程海断裂带断层泥中石英碎砾表面SEM特征及断层活动状态的分析

根据断层泥中石英碎砾表面SEM特征的鉴定研究，可将程海断裂中、北段断层泥中石英碎砾表面SEM形貌特征分为6类，这表明该段断裂经历了长期多期次活动，强烈活动时间在中晚更新世；5件样品中均未见破裂类(Io)的石英颗粒，表明程海断裂全新世以来强烈活动的频度相对较低。石英碎砾表面机械作用特征的分类统计研究显示：程海断裂中、北段晚更新世以来，断层所经历的活动方式以粘滑活动为主。     

青藏高原东北缘断层泥的研究

本文对青藏高原东北缘一些主要断裂（包括阿尔金、昌马、毛毛山等断裂）的断层泥首次进行了研究。在对断裂带的内部结构、围岩成分、断层泥的厚度及石英颗粒表面特征等综合分析的基础上对断裂的活动年代、活动方式及断层泥形成的深度进行了讨论。石英颗粒表面上溶蚀程度（颗粒表面的光滑程度、凹凸现象及孔洞发育情况）可划分为６种类型并且每种类型都有相应的年代。根据断裂的粘滑、蠕滑特征，对该区的各活动断裂进行了粘滑段与蠕滑段的划分。用红外光谱与稀土元素的分析结果，算得断层泥形成的深度在地壳１０ｋｍ范围内。     

毛毛山断裂带断层岩的特征及其意义

对毛毛山断裂带断层岩进行了宏观及微观的观察和分析，特别是对断层岩中石英颗粒的形貌特征、溶蚀类型及断层岩的组分进行了研究。结果表明该断裂是一条具有多期活动的全新世活动断裂．滑动性质以粘滑为主，断裂的东段较西段更为明显。     

昌马断裂带断层岩研究及其粘滑,蠕滑特征

在对断层岩的分布、内部结构、宏观变形及断层泥中石英颗粒形态、表面特征研究分析的基础上，讨论了昌马断裂带粘滑、蠕滑特征。同时指出，昌马断裂带虽以粘滑运动为主，但仍伴有一定量的蠕滑活动。     

阿尔金断裂东段断层泥特征及断层滑动方式

本文用扫描电镜、X衍射等方法对阿尔金断裂东段断层泥的特征、断层活动强度及断层滑动方式进行了研究,获得了如下结论: (1)阿尔金断裂东段的活动强度自晚更新世以后,由西往东逐渐减弱。(2)该断裂东段在第四纪以来至少发生过2—3次古地震事件。(3)全新世以来,该断裂的肃北至阿克塞一段以粘滑为主,而东边的巴个峡至昌马大坝之间断裂的滑动方式则为蠕滑。     

郯庐断裂带潍坊—嘉山段全新世活断层的活动方式与发震模式

郯庐断裂带潍坊－嘉山段全新世活断层由三个独立的破裂段组成。从各段的断错地貌，松散堆积物特征，断层本身的特点以及断层泥的显微构造标志看，各段具有共同的特点，就是主要粘滑运动为主，并在震后有蠕滑调整运动，各段具有断层闭锁→粘滑发震→震后调整→断层再次闭锁的发震模式，目前莒县－郯城段仍处于震后调整阶段，而安丘段和新沂－泗洪段由已处于断层闭锁的后期阶段，面临粘滑发震的危险。     

安宁河断裂带北段晚更新世以来的分段活动特征

本文据断裂带的断层几何形态、组合型式、断错地貌及地震活动资料,讨论了安宁河断裂带北段(西昌-石棉田湾段)在晚更新世以来的活动性状。根据该段活动程度的差异,从南至北将其分为三个活动段,即西昌-冕宁段;冕宁-紫马垮段;紫马垮-田湾段。上述三个活动段除南段具备发生大震背景外,中段和北段分别具有发生强震和中强震的背景。根据断层泥中石英碎屑表面扪描电子显微(SEM)结构特征,讨论了安宁河断裂带北段的运动性质,指出西昌-紫马垮段具粘滑运动方式;紫马垮-麂子坪段具粘滑、蠕滑兼有的运动方式;麂子坪以北至田湾段具以蠕滑为主的运动方式。     

