龙门山南段前陆大川-丹棱剖面磁组构特征及其构造意义

龙门山南段前陆盆地作为龙门山构造带南段盆-山耦合关系的具体响应,其中-新生代沉积地层的构造变形特征和叠加改造关系在一定程度上反映了龙门山构造带南段的形成与演化。本文基于横跨龙门山南段前陆的大川-丹棱剖面,通过野外构造解析和岩石磁组构特征,对前陆构造变形开展精细研究。构造解析揭示,剖面上发育一系列与双石断裂带走向近平行的宽缓褶皱和浅层逆冲断层,褶皱表现为北西翼较缓,而南东翼相对较陡,轴面略向NW倾的不对称特征。磁组构特征揭示,剖面中岩石具低磁化率和典型的沉积岩三轴磁化率椭球体的特征,磁化率椭球体以扁圆形为主,整体反映出弱变形的特征,与褶皱作用前的平行层缩短(LPS)相关;最大磁化率主轴(K_max)优势方位为NE-SW向,与龙门山构造带走向平行,主要反映了NW-SE向挤压作用。剖面还发育有磁面理与地层层面斜交、磁线理与地层走向斜交两类非典型磁组构,前者是褶皱作用中层间平行简单剪切的产物,后者则是构造叠加的产物。通过磁组构反映的应变分析结果,厘定出龙门山南段前陆中生代晚期主要受到NW-SE向挤压,与新生代的挤压应力方向呈小角度斜交,且挤压作用所产生的透入性应变到达了熊坡...     

川西地区龙门山前陆地层磁组构与应力研究

四川盆地紧邻龙门山冲断带,研究盆地西部新生代变形,对进一步认识和理解青藏高原隆升具有一定的科学意义。磁化率各向异性对地层应力状态变化非常灵敏。在雅安地区飞仙关镇附近选取9个采点进行岩石磁组构分析,探讨四川盆地西部岩石的构造变形特征。磁组构分析显示出样品具有沉积磁组构和初始变形磁组构特征。磁线理为NE-SW向,与区域褶皱轴方向一致,表明龙门山控制了四川盆地西部的构造变形,并且研究显示该变形发生在新生代。     

川西北磁组构演化及其揭示的应变特征

对龙门山褶皱冲断带北段前锋带至四川盆地边缘的川西北地区进行了磁组构研究.在江油和广元之间,沿着垂直于龙门山构造走向的4条采样路线,在18个采样点钻取了173个定向样品,样品采自侏罗纪和白垩纪砂岩及粉砂质泥岩.综合分析表明川西北磁组构反映的是新生代的变形,并在研究区域内总结出了3类磁组构:沉积磁组构、初始变形磁组构和铅笔状磁组构.除沉积磁组构之外的所有采样点样品的K1优势方向都是NE-SW向,说明研究区域的最大主压应力方向为NW-SE向,主要来源于龙门山褶皱冲断带.在垂直于龙门山褶皱冲断带构造走向上,从四川盆地到龙门山前锋,磁组构由沉积磁组构逐渐变为初始变形磁组构,直至铅笔状磁组构,说明盆地内部应变十分微弱,靠近造山带应变逐渐增强,且侏罗纪、白垩纪以来研究区的构造变形主要集中在造山带边缘或者还未传递到盆地内部.     

龙门山冲断带北段前锋带新生代构造变形

龙门山北段前锋构造的地震剖面解释和前缘盆地内沉积地层的磁组构研究表明前锋构造中发育两期构造挤压作用,即整体强烈的晚三叠世变形和由北向南逐渐减弱的弱新生代构造变形。受这两期构造挤压作用的控制,龙门山北段前锋构造中发育上、下两套构造层,地表构造为晚三叠世时期形成,而深部隐伏构造则形成于新生代。北部的矿山梁和天井山构造几何学上表现为一个双重构造,浅层是一个晚三叠世形成的断层转折褶皱;深层是新生代形成的多个逆冲岩片叠置所构成的隐伏堆垛背斜;南部的青林口和中坝构造主体表现为叠瓦状逆冲,前锋构造是断层转折褶皱和断层传播褶皱。新生代构造冲断位移量以及造成早期构造抬升由北向南逐渐减小,反映新生代变形强度由北向南的减弱。磁组构研究表明新生代变形从龙门山冲断带边缘到盆地内部,磁组构从铅笔状磁组构到初始变形磁组构并逐渐过渡到沉积磁组构。由南向北磁组构由初始变形磁组构转变为铅笔状磁组构,说明应变越来越强,从而进一步证明了龙门山前锋新生代构造的弱变形作用和变形强度的北强南弱分布特征。     

