构成北祁连蛇绿混杂岩带主要的北、南边界。该断裂具有由SW向NE方向逆冲的构造极性,控制了野牛沟和祁连等多个早白垩世盆地的发育,并将北祁连蛇绿混杂岩(含前寒武纪变质岩系和早古生代蛇绿岩套)逆冲推覆在早白垩世沉积盆地之上。
昌马—俄博断裂:也被称为昌马—祁连断裂带,主要由西段的昌马断裂和中东段的肃南—祁连断裂等连接而成;从昌马盆地的南缘向东经红窑子、月牙大坂、大泉口、臭水柳河、白泉门、大台子等地区,总体走向为N60~80°W,断面倾向SW,倾角55~60°(国家地震局兰州地震研究所,1992;国家地震局地质研究所和国家地震局兰州地震研究所,1993)。该断裂向东自俄博之后,归并到祁连山北缘断裂的冷龙岭断裂段,向东与海原断裂及天景山断裂相接。昌马—俄博断裂具有多期活动,可能最初形成于印支期,控制了白泉门三叠纪沉积盆地的发育;早白垩世以来活动加剧,将前新生代地层逆冲推覆在新生代地层之上,晚第四纪和全新世仍有活动。该断裂可能为超岩石圈断裂,以挤压逆冲为主,兼具左行走滑性质(国家地震局兰州地震研究所,1992)。
祁连山北缘断裂:也被称为北祁连北缘断裂(胡道功等,2018),为祁连山主逆冲断层,构成北祁连榆木山逆冲推覆构造系统的根带。该断裂主要由佛洞庙—红崖子断裂和冷龙岭断裂等各段组成,主要为第四纪活动构造(国家地震局地质研究所和国家地震局兰州地震研究所,1993)。主要沿祁连山北部边缘展布,西起昌马北部的疏勒河口(昌马河口),向东经金佛寺、肃南、民乐扁都口、俄博、金瑶岭、冷龙岭至雪龙横山以北;其东段通过雷公山—毛毛山断裂与左行走滑的海原断裂相接。可作为北祁连造山带(祁连山)与河西走廊盆地的大致边界,控制了河西走廊盆地早白垩世沉积。断层呈波状弯曲或锯齿状,总体走向NW,倾向SW,倾角为45~80°;以挤压逆冲为主,兼具左行走滑性质。断裂具多期活动,其形成可追溯到早古生代,晚古生代、中生代和新生代均有活动,第四纪(全新世)构造活动强烈。
榆木山逆冲推覆构造系统:榆木山及周边地区主要发育北祁连逆冲断层系(NQLTS)北部的构造要素,可称为榆木山逆冲推覆构造系统(YMTS),由一系列北西向、北西西向逆冲断层和系列褶皱组成,其根带为祁连山北缘断裂(NQLF)。该系统主要由榆木山南缘断裂(SYMF)、肃南断裂(SNF)、榆木山北缘断裂(NYMF; 国家地震局兰州地震研究所,1992;Ren et al., 2019)、梨园堡断裂(LYF;陈宣华等,2019a)等组成,具有多期活动的特点,主要为早白垩世早期的逆冲推覆构造。其中,榆木山南缘断裂和榆木山北缘断裂分别构成榆木山飞来峰的南、北边界;梨园堡断裂为挤压逆冲过程中引发的右行走滑断裂,相伴发育走滑双重构造(陈宣华等,2019a)。
河西走廊活动断裂系:河西走廊是青藏高原向北东扩展的最前缘,是现今构造变形和地震活动最为强烈的地区之一(Tapponnier et al., 1990;Hetzel et al., 2004;陈柏林等,2008;张培震等,2014;陈干等,2017;Yang et al., 2018a, 2018b);同时产出有作为我国最早石油基地的玉门油田(杨树锋等,2007;Cheng et al., 2019)。河西走廊活动断裂系主要包括榆木山北部山前的大更子断裂(DGF)、小更子断裂(XGF)、张掖断裂(ZF),以及河西走廊西部的嘉峪关—文殊山断裂(JWF)、宽滩山断裂(KF)等。大更子断裂和小更子断裂等构成榆木山北部山前的活动隐伏逆冲断层系,是榆木山逆冲推覆构造系统的重要组成部分(陈宣华等,2019a)。嘉峪关—文殊山断裂位于酒泉东部盆地的西侧,将酒泉盆地分割成酒西和酒东两个盆地;断裂呈NNW向展布,倾向SW,倾角陡立,具强烈的挤压逆冲特征,兼具右行走滑性质,为新生代和晚第四纪强烈活动的断裂(李玉龙,1984)。宽滩山断裂为南倾的隐伏逆冲断裂,其动力学与青藏高原南缘主边界逆冲断裂(MBT)类似,被称为青藏高原“北边界断裂”(North Boundary Thrust, 即NBT),沿NBT阿拉善地块可能向青藏高原之下俯冲(高锐等,1998)。
3.5 走滑断裂系统
主要包括由海原断裂(HYF)和天景山断裂(TJF)等构成的左行走滑断裂系统,以及由温泉断裂(WQF)、日月山断裂(RYF)和共和断裂(GHF)等组成的右行走滑断裂系统(图 3)。
海原断裂:是青藏高原东北缘最显著的边界断裂之一,整体呈现向NE凸出的宽缓弧形特征;其东起六盘山东麓,与NNW向六盘山逆冲断层相连接;向西北经月亮山—南华山—西华山北麓、黄家洼山南麓、哈思山—哈拉山南麓、米家山北麓和甘肃景泰兴泉堡,向西进入乌鞘岭,与雷公山—毛毛山断裂斜接,并归并到祁连山腹地WNW向逆冲断层系之中。海原断裂具有多阶段演化历史,其初始阶段强烈的NE向逆冲推覆始于(12±3)Ma,~5.4 Ma以来以不断增强的左行走滑为特征(王伟涛等,2014);第四纪表现为强烈的左行走滑和强震特征,记录了高原向NE扩展的构造过程(施炜等,2013)。海原断裂切过上、中地壳,具有多个分支,并归集到下地壳低角度拆离剪切带之中(Gao et al., 2013)。
天景山断裂:发育在青藏高原的东北缘,为青藏高原的东北边界,具有向NE凸出的弧形特征。该断裂向东与六盘山逆冲断层相接;自中卫南部向西经古浪进入冷龙岭,与海原断裂一起,归并到祁连山逆冲断层系之中。该断裂具有第四纪左行走滑特征。
温泉断裂:主要沿哇洪山一线分布,呈NNW向延伸达200 km以上,构成柴达木盆地—东昆仑与共和盆地—西秦岭的边界。断裂北端斜接柴北缘断裂,南端切断柴达木南缘断裂(即昆中断裂)。断裂总体走向330~350°,多数断面倾向SW,倾角50°~ 70°。该断裂具有右行走滑特征,为一条壳内转换断层,其右行走滑视位移量为~10 km;断裂作用发生在早上新世时期,与左行走滑的阿尔金断裂构成共轭剪切断裂体系(陈宣华等,2010)。
4. 地球物理场特征及其对断裂构造体系的反映
4.1 区域重力场特征
祁连造山带具有与周缘盆地及造山带明显不同的区域重力场特征。其中,南祁连为NW向展布的重力低异常带,布格重力值为(-460 ~ -320)×10-5 m/s2;中祁连为NNW向展布的梯级带,幅值为(-440 ~ -360)×10-5 m/s2,局部为重力高或重力低异常;北祁连为NNW向展布的梯级带,北祁连南部为(- 350 ~ - 400) × 10-5 m/s2,河西走廊为(- 350 ~ -260)×10-5 m/s2;银额盆地南部等地区为重力高异常区,布格重力值为(-255 ~ -180)×10-5 m/s2(冯治汉等,2018)。
