最大有效力矩准则约束下的广西罗阳山地震、地质与地貌效应

使用重新调查后的1936年灵山6?级地震的烈度资料,结合罗阳山西北麓和南麓的河流地貌与地质构造考察,参考该地区裂变径迹年代学资料,探讨了罗阳山地区的地质力学环境。重新调查后的极震区等烈度区有北北西和北东2个优势方向区域,这2个区域围绕北北西向的泗州断层和北东向的寨圩断层展布。在构造与地貌调查中发现:罗阳山山体有地貌隆升表现,并得到了裂变径迹证据支持;罗阳山西北麓山前冲沟具右旋活动表现;泗州断层内部破裂面的倾向以南西向为优势方向,并具顺时针旋转和高倾角特征。地震分布显示:寨圩断层和泗州断层交汇部位的东南侧有小地震密集展布现象。经分析后认为,以上构造地貌现象是最大有效力矩准则约束下的地震、地质和地貌效应。      

东昆仑地区地球物理特征与矿产资源分布

利用东昆仑地区的区域重磁场及深部地球物理信息,研究探讨了地球物理特征与矿产资源的关系。贯穿研究区的重力梯级带反映了地壳深部构造的深大断裂带,该梯级带与昆中断裂对应,它不仅是划分构造单元的边界,而且与地壳构造运动的性质及岩浆活动、矿产分布等密切相关。研究区航磁异常区以东西向、北西向和北东向为主,异常呈交叉及串珠状分布。沿重力梯级带及航磁异常周围形成一些具工业价值的矿床。深部地质与地球物理资料揭示了该区地壳与上地幔密度分布的不均匀性及其速度结构差异。深大断裂的发育对该地区金属成矿区带的分布起到了控制作用。     

中国东南部晚中生代-新生代玄武岩与壳幔作用

中国东南部的火山活动在早中生代时期仅有很小规模,晚中生代最早的、较大规模的岩浆活动始于中侏罗世早期,至早白垩世是火山岩浆活动的鼎盛期,在近100个Ma的时间内形成了大面积分布的晚中生代火山-侵入岩,而在新生代则以面积较小的玄武岩浆喷出活动为主,局限分布于沿海一带。以晚中生代湘南、赣南和闽西南的近EW向火山岩带和浙、闽沿海地区的近NNE向火山岩带,以及新生代近NNE向火山岩带为研究对象,对这些火山岩的地球化学特征对比研究,结合时空分布,讨论了它们的起源及其与壳幔相互作用的关系,以及它们形成的构造环境,其结果显示,EW向晚中生代火山岩带（180～170Ma）的西段玄武岩独立产出,且明显属碱性系列;而中段和东段玄武岩和流纹岩伴生,其中的玄武岩均为亚碱性系列的拉斑玄武岩。它们形成于板内拉张构造环境,是中国东南部特提斯构造域向太平洋构造域转换、晚中生代大规模岩浆作用的序幕。研究表明,该火山岩带自西向东表现出不同程度的壳幔相互作用,玄武岩在成岩过程中有少量陆壳组分加入。NNE向晚中生代火山岩带（130～90Ma）主要为流纹质岩石,安山岩和玄武岩很少。即使是双峰式火山岩也以酸性岩为主,玄武岩仅占全部火山岩体积的30％以下。其中的玄武岩主要属钙碱性系列,少数属拉斑系列。它们形成于火山弧构造环境,是中国东南部受太平洋构造域影响发生大规模火山岩浆作用的主旋律。其中玄武岩岩浆成分受到了较高程度的陆壳物质混染,同时代的中性火山岩是由底侵的玄武岩岩浆和陆壳物质来源的酸性岩浆发生岩浆混合作用而形成的,反映了强烈的壳幔相互作用。NNE向新生代火山岩带,分布在浙闽沿海,以碱性系列玄武岩为主,均含幔源包体,并受NNE向大陆边缘断裂构造的控制。它们形成于板内裂谷环境,是中国东南沿海由晚中生代火山弧构造环境转换为新生代板内裂谷环境的标志,起源于软流圈地幔,并有EMII岩石圈地幔的混合组分,但基本没有受到陆壳物质的混染。     

