日照—连云港地区主要断裂重磁异常特征

为满足1:25万海洋区域地质调查需求,解决海陆过渡区的基础地质问题,在统一编制1:25万重力异常图和磁力异常图的基础上,分析日照—连云港地区主要断裂的重磁异常特征。结合区域地质资料,探讨郯庐断裂沂水段、桑墟—连云港断裂、东海—赣榆断裂的重磁异常特征及其地质意义。结果表明: 昌邑—大店断裂是郯庐断裂沂水段的主断裂; 作为苏鲁造山带的南部边界,桑墟—连云港断裂控制了基底、地层和岩浆岩的分布; 东海—赣榆断裂将苏鲁造山带分割为南、北2部分。这些新认识为日照—连云港地区基础地质研究提供了重要参考。     

辽宁省综合地球物理解释断裂构造的方法和依据

通过研究辽宁省布格重力异常Δg及其位场转换场、航磁ΔT异常及其位场转换场、地震波场、大地电磁场,结合地貌以及钻探等资料,综合解释出了区内断裂构造.展示出了辽宁省断裂构造平面分布特征.配合地球物理解释剖面,可以了解区内主要断裂构造的垂向发育特征.分析认为郯庐断裂带为左行走滑断层带,划分出了表壳断裂、中-下地壳断裂、超岩石圈断裂.     

冀东地区冷口断裂重磁异常特征及其地质作用

利用冀东地区1∶2．5万高精度航空磁测资料及收集的地面重力资料,阐述了冷口断裂及其两侧航磁、重力异常特征,并结合物性特征,分析了航磁、重力异常的地质成因及其对地质构造和矿产的控制作用。冷口断裂两侧航磁、重力异常特征差别十分明显,反映了两侧结晶基底、盖层和侵入岩分布规律差异较大,认为该断裂不仅控制了地质构造分布,也间接控制了矿产分布,可为地学研究和矿产勘查提供必要的地球物理依据。     

长江中下游成矿带磁异常揭示的深部构造与成矿关系

长江中下游成矿带是我国最主要的铁铜金多金属成矿带之一。本文通过高精度航磁异常数据分析成矿带内磁异常的分布特征,研究表明,火山岩盆地和郯庐断裂带沿线的正磁异常呈团块状分布,而大别造山带和九华山的正磁异常呈宽缓分布,前者与成矿带内以铁矿化为主的多金属矿床密切相关。航磁异常边界识别结果清晰揭示了郯庐断裂带、晓天-磨子潭断裂和襄樊-广济断裂等区内重要的深大断裂,九江附近的边界可能是郯庐断裂带的南延。长江中下游及邻域的居里等温面深度变化范围约为23.5~31.5km,沉积盆地下方居里等温面总体呈现拗陷,火山岩盆地下方居里等温面总体呈现隆起,郯庐断裂带沿线的居里等温面呈带状分布的隆起。大别造山带和九华山下方居里等温面呈现拗陷,有别于火山岩盆地和郯庐断裂带沿线的居里等温面隆起。长江中下游成矿带内主要的铁铜多金属矿床点集中分布在居里等温面隆起或隆起边缘部位,指示了长江中下游早白垩世剧烈的岩浆活动使区域大地热流值相对较高,地壳深部的构造格局和岩浆活动制约了浅部的成矿。     

从航空重力看郯庐断裂系(渤海)及其围区构造几何学特征

本文以我国首次试验的渤海西、南部海陆结合带航空重力测量资料为依据, 探讨了郯庐断裂在渤海西、南部海域的空间展布及其围区的构造几何学特征。研究表明, (1)渤海南部和西部两个明显的NNE向 重力异常梯级带属于区域不同重力场的分界线, 分别是郯庐断裂带东支断裂(主干断裂)和西支断裂的反映; (2)郯庐主断裂东侧主要发育NE-NNE向重力异常梯级带, 西侧呈现NW向、NE-NNE向、近EW向重力异常梯级带相互交错的面貌, 反映了东、西两侧不同的断裂构造格局; (3)重力异常小区与异常梯级带的不同组合, 反映了拉张、压缩、扭动三类构造样式; (4)不同的重力异常区、亚区、小区, 反映了不同的沉积构造特征, 分别对应不同的构造单元。     