在剩余重力异常方面,祁连造山带与河西走廊盆地一起,构成被周缘剩余重力高所围限的相对低值区,剩余重力最低值出现在中祁连及之南的地区,与断裂构造体系的展布特征相一致(图 4a)。西宁盆地西侧的祁连山西部地区,其剩余重力异常表现为周缘高、中间低,呈NWW向展布;其上叠加局部负异常形态不规则,主要是中—新生代沉积盆地和古生代中酸性岩体的综合反映。河西走廊西部的酒西、酒东和民乐盆地,剩余重力异常表现为与祁连山走向大致平行,异常为NWW走向。银额盆地南部剩余重力异常表现为两组异常的迭合,以NEE向的重力异常为主,可能主要受前中生代构造格局控制;NNE向异常次之。在阿尔金山地区,剩余重力异常呈NE走向,南北均为重力高,中部发育局部负异常,可能与中—新生代地层的加厚有关。柴达木盆地也表现为被周缘重力高所围限的相对重力低值区,并具有东、西分区特征,西部为低值区。
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图 4 祁连山及周缘地球物理场异常及其与断裂构造体系的关系a—剩余重力异常及其与断裂构造体系的关系,剩余重力异常据冯治汉等(2018);b—航磁∆T场化极垂向一阶导数异常及其与断裂构造体系的关系,航磁∆T场化极垂向一阶导数异常据熊盛青等(2015);ALB—阿拉善地块;NQLOB—北祁连造山带;CQLB—中祁连地块;SQLOB—南祁连造山带;QDB—柴达木地块;DHB—敦煌地块Figure 4. Sketch maps showing the relationships between the geophysical field anomalies and the fault system in the Qilian Mountain and surrounding areasa-Residual gravity anomaly (after Feng Zhihan et al., 2018) and its relationship with fault system; b-First vertical derivative anomaly of the aeromagnetic ∆T field polarization (after Xiong Shengqing et al., 2015) and its relationship with fault system; ALB-Alxa Block; NQLOB-North Qilian Orogenic Belt; CQLB- Central Qilian Block; SQLOB-South Qilian Orogenic Belt; QDB-Qaidam Block; DHB-Dunhuang Block4.2 区域航磁特征
祁连造山带航磁异常总体呈NW至NWW走向,由多条NW向线性正磁异常带组成(图 4b),磁异常强度为50 ~ 200 nT;当磁场上延10 km、20 km后,反映为宽缓的区域性正负磁场(熊盛青等,2015)。其中,柴北缘—南祁连航磁异常由一连串等轴状、长条状高磁异常组成,西段为平稳磁场背景上叠加区域性负异常和局部磁异常;中祁连地块磁异常区,磁异常平静,幅值变化不大;北祁连为NWW走向的高磁异常带,局部为长条状、椭圆状,异常强度为100~200 nT;河西走廊地区为相对平静的磁场,仅有少量几处局部磁异常。银额南部为负磁异常区,包括宗乃山、特罗西滩以南、雅布赖山以西地区,磁力异常以NEE向展布为主;北部为正磁异常区,与特罗西滩隆起、宗乃山隆起带相对应(熊盛青等,2015;冯治汉等,2018)。区域航磁异常的展布与断裂构造体系具有较好的一致性。
与祁连造山带不同,柴达木盆地航磁异常呈磁场镶嵌特征,为宽阔、平缓、正负伴生异常,强度80~ 100 nT,以正磁异常为主;磁异常宽阔平缓之原因可能与古元古界结晶岩系埋深有关,异常的次级波动跳跃,反映出基底的不均一性(熊盛青等,2015)。
5. 超宽频大地电磁测深揭示的深部结构特征
5.1 数据采集
超宽频大地电磁测深法是在常规大地电磁测深(MT)测量基础上,结合长周期大地电磁、音频大地电磁等方法的探测优势,综合发展起来的深层、超深层大地电磁探测方法。与常规MT方法相同,超宽频MT方法以天然平面电磁波作为场源,通过高频和低频的双向扩频,弥补了常规MT方法对高频和低频信号响应的不足,以获得有用的深部信息。超宽频MT方法高频采集频率达到10000 Hz,尽可能提高对浅部不均匀电性体的识别、控制;低频部分采样频率最大控制到0.0001 Hz,在兼顾调查效率的同时,实现了对地下深部电性体的控制,其探测深度可达下地壳及上地幔。实验研究表明,采用长周期仪器设备和稳定性好的不极化电极,合理布置测站,能够采集到最长周期达几万秒的长周期大地电磁场信号(叶高峰等,2013)。
2017年6—7月,本项目组部署采集了柴北缘—祁连山—河西走廊盆地—合黎山—大青山—银额盆地南缘的超宽频MT剖面(图 2,图 3),测线编号为QLAL-2017MT,施工号为QL2017MT。剖面从南到北经过的大地构造单元包括柴达木地块(含柴达木盆地、德令哈坳陷和乌兰坳陷)、祁连造山带(包括南祁连造山带、中祁连地块、北祁连造山带,含天峻坳陷、木里坳陷等)、河西走廊过渡带(含酒泉盆地和民乐盆地)和阿拉善地块(包括阿拉善弧形构造带和银额盆地)。
超宽频MT测量的野外施工采用大间距张量观测方式,共采集Ex、Ey、Hx、Hy、Hz 5个分量,测深点距平均约5 km。投入使用的电法仪器及磁棒包括8台MTU-5A,19台V5- 2000(含1台备用),14根AMTC- 30和MTC- 80H磁棒、40根MTC- 50磁棒。通过仪器性能检测标定、一致性试验和采集参数试验,确定了极距和采集时间等采集参数。在平坦区,野外电极布置采用“+”字型方式布极,两对电极组成一个正交十字形,采集站基本在中心位置,南北向(0°)的偶极子为Ex,东西向(90°)的偶极子为Ey;电极距长度布设在180~200 m。在山地、沼泽、高压线、公路、铁路等布极困难地区,适当采用“L”型或“T”型装置布极,电极长度布设在50~200 m,极困难山区不低于30 m。电极、磁棒布设利用全站仪配合森林罗盘仪进行定向、测距。高频数据采集时间大于30 min;宽频带低频数据采集时间大于10 h,施工中保证单点全天采集,超宽频测深点采集时间为6 d以上。仪器开始及结束MT采集施工的一致性均方误差小于4%。QLAL-2017MT剖面采集长度为464 km,共采集91个测点,其中超宽频测深点31个(频率范围10000~0.0001 Hz),宽频测深点60个(10000~0.0005 Hz);宽频测深点在全线分布均匀。