福州—永泰区域地质构造及其对热田控制作用的初步探讨

本文通过沉积建造、岩浆活动、构造断裂、地貌、地震活动等方面,阐明了福州—永泰区域地质构造带及其特征。论述了本构造带内温泉的分布规律,该构造带控制了本区热源及地热异常带分布范围;区域上北东东向断裂带是压扭性的,特别是輓近时期挤压更甚,它在深部不可能成为热源通道;本区北北西向主要断裂在平面上大致以8—10公里间距排列,是控制区内温泉出露及展布的构造;北北西向断裂的力学性质以张为主张扭性特征,其在輓近时期活动性强、是本区良好的控热与导水构造。     

基于航磁资料的大兴安岭南部区域成矿构造填图尝试

大兴安岭地区是中国重要的成矿区带之一,具备大规模成矿的条件和找矿潜力。对大兴安岭地区的大型断裂、次级断裂及基底构造系统深入研究是揭示控制该地区构造-岩浆活动和成矿作用的重要内容。对大兴安岭南部的航磁数据进行处理和解释,查明了研究区北东向、东西向、北北东向和北西向深大断裂为主的深部基底构造特征,圈定了火山机构分布位置,分析了大兴安岭南部区域构造特征,揭示了反映岩浆岩活动的线性或面状正磁异常和磁异常梯级带,探讨了研究区金属成矿的有利区带。为大兴安岭南部地区的区域地质、构造特征三维地质填图、找矿远景区的圈定提供了基础性信息。     

吉南龙岗地区新生代火山机构恢复及地质特征——基于航磁特征解译分析

吉南龙岗地区发育大量新生代火山岩,是了解辽东—吉南新生代构造演化的重要途径之一,但龙岗地区植被发育且剥蚀严重,通过地表调查难以获得准确的火山构造以及空间分布等相关信息。本文利用龙岗地区头道溜河附近的航磁资料,对原始数据进行化极、垂向导数等频率域数据处理,结合龙岗地区新生代火山岩研究的其他资料,对龙岗地区火山岩的航磁特征以及典型地区航磁异常特征进行了分析。研究结果表明:在地表调查揭露火山机构困难的环境下,利用航磁数据对火山机构的识别及恢复是一种较为高效的方法;同时可以通过航磁异常的分布特征,推断多期次火山岩的空间分布特征;初步研究分析龙岗新生代火山机构航磁异常具有两种不同类型的特征,一类外部表现为环形串珠状正异常包围着不规则椭圆状的负磁异常;二类外部由多个不规则串珠状正磁异常组成,环形异常整体表现为负异常区,但中心区域叠加了两个强度较大的正异常。以上两类异常的特征与不同的火山及岩浆活动有关。     

琼北新生代火山构造的航磁异常特征及其地质意义

琼北地区发育大量新生代火山岩,是了解东南亚新生代构造演化的重要窗口之一。本文利用琼北地区最新航磁资料,采用航磁ΔT原始数据进行化极、垂向一阶导数等频率域转换处理等方法,并结合琼北新生代火山岩研究的其它资料,对琼北新生代火山岩区域航磁特征以及典型地区航磁异常特征进行了分析。研究结果表明:琼北东部与西部区域磁场特征存在一定的差异,即其东部具有平缓变化的负磁场特征,而中—西部具有强烈升高正磁场特征,这可能与琼北平缓变化的负背景场上叠加的新生代火山岩磁性强弱以及在空间上分布的不均匀有关。琼北新生代火山构造航磁异常具有两种不同的类型,第一类其内环航磁异常表现为不规则椭圆状负磁异常,负异常周围被环形升高的串珠状正磁异常所包围,该类航磁异常可能由塌陷式盾状火山锥群引起;第二类其外环由多个圈闭不规则的串珠状正磁异常组成,环形构造内部总体为负异常,但中心分布两个强度较大的正异常,该类航磁异常可能与早期塌陷式盾状火山锥群并叠加晚期磁性玄武质岩浆活动有关。     