郯庐断裂带南段的重磁场特征及其地质意义

由于断裂两侧的磁性、密度的纵横向差异在重力、磁力异常上有所表现,因此所获得的重力、磁力数据为深入研究关键的地质课题提供了科学基础,如郯庐断裂带的基底性质、断裂形成特征和岩浆岩分布。利用最新的高精度航空重力和磁力数据以及地面重力数据,绘制了郯庐断裂带地区的1∶50 000重力和磁力异常图,并结合区域地质数据分析了重力和磁力异常特征。分析结果认为:存在连体的郯庐—大别古老构造带,郯庐断裂带南段是元古宙和燕山中期岩浆活动的复合反映带;郯庐断裂带为中元古—新元古代时期南华北陆块与下扬子陆块的界限;磁力、重力异常图对比说明,合肥盆地范围由老到新向东扩展。     

基于重磁多尺度边缘检测的庐枞盆地基底构造研究

庐枞盆地位于怀宁-庐江“磁高重高”区域异常带的枞阳-庐江异常区,其区域重力场特征与区域磁场特征明显。本文利用上述特征异常,采用重磁多尺度边缘检测方法,对庐枞盆地重力和航磁数据进行了边缘检测,得到庐枞盆地不同深度的密度和磁性信息及重磁异常边界。结合重磁异常分布特点进行构造格架的推断、基底隆起区划分,建立了庐枞盆地构造格架。认为庐枞盆地基底断裂有四组方向,以北东走向断裂为主;盆地包含四块基底隆起区和一块基底残块隆起区。在此基础上,分析了庐枞盆地主要矿集区与构造格架的关系,提出了“S”形重力高异常带是寻找中深部隐伏矿床的有利部位的新认识。     

日照—连云港地区主要断裂重磁异常特征

为满足1∶25万海洋区域地质调查需求,解决海陆过渡区的基础地质问题,在统一编制1∶25万重力异常图和磁力异常图的基础上,分析日照—连云港地区主要断裂的重磁异常特征。结合区域地质资料,探讨郯庐断裂沂水段、桑墟—连云港断裂、东海—赣榆断裂的重磁异常特征及其地质意义。结果表明:昌邑—大店断裂是郯庐断裂沂水段的主断裂;作为苏鲁造山带的南部边界,桑墟—连云港断裂控制了基底、地层和岩浆岩的分布;东海—赣榆断裂将苏鲁造山带分割为南、北2部分。这些新认识为日照—连云港地区基础地质研究提供了重要参考。     

中国大陆及邻近海域航磁——大地构造解释及分区

地表地质研究及中国航磁异常表明中国航磁大地构造具以下3种类型:沉积盖层区(深浅层结果反映正常构造层序)、构造盖层区(地表及浅层为外来推覆山系,与深部构成异常构造层序)和航磁异常地质历史时期各期沉积-构造事件叠加的记录。按郯庐断裂两侧华北、扬子地台区航磁-构造异常带的可比性,郯庐断裂总位移可达500km.中国大陆及邻近海域航磁-大地构造分区为:Ⅰ光蒙区、Ⅱ华北区、Ⅲ哈萨克斯坦区、Ⅳ塔里木区、Ⅴ青藏高原区、Ⅵ扬子区、Ⅶ华夏——台湾区。     

中国大陆及邻近海域航磁─大地构造解释及分区

地表地质研究及中国航磁异常表明中国航磁大地构造具以下３种类型：沉积盖层区（深浅层结果反映正常构造层序）、构造盖层区（地表及浅层为外来推覆山系，与深部构成异常构造层序）和航磁异常地质历史时期各期沉积－构造事件叠加的记录。按郯庐断裂两侧华北、扬子地台区航磁－构造异常带的可比性，郯庐断裂总位移可达５００ｋｍ。中国大陆及邻近海域航磁－大地构造分区为：Ⅰ光蒙区、Ⅱ华北区、Ⅲ哈萨克斯坦区、Ⅳ塔里木区、Ⅴ青藏高原区、Ⅵ扬子区、Ⅶ华夏－台湾区。     