5.2 数据处理
超宽频MT资料处理包括数据预处理、资料反演、资料定性分析三个阶段。本次超宽频带大地电磁测深剖面测量中,每个测点数据采集分别使用了两种仪器,其中高频段使用MTU-5A仪器采集,频率为10000~10 Hz;低频段使用V5-2000采集,频率为360~0.0005 Hz(超宽频的低频为0.0001 Hz),两种仪器采集的数据在360~10 Hz频段相互重叠。在后续的数据处理之前,先是将这两种仪器采集的高频和低频数据进行拼接叠合成全频段曲线,然后进行了去噪处理以压制采集噪声影响,进行了极化模式识别,利用各测点首支电阻率分析进行了静态位移校正,并将大地电磁场分量随时间的变化转换成频谱,得到视电阻率和阻抗相位等参数的频率响应,获得视电阻率与相位剖面图件(图 5)。
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图 5 大地电磁测深剖面(QLAL-2017MT)静态位移及静校正对比图Figure 5. Comparison of static migration and static correction of magnetotelluric sounding profile (QLAL-2017MT)利用相位断面可以判断视电阻率静态改正的合理性。相位剖面等值线的横向变化可定性确定地层的起伏变化及断裂位置。在视电阻率剖面上(图 5a,图 5b),等值线横向分段特征明显,呈高阻、低阻相间分布的特征;在纵向上,有的显示低-高-低三层电性特征,有的显示高-低-高-低四层电性特征。由趋肤深度推断,在0.1 Hz附近相对连续的一套相对高阻层,是壳内高阻基底,该套层的厚度定性反映了高阻基底的厚度。而在该套高阻层下,出现一套相对连续的低阻,推测为壳内高导层。在1080、1170、1270、1350、1400等测点附近,剖面等值线突变,呈陡直状,推测为大型断裂的反映。相位断面形态(图 5c)与视电阻率具有较好的一致性;由于相位不受静态效应影响,其形态在横向上更加连续。
5.3 电性结构反演
通过野外小极距电性测量、钻井、地震、重磁和区域地质资料对电性层进行地质推断解释,确定电性层与地层的对应关系。对测区内的构造、地层起伏变化等建立整体的认识,采用可视化人机交互数据预处理系统,根据MT数据资料的特点,参照已有地质、地球物理探测成果,重新进行人机交互资料编辑,压制各种干扰,突出有效信息,然后在定性分析认识的基础上进行定量的一维反演和二维反演解释,将频率域相位断面转换成深度域的电阻率剖面。
根据测深点距大、沿测线构造复杂、相邻点构造跨度大、地表出露地层多、电性差异大等特点,本次研究采用以高频资料为标准、进行全频段手工智能校正的静态位移校正方法,对超宽频MT不同频段的数据分别进行有针对性的反演计算,获得浅层和中—深层两个深度的反演剖面并进行分析解释。一维大地电磁测深曲线的近似反演采用Bostick法。二维反演采用共轭梯度法。
浅层精细反演采用的频率范围为10000~0.001 Hz,为常规MT频段加上向高频扩频部分,反演深度10 km,主要反映基底及以上沉积地层构造及展布特征(图 6a)。本次研究尽可能多地收集和分析了地面地质及物性等资料,充分考虑了地层、岩性与电性的对应关系,对浅层反演结果进行标定和校正,提高了浅层反演的可靠性。按照由浅到深、由已知到未知的原则,在浅层反演结果可靠的条件下,也提高了中—深层的反演精度。
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图 6 大地电磁测深反演剖面(QLAL-2017MT)的构造解释a—共轭梯度法浅层反演剖面;b—浅层反演剖面的构造解释;c—共轭梯度法中—深层反演剖面;d—中—深层反演剖面的构造解释;断裂名称:NQDF—柴达木盆地北缘断裂;NZF—北宗务隆山断裂;NTJF—天峻盆地北缘断裂;SCQLF—中祁连南缘断裂;NMLF—木里盆地北缘断裂;NCQLF—中祁连北缘断裂;SYNF—野牛沟南缘断裂;CMF-昌马—俄博断裂;NQLF—祁连山北缘断裂;YN—榆木山逆冲推覆构造;NYMF—榆木山北缘断裂;LSF—龙首山断裂;JTF—金塔断裂;SYEF—银额盆地南缘断裂;Gr—花岗岩Figure 6. Structural geological explanation of magnetotelluric sounding profile (QLAL-2017MT)a-Inversion profile of shallow layers using conjugate gradient method; b-Structural interpretation of inversion profile of shallow layers; c-Inversion profile of middle to deep layers using conjugate gradient method; d-Tectonic interpretation of inversion profile of middle to deep layers. Fault names: NQDF-North Qaidam Fault; NZF- North Zongwulong Shan Fault; NTJF-North Tianjun Fault; SCQLF-South Central Qilian Fault; NMLF-North Muli Fault; NCQLF-North Central Qilian Fault; SYNF-South Yeniugou Fault; CMF-Changma-Ebo Fault; NQLF-North Qilian Fault; YN-Yumushan Nappe; NYMF-North Yumushan Fault; LSF-Longshoushan Fault; JTF- Jinta Fault; SYEF-South Yin' e Fault; Gr-Granite5.4 浅层结构特征