龙门山南段邛西断层转折褶皱磁组构及其有限应变

龙门山南段位于四川盆地以西,其新生代构造变形特征对于认识青藏高原东缘的变形机制具有一定的指示意义。磁组构是一种灵敏的应变指示计,在变形微弱的沉积岩地区尤为适用。在龙门山南段邛西断层转折褶皱不同构造部位选取48个采样点开展磁组构研究,分析断层转折褶皱的有限应变特征及区域构造变形机制。实验结果表明,邛西地区上白垩统中主要载磁矿物为高矫顽力的赤铁矿,背斜整体应变较弱,且存在3种类型的磁组构,以沉积磁组构和初始变形磁组构为主,铅笔状磁组构少见,主要存在于靠近褶皱中段的前翼部位,说明断层转折褶皱前翼较后翼和核部应变强,且中段地层应变较其他部位更为强烈。此外,各采样点磁线理的优势方位为近南北向（N10°E）,表明邛西断层转折褶皱的形成与龙门山南段晚新生代近东西向的地壳水平缩短有关,暗示龙门山南段的最大主压应力方向在晚新生代存在转变的可能。     

龙门山南段邛西断层转折褶皱磁组构及其有限应变

龙门山南段位于四川盆地以西,其新生代构造变形特征对于认识青藏高原东缘的变形机制具有一定的指示意义。磁组构是一种灵敏的应变指示计,在变形微弱的沉积岩地区尤为适用。在龙门山南段邛西断层转折褶皱不同构造部位选取48个采样点开展磁组构研究,分析断层转折褶皱的有限应变特征及区域构造变形机制。实验结果表明,邛西地区上白垩统中主要载磁矿物为高矫顽力的赤铁矿,背斜整体应变较弱,且存在3种类型的磁组构,以沉积磁组构和初始变形磁组构为主,铅笔状磁组构少见,主要存在于靠近褶皱中段的前翼部位,说明断层转折褶皱前翼较后翼和核部应变强,且中段地层应变较其他部位更为强烈。此外,各采样点磁线理的优势方位为近南北向(N10°E),表明邛西断层转折褶皱的形成与龙门山南段晚新生代近东西向的地壳水平缩短有关,暗示龙门山南段的最大主压应力方向在晚新生代存在转变的可能。     

桂东北地区鹰扬关韧性剪切带的厘定及其构造意义

论文通过宏-微观构造、磁组构、热液锆石和石英EBSD组构等,厘定鹰扬关韧性剪切带并讨论其构造意义。鹰扬关韧性剪切带具有宏-微观韧性变形组构,发育糜棱岩、拉伸线理、S-C组构、旋转碎斑系、书斜构造、压力影和石英的动态重结晶等。磁组构和宏-微观构造表明,鹰扬关韧性剪切带呈NNE向延伸超过40 km,宽2.5～8 km。糜棱C面理的极密点产状127°∠50°;磁面理的极密点产状107°∠83°。宏-微观构造研究表明,鹰扬关韧性剪切带具有早期左旋逆冲剪切,晚期右旋正滑剪切的运动学性质。石英EBSD组构表明,鹰扬关韧性剪切带具有晚期中低温变形(400～550℃)叠加于早期中高温变形(550～650℃)的特征。年代学研究表明,鹰扬关韧性剪切带早期左旋逆冲剪切的时代为(441.1±2.3)Ma,晚期右旋正滑剪切的时代应晚于420 Ma,区域构造应力由挤压转为伸展的时限为420 Ma。在磁组构、石英EBSD组构和热液锆石定年的基础上,结合区域地质资料,认为鹰扬关韧性剪切带形成于华夏陆块自SE向扬子陆块造山挤压的构造背景。早期造山挤压,产生压扁型应变和中高温左旋逆冲剪切;晚期造山后伸展,产生拉伸型应变和...     