龙门山地区关口断裂形成与演化分析

根据大量野外露头剖面资料与钻井数据,系统分析了关口断裂形成过程与演化特征。认为关口断裂在印支早、中期为张性大力构造背景下形成的同沉积正断层,在晚三叠世卡尼克期为生长性正断层;印支晚期构造事件中该断裂改变为逆冲断层。关口断裂活动性较强,其中在燕山晚期活动性最强。关口断裂在喜马拉雅期有多期次的、长时期的强烈活动;并且目前仍是一条活动性的断层。     

伊通盆地断裂体系特征及其演化历史

综合利用最新的地震、航磁、钻井等资料,对伊通盆地断裂体系进行了重新认识,并对断裂演化及其油气成藏的控制作用进行了综合分析.伊通盆地主要是受西北缘走滑断裂控制的新生代走滑-伸展盆地;断裂的性质、特征及演化极其复杂,按断裂特征及规模可划分为3个级别.一级断裂为西北缘和东南缘控盆边界断裂;二级断裂为早期张扭作用形成的呈雁列展布的马鞍山断裂,2号、3号、4号断裂和晚期压扭作用形成的西北缘逆冲断裂;三级断裂为盆地演化过程中形成的众多次级断裂.伊通盆地断裂演化特征与太平洋板块的俯冲作用、印度板块和欧亚大陆碰撞作用以及盆缘大黑山地垒和那丹哈达岭地体挤压位置与隆升强度密切相关,断裂演化经历了古近纪成盆期的右旋张扭作用阶段和新近纪反转期的右旋压扭及基底隆升作用阶段;新近纪反转期压扭作用形成的西北缘断褶带具有良好的油气勘探潜力.     

Fault-Growth Pattern of the South Margin Normal Fault of the Yuguang Basin in Northwest Beijing and its Influencing Factors

Based on high-resolution remote sensing image interpretation, digital elevation model 3-D analysis, field geologic field investigation, trenching engineering, and ground-penetrating radar, synthetic research on the evolution of the Yuguang Basin South Margin Fault (YBSMF) in northwest Beijing was carried out. We found that the propagation and growth of faults most often occurred often at two locations: the fault overlapping zone and the uneven or rough fault segment. Through detailed observation and analysis of all cropouts of faults along the YBSMF from zone a to zone i, we identified three major factors that dominate or affect fault propagation and growth. First, the irregularity of fault geometry determine the propagation and growth of the fault, and therefore, the faults always propagate and grow at such irregular fault segments. The fault finally cuts off and eliminates its irregularity, making the fault geometry and fault plane smoother than before, which contributes to the slipping movement of the half-graben block in the basin. Second, the scale of the irregularity of the fault geometry affects the result of fault propagation and growth, that is, the degree of the cutting off of fault irregularity. The degree of cutting off decreases as irregularity scale increases. Third, the maximum possible slip displacement of the fault segment influences the duration of fault propagation and growth. The duration at the central segments with a large slip displacement is longer than that at the end segments with a smaller slippage value.     

走滑断层研究进展及启示

自走滑断层概念提出之后,走滑断层在地质科学研究上的重要性逐渐体现出来,并在几何学、运动学、动力学及其构造意义等方面取得了重要的认识,使得走滑断层的研究得到快速的发展,但其分类及其成因机制分析还存在一定的局限性。在走滑断层相关文献调研的基础上,文章对走滑断层原理、概念和相关术语发展历程进行了归纳总结,同时也对走滑断层的位移特征、识别标志、力学性质、走滑派生或伴生构造、走滑盆地特征、走滑断层分类及走滑断层实例等研究成果进行了系统性研究分析。在此基础上,结合走滑断层的力学机制,提出走滑断层新分类方式,并运用新的分类方式进一步对美国西海岸圣安德列斯断层、新西兰的阿尔卑斯断层和中国著名的郯庐断裂带以及阿尔金断裂带等典型断层进行简要分析。      

郯庐断裂南段研究进展与断裂性质讨论

据1：5万区域地质调查和专题研究资料，就郯庐断裂带是否南延与消失的原因，其与大别—苏鲁造山带交截形成的假位错效应，以及与中新生代沉积盆地形成演化的关系等作了新的阐述。在此基础上，讨论了郯庐断裂带是否为巨大的左行平移断层或转换断层。认为郯庐断裂带可能是在“古郯庐带”的基础上于早侏罗世重新活动、白垩纪强烈活动的地堑型枢纽断裂带。     