超宽频大地电磁测深剖面资料处理与反演结果显示了较为清晰的浅层地壳结构(图 6b)。在剖面南部,MT浅层反演结果显示柴达木北缘乌兰盆地与北侧宗务隆山北缘断裂(NZF)的规模较小,宗务隆山底部与柴达木地块有着相似的电性特征,但往北电性界面的起伏明显增大,指示柴达木盆地北缘断裂(NQDF)、宗务隆山北缘断裂均与浅层新生代沉积盆地的挤压变形相关,往北挤压变形强度增大。在宗务隆山北缘断裂上盘出现的高阻异常表明,在宗务隆山存在岩体侵入,位置与地表出露的花岗岩及花岗闪长岩对应(郭安林等,2009)。宗务隆山北缘断裂北侧的新生代天峻盆地与柴达木北缘乌兰盆地具有非常相似的电性结构特征。
在新生代天峻盆地北侧,南祁连造山带出现显著的高阻电性体分布特征,高阻体在地表与出露的古生代次高阻层对应,地层岩性主要为志留系浅变质砂泥质岩石,岩石普遍发育片理及韧性变形,分布范围位于天峻盆地与中、新生代木里盆地之间,并在高阻体南北分界处形成电性快速变化的密集梯度带,南侧密集梯度带呈陡北倾,具有大型挤压逆冲构造特征,向下延伸规模较大。本次研究将之命名为天峻盆地北缘断裂(NTJF;图 6b),可作为中、新生代柴达木盆地向北扩展的边界断裂。北侧过渡带同样具有北倾特征,但倾角较缓,具有北倾逆冲断层的特征,规模较大。
南祁连造山带北部的中、新生代木里盆地呈明显的低阻特征。木里盆地的南北两侧受挤压构造控制,具挤压坳陷盆地特征。木里盆地北缘断裂(NMLF)的南侧发育中祁连南缘断裂(SCQLF),总体为南倾,构成南祁连造山带与中祁连地块的浅部边界。中祁连地块呈相对高阻特征,其中下元古界地层电阻率高于早古生界地层,与中祁连地表的下元古界及北祁连早古生界地层的电性统计结果一致。中祁连北缘断裂(NCQLF)具有南倾特征,向下延伸规模较大,构成中祁连地块与北祁连造山带的浅部边界。
祁连山北缘断裂(NQLF)是祁连造山带与河西走廊过渡带的分界断裂,处在北祁连造山带的北缘,其北部以低阻的中、新生代盆地发育为主要特征。祁连山北缘断裂上盘主要为高阻地质体;断裂下盘主要为低阻的中、新生代沉积盆地,已发生强烈的挤压变形,盆地南缘被压伏在逆冲断层之下。由于断裂上盘强烈的逆冲挤压作用,在祁连山北缘断裂以北形成榆木山逆冲推覆构造(YN),祁连山北缘断裂构成逆冲推覆构造的根带。作为局部的高山,由志留系复理石建造为主的榆木山构成飞来峰构造,其之下均为电阻率较低的白垩系,说明在榆木山飞来峰之下为早白垩世酒泉盆地的一个分支;盆地基底发生明显压陷变形,底部具有隐伏断裂构造控制特征。榆木山北缘断裂(NYMF)构成逆冲推覆构造的前锋,也是该地区青藏高原的北界(陈宣华等,2019a)。
中—深层反演采用频率范围为320~0.0001 Hz,为常规MT加上低频扩频和超低频部分,反演深度可达150 km以深,主要反映地壳及上地幔的物性结构特征(图 6c)。反演过程中采用了浅层静态位移校正的结果,对该频段曲线进行校正。
一维Bostick与二维共轭梯度反演结果的大体结构基本一致,二者在横向上结构相似,而在纵向上,共轭梯度比Bostick结果刻画精细,基本上可以划为高-低-高三套电性层,与地壳及上地幔的结构特征具有较好的一致性。因此,最终的地质构造解释主要依据二维共轭梯度反演结果。
在榆木山北缘断裂以北,中生代民乐盆地与榆木山南侧的酒泉盆地分支具有连续发育的特征,但盆地构造挤压变形幅度逐渐减弱;民乐盆地的白垩系和新生界沉积岩(K-Cz)最厚可达~4 km。
河西走廊盆地北侧的龙首山断裂(LSF)倾角较大,其向下部延伸的幅度不大,主要为走滑断裂特征,构成阿拉善地块的南界。阿拉善弧形构造带的中部发育高阻基底隆起,分割了两侧的早白垩世坳陷盆地。南侧盆地发育的断裂及岩体规模进一步减弱,反映随着远离祁连造山带,阿拉善地块的刚性逐渐增强。在银额盆地南缘断裂(SYEF)处,出现明显的近直立基底电性扭折带,反映该断裂具有强烈走滑变形特征。SYEF北侧的银额盆地在剖面上具有较为稳定的基底和沉积盖层发育特征。
5.5 中—深层电性结构特征
祁连造山带及周缘深部电性结构差异较大,电性层起伏大,但具有一定的纵向成层性,可大致划分为4套电性层,分别为:上部高阻层,厚度一般小于40 km,主要对应上地壳;中上部低阻层,深度一般在20~70 km,低阻层断续分布,局部发育高阻团块异常,对应下地壳;中深部高阻层,一般埋深在50~120 km,高阻层断续分布,局部发育低阻异常,推测主要为上地幔的反映;深部低阻层,一般在120 km以深发育,连续性差,推测为软流圈的反映。
柴达木地块具有最厚的上地壳高阻层,电阻率高。南祁连造山带上地壳厚度大、电阻率高,中祁连地块、北祁连造山带与河西走廊过渡带的上地壳厚度小、电阻率低,并具有向北厚度变薄的趋势。阿拉善地块(银额盆地)的上地壳厚度较大,有一定的变化,电阻率中等。上地壳厚度变化反映了构造稳定性的变化;柴达木、南祁连和银额盆地的上地壳厚度大、电阻率高,具有较强的稳定性。
该剖面下地壳厚度变化在15~40 km。其中,柴达木地块的下地壳厚度最薄,只有18 km左右;向北厚度逐步增大,达40 km左右,在柴达木北缘断裂附近有明显上隆,至南祁连南部一直保持着较厚的下地壳。中祁连南部至河西走廊过渡带南部的下地壳逐渐变薄,发育有下地壳和MOHO(莫霍)面斜坡。河西走廊和龙首山之下的下地壳总体表现为一套电阻率极低的电性层,电阻率只有5~100 Ω·m,厚度较大。北部阿拉善地块的下地壳厚度一般在20~30 km。
从中—深层反演剖面来看,祁连造山带的莫霍面起伏较大,埋深在42~80 km,具有波状起伏特征。在柴达木地块的北缘和北祁连造山带—走廊过渡带南部地区,分别形成两个幔隆区。而在南祁连造山带—中祁连地块和阿拉善地块北部之下,则分别形成两个幔坳区;MOHO面最深处可能位于南祁连造山带之下,最大可达80 km以深。
6. 讨论
6.1 深部电性结构的构造指示意义