皖南地区汤口断裂带磁组构特征及地质意义

断裂带的区域构造应力特征是研究其活动性的重要依据。在应变指示较少的地区,磁组构是研究区域构造应力的有效手段。在安徽1∶5万后山幅区域地质调查的基础上,对汤口断裂带进行系统的岩石磁组构特征研究。结果表明:该断裂带沉积地层的磁性矿物以磁铁矿为主,岩石磁化率椭球体以"扁球形"为主,显示其在原生沉积组构的基础上叠加了弱变形组构。磁化率椭球体的最大轴Kmax沿NEE-SWW向、最小轴Kmin沿NNWSEE向,反映汤口断裂带晚期受NNW-SEE向的挤压应力,兼较弱的NEE-SWW向拉张应力作用,说明喜山期汤口断裂带为近EW向正断拉张,兼具左行平移,时限为中新世—早更新世。     

河南西南部典型白垩纪剖面的岩石磁组构特征及其构造意义

对河南西南部西峡盆地阳城-丹水上白垩统岩石磁学、磁组构的研究表明,该陆相沉积地层磁性矿物以及特征剩磁载体以赤铁矿为主,并含少量磁铁矿,且磁铁矿与赤铁矿相对含量比例随剖面由老到新显示出逐渐增加的趋势。岩石磁组构主要受顺磁性矿物以及反铁磁性矿物的控制。全剖面磁化率椭球结果显示在原生沉积组构基础上叠加了最早期阶段的弱变形组构;同时,全剖面以及各岩石地层单元磁化率椭球体主轴方向的变化揭示了两个不同方向及大小的构造挤压作用导致磁化率最大轴从NNW-SSE向转至NW-SE向,后又到NNW-SSE向的变化模式,一方面是由于华南、华北板块NE-SW向的构造挤压导致;另一方面是由两板块构造挤压而引起的桐柏-大别造山带上地壳物质相对下地壳发生东向构造逃逸和挤出过程中与东部块体物质间发生的挤压作用引起,这两种不同的挤压应力作用在盆地发展的不同阶段各占主要地位。     

米仓山与龙门山结合部构造分带性特征

通过褶劈理化、叠加变形、褶皱和破裂等构造发育强度、构造形迹、岩性地层单元等研究认为,米仓山与龙门山结合部具有明显的构造分带性,从北往南构造变形强度逐渐减弱,大致可分为四个构造带。这种分带变形特征是由于秦岭、龙门山、米仓山不同时期综合作用的结果,并主要受秦岭构造带控制,往南受龙门山和米仓山构造的改造和限制作用,变形强度逐渐减弱,形成分带性特征。     

米仓山隆升时代的沉积学制约

米仓山地区位处上扬子北缘,既是四川盆地的北部边界,又是龙门山、秦岭造山带与四川盆地三者之间的盆山转换地带,是探讨秦岭造山带—上扬子北缘中生代构造演化的重要地区,其隆升时代关系到四川盆地的时空边界与区域构造演化格局。通过米仓山南、北两侧侏罗纪地层沉积层序的详细对比,可以确定米仓山侏罗纪古地理地貌与隆起特点。本研究在米仓山南侧分别选取旺苍白水镇、南江赶场镇2条侏罗系剖面进行实测和研究,并实测米仓山北侧西乡堰口侏罗系剖面。通过3条侏罗系剖面的沉积建造、层序地层特点对比分析表明,米仓山南北两侧侏罗系总体具有一定的可对比性,尤其是南北两侧下侏罗—中侏罗统下段沉积层序基本相同。这种沉积建造的可对比性表明,米仓山隆升时代至少始于中侏罗世晚期。     

Magnetic fabric of Pleistocene continental clays from the hanging-wall of an active low-angle normal fault (Altotiberina Fault,Italy)

Anisotropy of magnetic susceptibility (AMS) represents a valuable proxy able to detect subtle strain effects in very weakly deformed sediments. In compressive tectonic settings, the magnetic lineation is commonly parallel to fold axes, thrust faults, and local bedding strike, while in extensional regimes, it is perpendicular to normal faults and parallel to bedding dip directions. The Altotiberina Fault (ATF) in the northern Apennines (Italy) is a Plio-Quaternary NNW–SSE low-angle normal fault; the sedimentary basin (Tiber basin) at its hanging-wall is infilled with a syn-tectonic, sandy-clayey continental succession. We measured the AMS of apparently undeformed sandy clays sampled at 12 sites within the Tiber basin. The anisotropy parameters suggest that a primary sedimentary fabric has been overprinted by an incipient tectonic fabric. The magnetic lineation is well developed at all sites, and at the sites from the western sector of the basin it is oriented sub-perpendicular to the trend of the ATF, suggesting that it may be related to extensional strain. Conversely, the magnetic lineation of the sites from the eastern sector has a prevailing N–S direction. The occurrence of triaxial to prolate AMS ellipsoids and sub-horizontal magnetic lineations suggests that a maximum horizontal shortening along an E–W direction occurred at these sites. The presence of compressive AMS features at the hanging-wall of the ATF can be explained by the presence of gently N–S-trending local folds (hardly visible in the field) formed by either passive accommodation above an undulated fault plane, or rollover mechanism along antithetic faults. The long-lasting debate on the extensional versus compressive Plio-Quaternary tectonics of the Apennines orogenic belt should now be revised taking into account the importance of compressive structures related to local effects.     