大陆板内地震的发震机理与地震预报——以汶川地震为例

大陆板内地震主要产于新生代厚壳造山带或高原,在平面上呈弥散状分布,在剖面上震源沿中地壳成层分布,为浅源地震.盆山活动断层系统呈规律性组合,盆山挤压边界为逆冲型压性发震断层;盆山走滑转换边界为走滑型扭性发震断层;造山带内部主要是伸展型张性发震断层.大陆板内地壳分层流变作用制约了板内地震的构造物理过程.大陆下地壳韧性流层为地震活动提供了热能,热软化和热融化介质发生缓慢的韧性流动,是孕震构造;中地壳韧-脆性剪切带发生热-应力转换,聚积应力和应变,为蕴震构造;当下地壳流动在中地壳积累的应变超过上地壳特定构造部位介质的应力-应变极限时,上地壳形成脆性发震断层,产生地震.震源出现在上地壳脆性断层与中地壳脆-韧性剪切带的交汇部位,青藏高原的震源深度通常为12～35 km.目前地震预报是世界科学难题,然而,大陆动力学和板内地震的理论突破可能为短临预报提供了新思路.如果大陆下地壳热动力作用是中地壳产生地震和上地壳发生地震的根源,那么上地壳脆性断层活动会释放出地壳深部的热流体和热气体,引起局部的地温异常、水文异常和大气异常.建议从大气到地表再到地下系统地监测活动断层带及邻区的地下水、地表水、大气的温度异常和成分变化,结合观测下地壳流层厚度、地应力-应交变化、重力异常、磁异常、地电异常等,综合评价地壳活动性和发震可能性.2008年5月12日发生的里氏8.0级汶川地震处于龙门山造山带与四川盆地的构造边界上,是典型的大陆板内地震,震源处于映秀-北川断层上,震源深度为12 km.350 km长的地表破裂带呈右行左阶雁行排列在具有逆冲和右行走滑性质的汶川-茂县-青川、映秀-北川和江油-都江堰3条断层带上.下地壳的韧性流动伴随中地壳韧-脆性剪切带应力和应变的积累,产生上地壳脆性活动断层,并控制地表破裂带和滑坡的分布.     

柴达木东缘碰撞系统划分

基于前人对于柴达木东南缘北北西向鄂拉山岩浆带的研究成果,结合研究区火山-岩浆岩、蛇绿岩和沉积地层的形成时代、环境、分布规律、构造发育以及热力学环境和重磁地球物理异常等因素,认为鄂拉山岩浆弧是松潘—甘孜板块以阿尼玛卿蛇绿岩带为缝合线向北俯冲的产物.在整个闭合过程中,深部发生了滑脱,浅部碰撞前为半岛+拗拉槽+洋岛+海槽的基本格局,构造运动经历了洋壳俯冲中消减、陆内碰撞造山和地壳伸展3个阶段,区内花岗岩的起因,始于洋壳俯冲,发展于陆内碰撞,因而,所发育的岩浆岩具有Ⅰ-S过渡型花岗岩的特征,是海西晚期—燕山早期构造运动的地质记录.通过演绎这一发展过程,划分了柴达木东南缘岩浆岩带的碰撞体系.     

中国东部北黄海盆地东部坳陷岩浆活动特征及其与区域构造的耦合关系

如何深入了解中国东部北黄海盆地东部坳陷岩浆活动特征是目前研究的前沿之一.为探讨早白垩世异常剧烈岩浆活动的区域构造成因并揭示中国东部的构造动力学机制,利用井-震及岩浆岩测试资料,对北黄海盆地岩浆活动特征及其与区域构造的耦合关系进行研究.在空间上刻画了岩浆的侵入相、喷出相的地震反射特征及沿深大断裂展布的平面分布特征;在时间上划分出了包括早白垩世108~115 Ma、134~145 Ma在内的4期岩浆活动.结合区域地质分析认为早白垩世早期,伊泽奈琦板块沿北北西斜向俯冲于欧亚板块之下,太平洋板块向南西方向俯冲,板块剪切作用导致郯庐断裂带左旋走滑,使得盆地处于左旋伸展环境中,内部形成派生的北西向右旋、近南北向左旋的次级共轭断裂系并控制岩浆上侵底辟活动.经过综合分析,厘清了盆地岩浆活动及断裂演化过程与区域板块运动之间的耦合关系.      