前人已有的多条大地电磁测深剖面显示,祁连造山带及周缘深部电性结构复杂多样,存在明显的横向变化和纵向分层(高锐等,1995;朱仁学、胡祥云,1995;汤吉等,2005;詹艳等,2008;赵国泽等,2010;Xiao et al., 2011, 2012, 2013, 2015, 2016)。其中,阿尔金断裂带为一个近于垂直的电阻率边界带;走廊过渡带总体显示为低阻(高速)异常,存在中、下地壳低阻异常区;走廊过渡带与北祁连之间存在“鳄鱼嘴”构造,其中、下地壳向北祁连下方俯冲,而上地壳有向南仰冲的构造样式;北祁连电性结构相对复杂,上地壳上部为高阻异常,上地壳下部局部存在低阻异常区,下地壳—上地幔顶部的低阻异常不发育;中祁连地块上地壳为明显的高阻异常,下地壳—上地幔顶部显示为低阻异常,不连续延伸至北祁连下方的上地幔之中;中、南祁连地块的上地壳以高阻异常为主,局部发育低阻异常区,下地壳发育低阻异常带,向南延伸至柴达木盆地内(Xiao et al., 2011, 2012, 2013, 2015, 2016)。
本研究给出的超宽频MT中—深层反演剖面显示,祁连造山带及周缘的岩石圈电性结构具有一个非常明显的特点,即广泛发育壳内和上地幔低阻(高导)层(HCL),其电阻率值较小;在北祁连造山带之下~30 km深度等局部地区的电阻率甚至小于10 Ω·m。这一高导层具有横向上的连续分布和间断特征,并在垂向上跨越了中、下地壳和上地幔,总体上表现为一个向南倾伏的倒转背形形态(图 6c)。在中祁连地块—北祁连造山带—河西走廊过渡带地区,低阻高导层的上界面埋深最浅,可达上地壳的下部或地表浅层;向南,低阻高导层上界面的埋深逐渐加深,在南祁连造山带的宗务隆构造带之下~80 km深处发生断离,并继续向南在柴达木地块北缘之下迅速加深并向150 km以深延伸。在河西走廊过渡带下方,低阻高导层也在~80 km深处发生断离,并迅速向下进行垂向延伸,垂深可达150 km以深,导电性在20~40 Ω·m,接近于稳定大陆区的中、下地壳导电性。
祁连造山带及周缘的壳内和上地幔高导层成因机制存在多种不同的观点。根据地质构造特征和流变学性质分析,含盐流体的填充、导电矿物的富集、壳内岩石的部分熔融等,均可引起中、下地壳电阻率的减小。但是,导电矿物的富集难以引起大范围连续分布壳内高导层的形成;而部分熔融多发生在火山发育区或具有较高热流值的区域,可能与地壳内部的局部热富集有关,要求有较高的温度,这与祁连造山带的情况相左。大地热流数据显示,中祁连地块的平均热流值为68.3 mW/m2,海原弧形构造区为60 mW/m2,均难以达到部分熔融的局部热富集要求。因此,用部分熔融来解释区内存在的高导体有一定的困难;部分作者倾向于含盐水流体成因(金胜等,2012)。也有的作者认为,祁连造山带的下地壳温度可达到或超过550 ℃,可能已发生部分熔融(李清河等,1998;涂毅敏等,2000)。一般认为,上地幔的高导层可能是岩石部分熔融与含盐水流体引起的。
现代海底之下50~150 km处的大洋岩石圈上地幔具有高的电导率(0.02 ~ 0.2 S/m;Naif, 2018)。与板块的年龄无关,亏损的洋中脊玄武岩地幔(DMM)在100~300 km深处的电导率为10-1.2~-1.5 S/m(Katsura et al., 2017)。考虑到大洋岩石圈的含水量较高和高温状态,而在通过俯冲碰撞导致大洋关闭而形成大陆之后,大洋岩石圈的残余(如蛇绿混杂岩带)经历了脱水和降温作用,其电导率应有所下降。Xu et al.(2016)认为,我国西北西准噶尔造山带的宽频带大地电磁测深剖面上存在晚古生代“化石”洋内俯冲带。Yin et al.(2017)在纵贯华北造山带(Trans-North China Orogen,简称TNCO)的MT阵列观测中,将电阻率为10~100 Ω · m相对高导的岩石圈地幔解释为“化石”大洋俯冲带。本研究超宽频MT测深得到的祁连造山带壳内和上地幔高导层(HCL),与大洋岩石圈地幔的电导率相当,可能是大洋岩石圈板块的残余。
柴北缘—祁连造山带—走廊过渡带广泛出现的壳内和上地幔低阻高导层(HCL),除了该地区普遍存在的高含水量之外,也可能为早古生代双向俯冲的北祁连洋板块残余的反映(图 6d);低阻高导层在局部可以通过逆冲断层连通到地表的蛇绿混杂岩带,也说明了其代表洋板块残余的可能性。同时,本研究提出的模式认为,祁连造山带之下发育了大范围的层状低阻大洋俯冲板片的断裂构造,低阻大洋板片向南俯冲到巨厚的祁连造山带山根之下,出现大洋板片间断熔离区,并在熔离板片的前缘出现局部向上反冲的折返特征,这一构造特征与南祁连造山带中出现的蛇绿混杂岩带密切相关。在北祁连洋(原特提斯洋)板块的北部,向北俯冲的大洋板片以具有右行走滑性质的银额盆地南缘断裂(SYEF)为界与阿拉善地块对接,在对接带下部同样存在已断离的深俯冲古大洋板片,揭示了早古生代北祁连洋板块向南、北两个方向俯冲的双俯冲模式,以及加里东期古老造山带的山根和俯冲板片的断离构造。由于中生代以来挤压构造事件的影响,这一向南、北两侧双向俯冲构造的残余,也发生了严重的挤压缩短变形,构成向南倾伏的倒转背形形态。随着北祁连洋的俯冲、闭合,在双向古俯冲带的前缘分别出现了陆缘增生楔,以及其后部的岛弧岩浆带。由于后期区域挤压构造事件作用,在增生楔发育的地壳强度薄弱部位发育大规模的逆冲挤压和推覆,形成祁连山北缘的榆木山逆冲推覆和飞来峰构造(图 6d)。
由于早古生代北祁连洋板块的消减而形成的祁连造山带,其南部边界为现今的柴达木盆地北缘,北部边界则为银额盆地的南缘,以银额盆地南缘断裂为界。俯冲消减的北祁连洋板块残片,包括断离板片、熔离板片和俯冲折返的板片,其累计的宽度可达~600 km;如果再把出露地表的蛇绿混杂岩累计进来,北祁连洋板块残片的宽度将远远超过~600 km,说明原特提斯北祁连洋的宽度远在~600 km之上。
在双向俯冲的大洋板片下部,大型柱状高阻电性体一直向下延伸至上地幔深部,可能具有已固化的上涌古地幔柱的构造特征,推测为早古生代北祁连洋板块在南、北两个方向上进行双向俯冲的深部动力来源;上涌地幔大致在MOHO面深度出现向北的水平底辟扩展特征,并分割了向北俯冲的原特提斯洋板片。在剖面南部的柴达木地块与南祁连造山带交接部位,同样存在古老的地幔物质上涌构造残余,并在柴达木地块与南祁连造山带接触区域形成伸展变形区,但地幔上涌的规模较小,可能是该地区晚石炭世—二叠纪大陆裂谷与夭折了的宗务隆有限洋盆形成演化的深部记录。
6.2 构造变形与构造演化
祁连造山带经历了早古生代原特提斯洋发育以来的构造演化,是青藏高原东北缘高原隆升与扩展的关键构造带。综合研究表明,祁连造山带可能经历了以下多个阶段的构造演化(图 7)。