丽江-小金河断裂盐源段断裂带规模、断裂带结构及其历史活动性

2008年汶川地震促使人们思考青藏高原东南缘走向和规模与龙门山断裂带相近的丽江- 小金河断裂的活动历史,但受限于地质条件制约断裂尤其是其北段相关研究极其薄弱。基岩断裂带的物质组成与结构特征是断层长期活动的产物,蕴含丰富的历史活动信息。本文以丽江- 小金河断裂盐源段多个天然剖面为研究对象,通过详细的断裂带宏观结构调查、断层岩显微构造及XRD分析发现：① 断层破碎带以一套厚度>20 m的破裂面密集带为特征,优势破裂面走向为NE20°~30°,推测为丽江- 小金河断裂长期活动形成的张剪性破裂;② 断层带核部以断层角砾岩和断层泥为主,灰岩角砾岩黏土矿物含量~2%,以伊利石和伊蒙混层为主,粉砂岩断层泥黏土矿物含量~52%,以坡缕石和绿泥石为主,石英含量36%,缺失长石类矿物。断裂带宏观结构和断层岩微观结构特征均表现为角砾呈棱角状,砾径差异极大且呈零散状分布,符合快速滑动特征,指示断层滑移方式为黏滑。此外,核部断层岩带统计厚5~8 m,这一规模相对于龙门山映秀- 北川断裂带核部180~280 m和安县- 灌县断裂带核部40~50 m显著偏小,表明前者自形成以来的活动性远低于后者,两者的地震行为并不能简单类比。结合断裂在宏观结构特征、断层岩成分与种类以及所反映的滑动方式与隆升剥蚀量的差异,认为丽江- 小金河断裂更可能是鲜水河断裂切断锦屏山- 龙门山构造带之后形成的,晚新生代与龙门山断裂带具有不同的活动历史。     

Relationship between the Pre-existing Active Kunlun Fault and Co-seismic Surface Ruptures Produced by the 2001 Mw 7．8 Central Kunlun Earthquake，China

Field investigations allow to constrain the co-seismic surface rupture zone of ～400km with a strike-slip up to 16．3 m associated with the 2001Mw 7．8 Central Kunlun earthquake that occurred along the western segment of the Kunlun fault,northern Tibet．The co-seismic rupture structures are almost duplicated on the pre-existing fault traces of the Kunlun fault．The deformational characteristics of the co-seismic surface ruptures reveal that the earthquake had a nearly pure strike-slip mechanism．Theg eologic and topographice vidence clearly shows that spatial distributions of the co-seismic surface ruptures are re-stricted by the pre-existing geological structures of the Kunlun fault．     

河北东北部兴隆煤田区逆冲构造的特征及其区域构造意义

兴隆煤田及邻区的逆冲构造系基底卷入变形的厚皮逆冲构造,并具有典型的断坪-断坡式几何学结构.断层上盘逆冲方向指向NNW,沿着主干逆冲断层发生的倾向位移量约为13.1 km,逆冲断层及相关褶皱变形所造成的局部表层地壳缩短率约32.3%.对兴隆逆冲构造的几何学结构、运动学性质及其地层效应的分析表明,在申家胡同到黄土梁近东西向一线以南的区域,寻找到因逆冲断层作用导致的隐伏煤田的可能性是极小的.主干逆冲断层上、下盘地层大面积陡立乃至倒转的特征,更容易用断展褶皱,尤其是三角形剪切断展褶皱模型做出合理解释.该逆冲构造主要逆冲断层的上、下盘盖层岩系不整合于基底结晶变质岩系之上,地层序列发育完整而且可以一一对应,不存在沿着相对软弱层发育的大规模逆冲断层之断坪,因此,将该逆冲构造作为区域上承德逆冲构造的根带是不合适的.     