What triggers Koyna region earthquakes? Preliminary results from seismic tomography digital array

The cause for prolific seismicity in the Koyna region is a geological enigma. Attempts have been made to link occurrence of these earthquakes with tectonic strain as well as the nearby reservoirs. With a view to providing reliable seismological database for studying the earth structure and the earthquake process in the Koyna region, a state of the art digital seismic network was deployed for twenty months during 1996–97. We present preliminary results from this experiment covering an area of 60 × 80 km² with twenty seismic stations. Hypocentral locations of more than 400 earthquakes confined to 11×25 km² reveal fragmentation in the seismicity pattern — a NE — SW segment has a dip towards NW at approximately 45°, whilst the other two segments show a near vertical trend. These seismic segments have a close linkage with the Western Ghat escarpment and the Warna fault. Ninety per cent of the seismicity is confined within the depth range of 3–10 km. The depth distribution of earthquakes delimits the seismogenic zone with its base at 10 km indicating a transition from an unstable to stable frictional sliding regime. The lack of shallow seismicity between 0 and 3 km indicates a mature fault system with well-developed gouge zones, which inhibit shallow earthquake nucleation. Local earthquake travel time inversion for P- and S-waves show ≈ 2% higher velocity in the seismogenic crust (0–10 km) beneath the epicentral tract relative to a lower velocity (2–3%) in the adjoining region. The high P- and S-wave velocity in the seismogenic crust argues against the presence of high pressure fluid zones and suggests its possible linkage with denser lithology. The zone of high velocity has been traced to deeper depths (≈ 70 km) through teleseismic tomography. The results reveal segmented and matured seismogenic fault systems in the Koyna region where seismicity is possibly controlled by strain build up due to competent lithology in the seismic zone with a deep crustal root.     

唐山地震区域构造背景和发震模式的讨论

1976年7月28日3点42分在我国河北省唐山地区发生了7.8级强烈地震。地震的发生,是有它的区域构造背景和震区的构造条件的。深入研究这个问题,对认识地震的形成、孕育和发生是十分有意义的。唐山地震震中与深大断裂没有表现直接的联系,而是分布在不引入注目的北东向断裂上。其控制因素我们认为是包围震区的边界断裂起了重要作用。边界断裂的存在使被围限的北东向断裂得到了暂时的平衡,形成相对“闭锁”区段。当区域应力场急剧变化时,“闭锁”就被突破,产生大地震。     

Kinematics and strain partitioning in the southeast Hellenides (Greece)

New kinematic and structural data from the tectonic windows of eastern Crete and the Dodecanese Islands combined with strain and quartz fabric analysis have enabled us to determine a detailed structural evolution of the region and to present a plate tectonic scenario for the southeast Hellenides. During the Early Mesozoic, the southeastern part of Apulia was separated from North Africa and the adjacent microplates by WNW‐trending rift zones and NE‐trending transfer faults. Displacement along the transfer faults has locally reoriented these rift zones into an ENE–WSW direction. Finite strain and quartz fabric asymmetry data indicate that in Late Cenozoic time, NNW‐directed nappe movements caused a nearly coaxial deformation along the ENE–WSW trending rift segments and non coaxial top‐to‐the‐southeast shearing along the WNW‐trending rift segments, as well as along the pre‐existing NE‐trending transfer faults. Tectonic style along the margin varies in response to the obliquity of the principal shortening direction with respect to the margin. These variations could be due to the pre‐convergence geometry of the southern margin of Eurasia and to local strain partitioning effects. Furthermore, a tectonic model is presented in which syncompressional uplift and vertical buoyancy of the subducted crustal slice caused the rapid exhumation of metamorphic units in the south Hellenides. Copyright © 2003 John Wiley & Sons, Ltd.     