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图 7 祁连造山带及周缘新元古代以来构造演化模式Figure 7. Tectonic evolution of the Qilian Orogenic Belt since Neo-Proterozoic(1)北祁连洋扩张与被动大陆边缘的形成(1000~520 Ma):在经历中元古代罗迪尼亚(Rodinia)超大陆的裂解(~1.5 Ga; Wang et al., 2016)之后,祁连山地区又经历了新元古代大洋俯冲、大陆碰撞与裂解等过程(杨经绥等,2009;夏林圻等,2016;Wu et al., 2016, 2017;Zuza et al., 2017)。新元古代以来,伴随着北祁连洋的扩张,形成了柴达木—祁连地块与阿拉善地块之间的原特提斯洋,其两侧发育被动大陆边缘。前奥陶纪时期,南祁连与中祁连—陇西地块和柴达木地块可能具有相同的地壳结构形式和物质组成特点(Song et al., 2013),属于同一个大陆板块;或者,柴达木地块与祁连造山带之间存在短暂的柴北缘洋。阿拉善地块构成古亚洲洋与特提斯洋两大构造域之间的分界,它既是原特提斯洋的北岸,又是古亚洲洋的南岸。
(2)北祁连洋俯冲、关闭与碰撞造山(520~407 Ma):早古生代,祁连山地区经历了原特提斯洋(北祁连洋)弧盆系的形成演化与大洋俯冲、大陆俯冲和碰撞造山等过程(Gehrels et al., 2003a, b; Xiao et al., 2009; 杨经绥等, 2009, 2010;Song et al., 2014;潘桂棠、肖庆辉,2015;夏林圻等,2016;白建科等,2016;Wu et al., 2016, 2017;李冰等,2017; Li et al., 2018)。原特提斯洋构造域北祁连洋板块向南和向北进行双向俯冲,在北祁连洋的北侧形成走廊南山岛弧和阿拉善南缘(北大山—大青山)早古生代岩浆弧,在南侧则形成中祁连岩浆弧(黄增保等,2015)和南祁连岩浆弧(大陆弧;朱小辉等,2016)。此时,北祁连造山带肃南地区的下奥陶统沉积物源主要来自于其南侧的中祁连地块,也有少量来源于北部的北祁连岛弧等(李猛等,2015)。柴北缘和北祁连的高压超高压(HP-UHP)变质作用同时形成,洋壳变质榴辉岩的年龄集中在470~460 Ma(Yang et al., 2002; Song et al., 2013, 2014; Zhang et al., 2017)。原特提斯(北祁连)洋板块向南和向北两个方向上的双向俯冲模式,可以较好地解释深地震反射、大地电磁测深等深部探测地球物理资料和该地区花岗岩类侵入岩体的分布特征。
(3)陆内造山、弧后伸展与宗务隆有限洋盆(407~240 Ma):祁连山造山带和华北克拉通之间的碰撞使混杂堆积上冲到华北克拉通的被动大陆边缘地层之上。早泥盆世,祁连山地区广泛发育磨拉石建造;晚泥盆世进入后造山的伸展垮塌阶段(孙廷贵等,2004;吴才来等,2004;杨超等,2010;夏林圻等,2016)。至石炭纪,祁连山及周缘继续处于区域性伸展环境,形成宗务隆有限洋盆(郝国杰等,2004;孙娇鹏等,2014),可能是古特提斯洋(Gehrels et al., 2011)北部的一个分支。早二叠世(~276 Ma),古亚洲洋构造域南缘和阿拉善地块普遍发育与陆内伸展有关的基性岩墙群(Zhang et al., 2017)。河西走廊北侧大青山—北大山一带晚石炭世—早三叠世时期的岩浆侵入活动,可能与古亚洲洋南缘的边缘海在此关闭及洋壳俯冲的过程有关。晚二叠世—早三叠世以来,祁连山地区处在古特提斯洋向北俯冲形成的东昆仑—柴达木—西秦岭岩浆弧地体的北侧(Chen et al., 2015),构成东昆仑—柴达木—祁连—西秦岭地块的一部分。
(4)古特提斯洋的关闭、陆内伸展与早白垩世构造挤压(240~65 Ma):受古特提斯洋关闭的影响,祁连造山带及周缘普遍发育印支期挤压构造变形(Chen et al., 2015; Li et al., 2017)。祁连造山带内部发育的三叠纪盆地沉积,记录了印支期构造挤压事件。之后的晚三叠世晚期与早、中侏罗世,祁连造山带和柴达木盆地等地区整体处于伸展构造环境(郭召杰等,1998;金之钧等,1999;戴俊生等,2000;汤良杰等,2000;罗金海等,2001;曾联波等, 2001, 2002;Chen et al., 2003; Yin et al., 2008;陈宣华等,2010)。
在中国东部广泛发育的燕山运动(~165 Ma)与中国西部印度—亚洲大陆碰撞事件(~55 Ma;Yin and Harrison, 2000)之间,河西走廊北部地区曾发生了一次早白垩世早期的南北向构造挤压事件,可能是中特提斯洋关闭事件(或称之为基梅里运动,即班公湖—怒江洋俯冲和关闭事件)及其远程效应的具体表现。早白垩世构造挤压导致祁连造山带内部及周缘早白垩世大量类前陆盆地(如平山湖盆地;邵浩浩等,2019)的形成,祁连山北缘断裂等继续活动,形成榆木山逆冲推覆和飞来峰构造(陈宣华等,2019a)。祁连山北缘及榆木山飞来峰之下掩伏有早白垩世早期的沉积盆地,是油气与水资源勘查的重要远景区(潘宏勋等,2000;陈宣华等,2019a)。早白垩世晚期普遍发育的伸展作用和伸展断陷盆地的形成(Chen et al., 2003;陈宣华等,2019a),改造了榆木山逆冲推覆构造及其逆掩断层之下的白垩系褶皱构造;白垩纪中期则是北祁连和酒西盆地等烃类形成的主要时期。早白垩世早期的构造挤压,是先于新生代青藏高原整体形成的一次高原雏形形成事件,具有重要的大陆动力学和大地构造意义。
(5)印度—亚洲碰撞远程效应(65~0 Ma):新生代在印度板块与欧亚大陆碰撞造山(始于~55 Ma)的大规模挤压构造背景下,柴达木地区发育大型压陷盆地(E2-Qp;Yin and Harrison, 2000; Yin et al., 2002; 陈宣华等,2010)。在祁连造山带,新生代陆内造山作用强烈,发育逆冲断裂作用(Wu et al., 2016;Zuza et al., 2016, 2017, 2019; Li Bing et al., 2019; 陈宣华等,2019a),具有复杂的造山带地壳结构和深部过程(Wang et al., 2011; Gao et al., 2013; 赵文津等,2014;Ye et al., 2015, 2016;陈宣华等,2019a)。祁连造山带复杂的逆冲断裂作用使得老的南倾俯冲带再次活动,在被动大陆边缘地层与基底之间产生新的滑脱构造,新生代逆冲作用使得蛇绿混杂岩带在造山带的不同部位重复出现,分割了原来作为整体的北祁连洋板块南、北两个俯冲造山带。中新世冷却历史(20~10 Ma)记录了北祁连造山带最初的剥露作用,与青藏高原—塔里木地区普遍的新生代隆升与剥露历史相一致(George et al., 2001)。