Salinia revisited: a crystalline nappe sequence lying above the Nacimiento fault and dispersed along the San Andreas fault system,central California

Salinia, as originally defined, is a fault-bounded terrane in westcentral California. As defined, Salinia lies between the Nacimiento fault on the west, and the Northern San Andreas fault (NSAF) and the main trace of the dextral SAF system on the east. This allochthonous terrane was translated from the southern part of the Sierra Nevada batholith and adjacent western Mojave Desert region by Neogene-Quaternary displacement along the SAF system. The Salina crystalline basement formed a westward promontory in the SW Cordilleran Cretaceous batholithic belt, relative to the Sierra Nevada batholith to the north and the Peninsular Ranges batholith to the south, making Salinia batholithic rocks susceptible to capture by the Pacific plate when the San Andreas transform system developed. Proper restoration of offsets on all branches of the San Andreas system is a critical factor in understanding the Salinia problem. When cumulative dextral slip of 171 km (106 mi) along the Hosgri–San Simeon–San Gregorio–Pilarcitos fault zone (S–N), or dextral slip of 200 km (124 mi) along the Hosgri–San Simeon–San Gregorio–Pilarcitos–northern San Andreas fault system, is added to the cumulative dextral slip of 315–322 km (196–200 mi) along the main trace of the SAF north of the San Emigdio–Tehachapi mountains, central California, there is a minimum amount of cumulative dextral slip of 486 km (302 mi) or a maximum amount of cumulative dextral slip of 522 km (324 mi) along the entire SAF system north of the Tehachapi Mountains. When these sums are compared with the offset distance (610–675 km or 379–420 mi) between the batholithic rocks associated with the Navarro structural discontinuity (NSD) in northern California, and those in the ‘tail’ of the southern Sierra Nevada granitic rocks in the San Emigdio–Tehachapi mountains, central California, a minimum deficit of from ～100 km (～62 mi) to a maximum deficit of ～189 km (～118 mi) is needed to restore the crystalline rocks associated with the NSD with the crystalline terranes within the San Emigdio and Tehachapi mountains – the enigma of Salinia. Two principal geologic models compete to explain the enigma (i.e. the discrepancy between measured dextral slip along traces of the SAF system and the amount of separation between the Sierra Nevada batholithic rocks near Point Arena in northern California and the Mesozoic and older crystalline rocks in the San Emigdio and Tehachapi mountains in southern California). (i) One model proposes pre-Neogene (>23 Ma), Late Cretaceous or Maastrichtian (<ca. 71 Ma) to early Palaeocene or Danian (ca. 66 Ma) sinistral slip of 500–600 km (311–373 mi) along the Nacimiento fault and of the western flank of Salinia from the eastern flank of the Peninsular Ranges (sinistral slip but in the opposite sense to later Neogene (<23 Ma) dextral slip along and within the SAF system. (ii) A second model proposes that the crystalline rocks of Salinia comprise a series of 100 km- (60 mi-) scale allochthonous (extensional) nappes that rode southwestward above the Rand schist–Sierra de Salinas (SdS) shear zone subduction extrusion channels. The allochthonous nappes are from NW–SE: (i) Farallon Islands–Santa Cruz Mountains–Montara Mountain, and adjacent batholithic fragments that appear to have been derived from the top of the deep-level Sierra Nevada batholith of the western San Emigdio–Tehachapi mountains; (ii) the Logan Quarry–Loma Prieta Peak fragments that appear to have been derived from the top of a buried detachment fault that forms the basement surface beneath the Maricopa sub-basin of the southernmost Great Valley; (iii) The Pastoria plate–Gabilan Range massif that appears to have been derived from the top of the deep-level SE Sierra Nevada batholith; and (iv) the Santa Lucia–SdS massif, which appears to be lower batholithic crust and underlying extruded schist that were breached westwards from the central to western Mojave Desert region. In this model, lower crustal batholithic blocks underwent ductile stretching above the extrusion channel schists, while mid- to upper-crustal level rocks rode southwestwards and westwards along trenchward dipping detachment faults. Salinian basement rocks of the Santa Lucia Range and the Big Sur area record the most complete geologic history of the displaced terrane. The oldest rocks consist of screens of Palaeozoic marine metasedimentary rocks (the Sur Series), including biotite gneiss and schist, quartzite, granulite