A tectonic origin of magnetic fabric in the Shemshak Group from Alborz Mts. (northern Iran)

The magnetic lineation observed in “undeformed” sedimentary units has been interpreted either as an indication of paleoflow direction, or as a result of tectonic overprint which progressively modifies the original sedimentary fabric related to compactional processes. Distinguishing between the two processes is not always easy. In fact, most studies of the Anistropy of Magnetic Susceptibility (AMS) of “undeformed” sequences have been carried out in fine-grained sediments from foredeep sequences, which are characterized by sedimentary flow directions which are almost parallel to the main deformation structures, like thrust faults and folds. In the Alborz Mts., the Upper Triassic–Lower Jurassic Shemshak Group was deposited in a foreland to molassic basin of the Eo-Cimmerian orogen and now outcrops in several folds which are oriented parallel to the curved chain. Paleoflow directions are generally oblique to the main tectonic structures, being directed SSW to SSE and showing negligible changes in their orientation along the Alborz Mountains. We have, therefore, the opportunity to distinguish between tectonic- or sedimentary-related origins of the magnetic lineation. The AMS results show that magnetic lineations of the Shemshak Group are oriented almost parallel to the main fold axes and thrust structures, which follow the Alborz Mts. curved trend, suggesting that magnetic lineation is of tectonic origin in fine to medium grained, mostly massive sandstones, and confirming that AMS is a valuable tool to study deformation processes in sedimentary rocks.     

Evaluating magnetic lineations (AMS) in deformed rocks

Magnetic lineation in rocks is given by a cluster of the principal axes of maximum susceptibility (K_max) of the Anisotropy of Magnetic Susceptibility (AMS) tensor. In deformed rocks, magnetic lineations are generally considered to be the result of either bedding and cleavage intersection or they parallel the tectonic extension direction in high strain zones. Our AMS determinations, based on a variety of samples that were taken from mudstones, slates and schists from the Pyrenees and Appalachians, show that strain is not the only factor controlling the development of magnetic lineation. We find that the development and extent to which the magnetic lineation parallels the tectonic extension direction depends on both the original AMS tensor, which in turn depends on the lithology, and the deformation intensity. Rocks having a weak pre-deformational fabric will develop magnetic lineations that more readily will track the tectonic extension.     

四川类前陆盆地须家河组震积岩的发现及其研究意义

四川盆地是扬子地块上的一个多旋回类前陆盆地,盆地边缘长期剧烈的构造活动控制着上三叠统须家河组的沉积作用。通过地表剖面和岩芯观察,首次在该盆地上三叠统须家河组地层中识别出微裂缝、微褶皱层、[JP2]微断层、液化砂岩构造、球—枕构造和角砾岩等典型的软沉积变形构造的地质记录,这些变形构造可能与印支构造运动期的地震活动有关。越靠近断裂带附近,软变形构造呈明显增加的趋势,表明震积岩的分布与龙门山和米仓山—大巴山构造活动有关。因此,研究该盆地须家河组震积岩,对了解控制盆地边界的龙门山和米仓山—大巴山造山带的活动史具有重要意义。     

Magnetic fabric study of the SE Rhenohercynian Zone (Bohemian Massif): Implications for dynamics of the Paleozoic accretionary wedge