7. 结论
本文通过超宽频大地电磁测深剖面给出的全地壳深部结构特征,结合区域地质调查与构造解析,初步分析了青藏高原东北部祁连造山带深部地壳结构与构造变形特征,在前人基础上,进一步建立了区域构造演化模型,得到以下结论:
(1)超宽频大地电磁测深(MT)剖面的浅层反演与构造解释,揭示了祁连造山带盆山结构特征。祁连山北缘发育榆木山逆冲推覆构造和飞来峰,使得早白垩世沉积盆地被逆冲推覆体所掩埋,具有油气勘查的前景。构造解析表明,榆木山逆冲推覆构造的发育可能在早白垩世的早期,并受到中新世以来印度—亚洲大陆碰撞远程效应引起的挤压构造变形的影响。
(2)MT剖面中深层反演显示,早古生代(原特提斯)北祁连洋板块具有向南和向北双向俯冲的化石俯冲带深部结构特征。中、南祁连之下的北祁连洋板块具有向南在柴达木—祁连地块之下低角度俯冲的深部结构特征,其俯冲断离的板片至少可以达到现今柴达木盆地北缘的位置。在祁连山北侧,北祁连洋板块向北的俯冲作用产状较陡,而其俯冲断离的板片甚至发生了产状倒转。中生代以来的构造挤压变形可能是其发生北翼倒转的背形褶皱作用的原因。
(3)深部结构特征显示,由于早古生代北祁连洋板块的消减而形成的祁连造山带,其南部边界为现今的柴达木盆地北缘,北部边界则为银额盆地的南缘,以银额盆地南缘断裂为界。通过俯冲消减的北祁连洋板块残片,计算得到原特提斯北祁连洋的宽度约600 km之上。
致谢: 本文参加野外地质调查工作的还有徐盛林、张垚垚、王永超、邵浩浩、陈泓旭、韩建恩、史建杰、李江瑜、苗慧心、李杰、王洛娟、贺承广、韩乐乐、秦翔、余苇、丁伟翠、王叶、马飞宙、周琦等,研究工作得到中国地质调查局西北项目办和甘肃省张掖丹霞国家地质公园等的大力支持与帮助,东方地球物理公司综合物化探处协助完成QLAL-2017MT大地电磁剖面数据采集与资料处理,笔者在此一并表示衷心感谢。 -
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图 1 亚洲构造简图(据任纪舜等,2013;陈宣华等, 2017, 2019b简化修改)
图中给出古亚洲洋构造域、西太平洋构造域和特提斯构造域的大致范围、主要克拉通和一些主要的大型断裂,以及图 2和图 3的位置
Figure 1. Sketch tectonic map of Asia (modified from Ren Jishun et al., 2013; Chen Xuanhua et al., 2017, 2019b)
The map shows general ranges of the Paleo-Asian Ocean, the Western Pacific and the Tethyan tectonic domains, the main cratons and some major large-scale faults, as well as the locations of Fig. 2 and Fig. 3
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图 2 中国西北及周边地区断裂构造体系略图(据陈宣华等,2019a修改)
TSFS—天山走滑断裂系统;ATF—阿尔金断裂;CZF—成吉斯—准噶尔断裂;KLF—昆仑断裂;CHF—车尔臣河断裂;SQDF—柴达木南缘断裂;NQDF—柴达木北缘断裂;NQLF—祁连山北缘断裂;HYF—海原断裂;图中给出超宽频大地电磁测深剖面(QLAL-2017MT)的位置
Figure 2. Sketch map of the fault system of Northwest China and surrounding areas (modified from Chen Xuanhua et al., 2019a)
TSFS- Tianshan strike-slip fault system; ATF- Altun Fault; CZF- Chingiz-Junggar Fault; KLF-Kunlun Fault; CHF- Cheerchen Fault; SQDF- South Qaidam Fault; NQDF- North Qaidam Fault; NQLF- North Qilian Fault; HYF- Haiyuan Fault. The location of super-broadband magnetotelluric sounding profile (QLAL-2017MT) is shown in Fig. 2
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图 3 祁连造山带及周缘断裂构造体系略图
SQLOB—南祁连造山带;CQLB—中祁连地块;NQLOB—北祁连造山带;ATF—阿尔金断裂;KLF—昆仑断裂;NQDF—柴达木盆地北缘断裂;SDNF—党河南山南缘断裂;TDF—土尔根达坂断裂;NZF—北宗务隆山断裂;SQHF—青海南山断裂;SCQLF—中祁连南缘断裂;NCQLF—中祁连北缘断裂;SYNF—野牛沟南缘断裂;CMF—昌马—俄博断裂;NQLF—祁连山北缘断裂;HYF—海原断裂;TJF—天景山断裂;WQF—温泉断裂;RYF—日月山断裂;GHF—共和断裂;LSF—龙首山断裂;JTF—金塔断裂;AYF—阿拉善右旗断裂;YBF—雅布赖断裂;EGF—恩格尔乌苏南缘断裂;SYEF—银额盆地南缘断裂。图中给出超宽频大地电磁测深剖面(QLAL-2017MT)的位置
Figure 3. Sketch map of the fault system of the Qilian Mountain Orogenic Belt and its adjacent areas