The Seismogenic Structure and Deformation Mechanism of the Lushan (Mw 6.6) Earthquake,Sichuan, China

On April 20 th, 2013, an earthquake of magnitude MW 6.6 occurred at Lushan of Sichuan on the southern segment of the Longmenshan fault zone, with no typical coseismic surface rupture. This work plotted an isoseismal map of the earthquake after repositioning over 400 post–earthquake macro–damage survey points from peak ground acceleration(PGA) data recorded by the Sichuan Digital Strong Earthquake Network. This map indicates that the Lushan earthquake has a damage intensity of IX on the Liedu scale, and that the meizoseismal area displays an oblate ellipsoid shape, with its longitudinal axis in the NE direction. No obvious directivity was detected. Furthermore, the repositioning results of 3323 early aftershocks, seismic reflection profiles and focal mechanism solutions suggests that the major seismogenic structure of the earthquake was the Dayi Fault, which partly defines the eastern Mengshan Mountain. This earthquake resulted from the thrusting of the Dayi Fault, and caused shortening of the southern segment of the Longmenshan in the NW–SE direction. Coseismal rupture was also produced in the deep of the Xinkaidian Fault. Based on the above seismogenic model and the presentation of coseismic surface deformation, it is speculated that there is a risk of more major earthquakes occurring in this region.     

Tectonic implications of the earthquakes in the Indian subcontinent

The Bhuj earthquake (26 January 2001) in India and the Ghori earthquake (8 October 2005) in Pakistan, both occurred close to the Indian-Iranian plate boundary related to the activity along the intercontinental Chaman transform fault. It is suggested that the seismic activity along NNW — NNE trending weak zones or faults is more intense in the sub-continent than along the WNW trending zones. Since the stress along the former is less compressive but more of the shear or translational type. The devastative Koyna (1967) and Latur (1993) earthquakes both occurred along faults or weak zones that were close to the meridional rather than the equatorial trend. The Indian plate is moving to the north or NNE or NNW, along a rotational trajectory and hence the force tends to be more compressive along the equatorial weak zones. In contrast, it tends to be less compressive and more of the shear or translational along the weak zones that are close to meridional trend. The seismic activity is therefore more intense along the weak zones with NNW to NNE trend than along the ENE to EW trending zones.     

Deep Seismogenic Environment in the Southern Section of the Longmenshan Fault Zone on the Eastern Margin of the Tibetan Plateau and Lushan Ms 7.0 Earthquake

The 2,026 earthquake events registered by the Sichuan regional digital seismic network and mobile seismic array after the April 20 th,2013 Lushan earthquake and 28,188 pieces of data were selected to determine direct P waves arrival times. We applied the tomographic method to inverse the characteristics of the velocity structure for the three-dimensional(3D) P wave in the mid-upper crust of the seismic source region of the Lushan earthquake. The imaging results were combined with the apparent magnetization inversion and magnetotelluric(MT) sounding retest data to comprehensively study the causes of the deep seismogenic environment in the southern section of the Longmenshan fault zone and explore the formation of the Lushan earthquake. Research has shown that there are obvious differences in velocity structure and magnetic distribution between the southern and northern sections of the Longmenshan fault zone. The epicenter of the Lushan earthquake is located near the boundary of the high and low-velocity anomalies and favorable for a high-velocity section. Moreover,at the epicenter of the Lushan earthquake located on the magnetic dome boundary of Ya’an,the development of high velocity and magnetic solid medium favors the accumulation and release of strain energy. Lowvelocity anomalies are distributed underneath the are of seismogenic origin,The inversion results of the MT retest data after the April 20 th Lushan earthquake also indicate that there a high-conductor anomaly occurs under the area of seismogenic origin of the Lushan earthquake,Therefore,we speculated that the presence of a high-conductivity anomaly and low-velocity anomaly underneath the seismogenic body of the Lushan earthquake could be related to the existence of fluids. The role of fluids caused the weakening of the seismogenic layer inside the mid-upper crust and resulted in a seismogenic fault that was prone to rupture and played a triggering role in the Lushan earthquake.     