gneiss, granofels, and marble. The Sur Series was intruded during Cretaceous high-flux batholithic magmatism by granodiorite, diorite, quartz diorite, and at deepest levels, charnockitic tonalite. Local nonconformable remnants of Campanian–Maastrichtian marine strata lie on the deep-level Salinia basement, and record deposition in an extensional setting. These Cretaceous strata are correlated with the middle to upper Campanian Pigeon Point (PiP) Formation south of San Francisco. The Upper Cretaceous strata, belonging to the Great Valley Sequence, include clasts of the basement rocks and felsic volcanic clasts that in Late Cretaceous time were brought to a coastal region by streams and rivers from Mesozoic felsic volcanic rocks in the Mojave Desert. The Rand and SdS schists of southern California were underplated beneath the southern Sierra Nevada batholith and the adjacent Salinia-Mojave region along a shallow segment of the subducting Farallon plate during Late Cretaceous time. The subduction trajectory of these schists concluded with an abrupt extrusion phase. During extrusion, the schists were transported to the SW from deep- to shallow-crustal levels as the low-angle subduction megathrust surface was transformed into a mylonitic low-angle normal fault system (i.e. Rand fault and Salinas shear zone). The upper batholithic plate(s) was(ere) partially coupled to the extrusion flow pattern, which resulted in 100 km-scale westward displacements of the upper plate(s). Structural stacking, temporal and metamorphic facies relations suggest that the Nacimiento (subduction megathrust) fault formed beneath the Rand-SdS extrusion channel. Metamorphic and structural relations in lower plate Franciscan rocks beneath the Nacimiento fault suggest a terminal phase of extrusion as well, during which the overlying Salinia underwent extension and subsidence to marine conditions. Westward extrusion of the subduction-underplated rocks and their upper batholithic plates rendered these Salinia rocks susceptible to subsequent capture by the SAF system. Evidence supporting the conclusion that the Nacimiento fault is principally a megathrust includes: (i) shear planes of the Nacimiento fault zone in the westcentral Coast Ranges locally dip NE at low angles. (ii) Klippen and/or faulted klippen are locally present along the trace of the Nacimiento fault zone from the Big Creek–Vicente Creek region south of Point Sur near Monterey, to east of San Simeon near San Luis Obispo in central California. Allochthonous detachment sheets and windows into their underplated schists comprise a composite Salinia terrane. The nappe complex forming the allochthon of Salinia was translated westward and northwestward ～100 km (～62 mi) above the Nacimiento megathrust or Franciscan subduction megathrust from SE California between ca. 66 and ca. 61 Ma (i.e. latest Cretaceous–earliest Palaeocene time). Much, or all, of the westward breaching of the Salinia batholithic rocks likely occurred above the extrusion channels of the Rand-SdS schists; following this event, the Franciscan Sur-Obispo terrane was thrust beneath the schists, perhaps during the final stages of extrusion in the upper channel. Later, the Sur-Obispo terrane was partially extruded from beneath the Salinia nappe terrane, during which time the upper plate(s) underwent extension and subsidence to marine conditions. Attenuation of the Salinia nappe sequence during the extrusion of the Franciscan Complex thinned the upper crust, making the upper plates susceptible to erosion from the top of the Franciscan Complex near San Simeon, where it is now exposed. In the San Emigdio Mountains, the relatively thin structural thickness of the upper batholithic plates made them susceptible to late Cenozoic flexural folding and disruption by high-angle dip–slip faults. The ～100 km (～62 mi) of westward and northwestward breaching of the Salinia batholithic rocks above the Rand-SdS channels, and the underlying Nacimiento fault followed by ～510 km (～320 mi) of dextral slip from ～23 Ma to Holocene time along the SAF system, allow for the palinspastic restoration of Salinia with the crystalline rocks of the San Emigdio–Tehachapi mountains and the Mojave terrane, resolving the enigma of Salinia.     

龙泉山断裂带隐伏断层氡气特征及其活动性分析

龙泉山断裂构造带作为龙门山推覆带的前陆隆起,严格控制了成都平原东边界,其活动性历来受到人们的关注。通过对龙泉山断裂带的氡气进行测量,可以有效地判断隐伏断层的位置及其活动性。测量结果显示,龙泉山断裂带北段东坡活动性强于西坡,主断层的活动性明显强于边缘隐伏断层,4条断层的活动性由强到弱依次为合兴场断层红花塘断层龙泉驿断层松林场断层。龙泉山断裂带同一条断层在地表由多个破碎带组成,其氡气异常特征与断层活动性和破碎带特征呈正相关性,即断层活动性越强,氡气异常特征越显著。龙泉山断裂带氡气平均异常浓度是背景值的9.6倍,将各异常带峰值浓度与背景值进行对比分析,大致归纳出了龙泉山地区隐伏断层活动性的相对判别标准。