The progressive deformation recorded in the magnetic fabric of sedimentary rocks was studied in the SE Rhenohercynian Zone (RHZ), eastern margin of the Bohemian Massif, Czech Republic. Almost 800 oriented samples of the Lower Carboniferous mudstones and graywackes were collected from the SSE part of the Czech RHZ, so-called the Drahany Upland. The anisotropy of magnetic susceptibility (AMS) is predominantly controlled by the preferred orientation of paramagnetic phyllosilicates, mainly iron-bearing chlorites. A regional distribution of the magnetic fabric within the Drahany Upland revealed an increasing deformation from the SSE to the NNW. In the SE, the magnetic fabric is bedding-parallel with magnetic lineation scattered in the bedding plane or trending N–S to NNE–SSW. Further to the NW, the magnetic foliation rotates from the bedding-parallel orientation to the orientation parallel to the evolving cleavage. This rotation is accompanied by a decrease of the anisotropy degree and the prolate nature of the anisotropy ellipsoids. The magnetic lineation is parallel to the strike of the bedding, bedding/cleavage intersection, pencil structure or the fold axes on a regional scale. In the NW part of the Drahany Upland, the magnetic foliation becomes parallel to the cleavage accompanied by an increase of the anisotropy degree and the oblate nature of the anisotropy ellipsoids. The increasing trend of deformation corresponds to the SSE–NNW increase in the degree of anchimetamorphism; both trends being oblique to the main lithostratigraphic formations as typically observed in the sedimentary rocks of the accretionary wedges. The SSE–NNW increase in deformation and anchimetamorphism continues to the Nízký Jeseník Mts., representing the northern part of the same accretionary wedge. The kinematics of deformation could not be unambiguously assessed. The observed magnetic fabric may reflect either lateral shortening or horizontal simple shear or a combination of both mechanisms. Regarding the subduction process, it seems that the sedimentary sequences of the Drahany Upland were subducted, partly offscraped and accreted frontally or partly underplated as opposed to the Nízký Jeseník Mts. where some return flow must have occurred.     

四川含油气叠合盆地基本特征

随着近年来四川盆地油气勘探的不断突破,重新审视其基本地质特征和油气成藏特点变得迫切而必要.四川盆地是典型的叠合盆地,显生宙以来经历了震旦纪一中三叠世伸展体制下的差异升降和被动大陆边缘(海相碳酸盐岩台地)、晚三叠世-始新世挤压体制下的摺皱冲断和复合前陆盆地(陆相碎屑岩盆地)、渐新世以来的褶皱隆升改造(构造盆地)3大演化阶...     

Mesozoic extension in the Basque–Cantabrian basin (N Spain): Contributions from AMS and brittle mesostructures

In this work we analyse and check the results of anisotropy of magnetic susceptibility (AMS) by means of a comparison with palaeostress orientations obtained from the analysis of brittle mesostructures in the Cabuérniga Cretaceous basin, located in the western end of the Basque–Cantabrian basin, North Spain. The AMS data refer to 23 sites including Triassic red beds, Jurassic and Lower Cretaceous limestones, sandstones and shales. These deposits are weakly deformed, and represent the syn-rift sequence linked to basins formed during the Mesozoic and later inverted during the Pyrenean compression. The observed magnetic fabrics are typical of early stages of deformation, and show oblate, triaxial and prolate magnetic ellipsoids. The magnetic fabric seems to be related to a tectonic overprint of an original, compaction, sedimentary fabric. Most sites display a NE–SW magnetic lineation that is interpreted to represent the stretching direction of the Early Cretaceous extensional stage of the basin, without recording of the Tertiary compressional events, except for sites with compression-related cleavage.Brittle mesostructures include normal faults, calcite and quartz tension gashes and joints, related to the extensional stage. The results obtained from joints and tension gashes show a dominant N–S to NE–SW, and secondary NW–SE, extension direction. Paleostresses obtained from fault analysis (Right Dihedra and stress inversion methods) indicate NW–SE to E–W, and N–S extension direction. The results obtained from brittle mesostructures show a complex pattern resulting from the superposition of several tectonic processes during the Mesozoic, linked to the tectonic activity related to the opening of the Bay of Biscay during the Early Cretaceous. This work shows the potential in using AMS analysis in inverted basins to unravel its previous extensional history when the magnetic fabric is not expected to be modified by subsequent deformational events. Brittle mesostructure analysis seems to be more sensitive to far-field stress conditions and record longer time spans, whereas AMS records deformation on the near distance, during shorter intervals of time.     

柴达木盆地西部新生界磁组构特征及其构造意义

柴达木盆地西部狮子沟一带新生代沉积岩磁组构分析结果显示, 岩石磁组构具有磁面理发育、磁线理不发育、磁化率量值椭球呈压扁状的特点; 磁化率各向异性度P值不大, 反映总体构造变形相对较弱。岩石磁组构反映的应力状态总体为以NE向挤压为主, 与轴向NW的背斜构造发育相一致。该区岩石磁组构大多具有原始沉积磁组构特征, 磁面理产状大体上反映沉积岩层的层理, 同时也记录了受NE向挤压作用的痕迹。根据岩石磁组构与地层层理之间的关系分析, 柴西地区两翼不对称的狮子沟背斜具有断展褶皱性质, 其形成与下部的花土沟逆冲断层向南西方向的仰冲有关。