SQLOB-South Qilian Orogenic Belt; CQLB-Central Qilian Block; NQLOB-North Qilian Orogenic Belt. ATF-Altun Fault; KLF-Kunlun Fault; NQDF-North Qaidam Fault; SDNF-South Danghe Nan Shan Fault; TDF-Tuergendaban Fault; NZF-North Zongwulong Shan Fault; SQHF- South Qinghai Fault; SCQLF-South Central Qilian Fault; NCQLF-North Central Qilian Fault; SYNF-South Yeniugou Fault; CMF- Changma-Ebo Fault; NQLF-North Qilian Fault; HYF- Haiyuan Fault; TJF-Tianjingshan Fault; WQF-Wenquan Fault; RYF-Riyueshan Fault; GHF- Gonghe Fault; LSFLongshoushan Fault; JTF- Jinta Fault; AYF-Alxa Right Banner Fault; YBF- Yabulai Fault; EGF-South Engeerwusu Fault; SYEF-South Yin' e Fault. The location of super-broadband magnetotelluric
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图 4 祁连山及周缘地球物理场异常及其与断裂构造体系的关系
a—剩余重力异常及其与断裂构造体系的关系,剩余重力异常据冯治汉等(2018);b—航磁∆T场化极垂向一阶导数异常及其与断裂构造体系的关系,航磁∆T场化极垂向一阶导数异常据熊盛青等(2015);ALB—阿拉善地块;NQLOB—北祁连造山带;CQLB—中祁连地块;SQLOB—南祁连造山带;QDB—柴达木地块;DHB—敦煌地块
Figure 4. Sketch maps showing the relationships between the geophysical field anomalies and the fault system in the Qilian Mountain and surrounding areas
a-Residual gravity anomaly (after Feng Zhihan et al., 2018) and its relationship with fault system; b-First vertical derivative anomaly of the aeromagnetic ∆T field polarization (after Xiong Shengqing et al., 2015) and its relationship with fault system; ALB-Alxa Block; NQLOB-North Qilian Orogenic Belt; CQLB- Central Qilian Block; SQLOB-South Qilian Orogenic Belt; QDB-Qaidam Block; DHB-Dunhuang Block
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图 5 大地电磁测深剖面(QLAL-2017MT)静态位移及静校正对比图
Figure 5. Comparison of static migration and static correction of magnetotelluric sounding profile (QLAL-2017MT)
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图 6 大地电磁测深反演剖面(QLAL-2017MT)的构造解释
a—共轭梯度法浅层反演剖面;b—浅层反演剖面的构造解释;c—共轭梯度法中—深层反演剖面;d—中—深层反演剖面的构造解释;断裂名称:NQDF—柴达木盆地北缘断裂;NZF—北宗务隆山断裂;NTJF—天峻盆地北缘断裂;SCQLF—中祁连南缘断裂;NMLF—木里盆地北缘断裂;NCQLF—中祁连北缘断裂;SYNF—野牛沟南缘断裂;CMF-昌马—俄博断裂;NQLF—祁连山北缘断裂;YN—榆木山逆冲推覆构造;NYMF—榆木山北缘断裂;LSF—龙首山断裂;JTF—金塔断裂;SYEF—银额盆地南缘断裂;Gr—花岗岩
Figure 6. Structural geological explanation of magnetotelluric sounding profile (QLAL-2017MT)
a-Inversion profile of shallow layers using conjugate gradient method; b-Structural interpretation of inversion profile of shallow layers; c-Inversion profile of middle to deep layers using conjugate gradient method; d-Tectonic interpretation of inversion profile of middle to deep layers. Fault names: NQDF-North Qaidam Fault; NZF- North Zongwulong Shan Fault; NTJF-North Tianjun Fault; SCQLF-South Central Qilian Fault; NMLF-North Muli Fault; NCQLF-North Central Qilian Fault; SYNF-South Yeniugou Fault; CMF-Changma-Ebo Fault; NQLF-North Qilian Fault; YN-Yumushan Nappe; NYMF-North Yumushan Fault; LSF-Longshoushan Fault; JTF- Jinta Fault; SYEF-South Yin' e Fault; Gr-Granite
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