小南沟金矿构造控矿特征及成矿预测

河南熊耳山地区的金矿大多产于NE向和近E-W向断裂中.近年来发现的小南沟金矿受控于近S-N向断裂,开拓了该地区金矿找矿的新思路.研究表明,近S-N向的控矿断裂为NNW向与NE向一组共轭断裂的复合成因,是在E-W向基底断裂的基础上发育形成的,成矿作用与区域成矿具有一致性.总结出NE向断裂有利成矿的断裂走向勘探标志,指出小南沟金矿的外围仍有良好的找矿条件,NNW向、NE向与NWW向断裂构造交汇部位有利成矿.小南沟主矿体存在向北的迅速侧伏,侧伏的原因与E-W向断层北倾以及NNW与NE向断层交汇线的向北侧伏有关.     

2017年四川九寨沟Ms7.0地震InSAR同震形变场及发震构造探讨

2017年8月8日四川省九寨沟县发生M_s7.0级地震,构造部位处于青藏高原东缘的巴颜喀拉地块东北角,震中位置是岷江断裂、塔藏断裂、虎牙断裂和雪山梁子断裂围闭的空震区。哪条断裂发震,如何界定其与周边活动断裂的关系,与青藏高原东缘近年来发生的大地震是否有成因联系等问题对于理解该区域现今构造活动模式、预判地震发展趋势和部署地震地质灾害防控等工作具有重要意义。利用地震前后两期Sentinel-1合成孔径雷达数据对地表同震形变场进行了InSAR测量,获取了极震区约2000 km²范围内的雷达视线向变形（-13~28 cm）和运动方向,呈现为主动盘单侧走滑兼逆冲的变形模式,结合震源机制、断裂展布、构造背景和近年地震迁移的分析,揭示了控震构造是巴颜喀拉地块北缘边界断裂弧形旋转体系的尾端构造,发震断层是该断裂系中塔藏断裂的南段,并有与虎牙断裂贯通的趋势,因此,应重视本次地震与虎牙断裂之间的空震区未来的强震危险性问题;从区域上看,此次九寨沟地震可能与汶川地震具有一定的时空成因联系,因在巴颜喀拉地块南北边界断裂破裂基本贯通的条件下,2008年汶川地震诱发的东缘中部锁固破裂导致块体加速向东挤出,2013年鲁甸地震又释放了东缘南段挤压构造应力,从而进一步加剧了东北角的应力集中,促使九寨沟地震的发生。     

皖南-浙西地区盖层褶皱构造形迹特征

前人对皖南-浙西地区古生代至早中生代盖层中发育的褶皱变形期次、特征和构造样式的认识尚存在较多分歧。本文通过区内盖层褶皱变形调查与解析,除印支早期褶皱和燕山期构造外,新识别出加里东期和印支晚期褶皱。加里东期褶皱样式主要表现为大型中常至开阔褶皱,且均为复式褶皱;次为小型紧闭褶皱,二者可能为从属性质。其构造线均呈近东西向或北东东向。印支早期褶皱样式主要为中常线形褶皱,其轴迹呈北东向;晚期表现为中常至开阔褶皱样式,轴迹呈北北西或近南北向。燕山期构造主要为盆地和断裂构造。早白垩世早期,表现为同沉积宽缓向斜,构造线呈近东西向;早白垩世之后,主要表现为断陷盆地和断裂构造,构造线呈北东或北北东向。各期褶皱叠加明显,形成"L"或"厂"字型组合特征,或形成构造穹窿-盆地组合。深入研究构造特征及演化规律,对区域构造格架建立具有重要意义。