海原活动断裂中断层泥的特征、成因及其对断层滑动性能的影响

本文对海原断裂的断层泥的各类特征进行了系统的研究,分析了断层泥带内部的小型断裂类型,探讨了断层泥组分的有机地球化学意义。通过对比,确立了石英碎屑表面机械作用成因的电子显微构造特征组合为活断层的判别标志。本文将石英碎屑表面电子显微溶蚀构造分为五类,据此分析了断层活动时期和状态。研究中还发现了断层泥带内部电子显微结构类型,进而分析了断层活动与微结构、粒度分布间的关系。最后还讨论了断层泥形成演化过程以及断层泥对全新世以来断层滑动性能影响及其与地震活动的关系     

秦皇岛市断裂断层泥的SEM特征与断裂活动性

在野外地质调查的基础上，通过研究秦皇岛市Ｆ１、Ｆ２、Ｆ３断裂断层泥中石英颗粒表面的ＳＥＭ特征，认为Ｆ１断裂最末一次活动时间在早更新世至中更新世；Ｆ２断裂最末一次活动时间在晚更新世中晚期；Ｆ３断裂最末一次活动时间在晚更新世末或全新世初。     

郯庐断裂带淮河南到女山湖段晚第四纪以来的新活动

以郯庐断裂带淮河南到女山湖段晚第四纪以来是否具有新活动为主要研究目标,通过遥感影像资料解译及地表反复调查,选择构造地貌显著地段开挖探槽,识别和记录其变形形态,分析其活动习性,定向采集新活动变形物质,在保持原态基础上磨制定向薄片,并进行微观构造分析论证。研究表明,断裂沿线线状构造地貌清晰,横跨断裂带的3个探槽均揭示出晚第四纪以来活动痕迹,断裂最新错断了晚更新世-全新世地层;滑移方式多表现为粘滑,典型表现为断层陡坎、楔状堆积、断层和充填裂缝等,总体显示为脆性高速变形特征,属于史前地震遗迹。上述认识部分得到微观分析证实。文中还初步探讨了淮河南北郯庐断裂最新活动特征的异同点及其可能的原因。     

郯庐断裂带白山-卅铺段第四纪以来的活动习性

根据构造地貌遥感解析,发现郯庐断裂带沿庐江白山到桐城卅铺一线显示1组平行断层,现场地震地质调查验证其为1组活动断层。通过断层剖面观测、样品采集及样品测试分析和宏微观构造分析,结果表明,郯庐断裂带在白山—卅铺一带第四纪以来仍具有黏滑、蠕滑交替的变形活动。其中,在柯坦—卅铺一带,最年轻的水系被NE向断层组右旋扭折,其断层物质的微观观测和测龄结果表明该断裂段第四纪时的活动具有脆、塑性过渡变形特征,强烈活动时间处于早、中更新世;而白山剖面断层泥年龄测试结果则反映相应断层段在中、晚更新世曾有过较强烈的活动。断层泥超微(SEM)和显微观测结果亦表明该断裂段曾发生黏滑、蠕滑交替的构造变形事件,且表现为先黏滑后蠕滑;结合水系呈现缓慢扭折表征,近年来沿断裂有不少微震发生,表明郯庐断裂带在白山—卅铺段的最新滑移方式主要表现为蠕滑,也就是说,该段积累的应力以蠕滑或微震等方式缓慢释放,据此推测未来一定时期内不易孕育强烈地震     

红河和曲江断裂带断层泥的特征及其地震地质意义

活断层产物的研究近年来受到国内外地震地质学者的关注。笔者对地质、地震证据充分的活断层——红河断裂带和曲江断裂带的断层泥进行多种手段的分析研究。它们的显微构造、粒度分布,组构特征以及石英碎砾的SEM显微形貌等显示了活断层中的长期蠕滑研磨作用、地震过程的快速剪切运动以及活断层特定条件下的退变质作用和其他化学作用等成因特征。综合分析指出,红河断裂带南段可能是蠕滑运动为主的活断层,其北段和曲江断裂带则为粘滑运动为主的活断层     

鉴定活断层粘滑活动的一种新标志

本文根据实验研究,探讨了活断层泥中石英碎砾表面放射状张裂纹和凹坑的形成机制,提出了放射状张裂纹和凹坑是活断层粘滑活动时石英碎砾中包体发生爆裂的产物的观点。这种放射状爆裂张裂纹和弹坑可以作为鉴定活断层粘滑活动的一种新标志。     

程各庄断裂断层泥显微结构特征及其断裂活动性探讨

程各庄断裂是马坊－夏垫断裂带北段的一条东分支断裂，根据其断层泥的显微结构，石英碎屑ＳＥＭ特征，热释光年龄综合分析，结果表明，该断裂不同区段的最新活动都是以粘滑迷主，但各个区段不同地质时期其活动方式和强度不同。     

郯庐断裂带南段新活动性的初步研究

由于郯庐断裂带南段的第四纪地层不发育,尽管断裂构造岩松散而未固结成岩,也难以应用地层变位法来确定它的最新活动时代和活动方式。笔者在发育断层泥的断裂露头剖面上,采集断层泥样品9个,通过扫描电镜——石英碎砾刻蚀形貌法来确定它的新动活性。根据石英碎砾的刻蚀形貌类型判定断层的最新活动时代和活动方式;蠕滑?粘滑?从而确定郯庐断裂带南段的最新活动时代在N_2—Q_1或Q_2,活动方式以粘滑为主。     

利用滑动速率、古地震资料估算走滑断裂的粘滑及蠕滑量的方法

断层走滑包括粘滑和蠕滑,前者是伴有强震发生的快速运动,后者则是一种缓慢的无震稳滑运动。这２ 种运动常随时间交替出现,共同构成了断层的基本运动方式。在利用断层滑动速率讨论大震重复率的问题中,人们最关心的问题则是如何从总滑动量中分辨和划分出其中所包含的粘滑和蠕滑量,特别是对蠕滑量的划分,因为它直接影响着大震重复率的正确性。笔者在野外考察的基础上,对昌马活动断裂的位移量进行了分级,确定出昌马断裂带全新世以来的水平滑动量大致可划分为５个级别：３１～４１ ｍ ;２５～３１ ｍ ; １５～２２ ｍ ; ８～１３ ｍ ;１～５．５ ｍ ,同时依据古地震学方法并结合１４Ｃ断代法及断层崖形成年代的数学模拟计算,求得全新世以来在昌马断裂带上共发生５ 次古地震事件。在上述２ 项资料确定的基础上,进一步对昌马断裂带的粘滑及蠕滑量进行了划分,并给出了它们随时间的变化情况     

临潼-长安断裂带晚第四纪以来的活动性

对临潼-长安断裂带进行了详细的野外调查,以期掌握其最新活动年代和第四纪以来的活动特征。该断裂总体走向NE,以张性垂直运动为主,断面明显错断了黄土中的第1层古土壤S1,说明其晚更新世以来仍在活动,并且北段和中段的活动性比南段强,但是错距大多<2m,滑动速率较小,考虑到临潼-长安断裂带由多条次级断层组成,其整体活动性应该比我们计算得到的局部断层滑动速率大得多。断层错距自上而下成递增趋势,并且根据不同地层年代计算出的滑动速率基本一致,因此该断裂带自中更新世晚期以来极可能以垂向蠕滑活动为主     

LATE-QUATERNARY ACTIVITY OF THE YALAHE FAULT OF THE XIANSHUIHE FAULT ZONE,EASTERN MARGIN OF THE TIBET PLATEAU

Complex geometrical structures on strike-slip faults would likely affect fault behavior such as strain accumulation and distribution, seismic rupture process, etc. The Xianshuihe Fault has been considered to be a Holocene active strike-slip fault with a high horizontal slip rate along the eastern margin of the Tibetan plateau. During the past 300 years, the Xianshuihe Fault produced 8 earthquakes with magnitude≥7 along the whole fault and showed strong activities of large earthquakes. Taking the Huiyuansi Basin as a structure boundary, the northwestern and southeastern segments of the Xianshuihe Fault show different characteristics. The northwestern segment, consisting of the Luhuo, Daofu and Qianning sections, shows a left-stepping en echelon pattern by simple fault strands. However, the southeastern segment(Huiyuansi-Kangding segment)has a complex structure and is divided into three sub-faults: the Yalahe, Selaha and Zheduotang Faults. To the south of Kangding County, the Moxi segment of the Xianshuihe Fault shows a simple structure. The previous studies suggest that the three sub-faults(the Yalahe, Selaha and Zheduotang Faults of the Huiyuansi-Kangding segment)unevenly distribute the strain of the northwestern segment of the Xianshuihe Fault. However, the disagreement of the new activity of the Yalahe Fault limits the understanding of the strain distribution model of the Huiyuansi-Kangding segment. Most scholars believed that the Yalahe Fault is a Holocene active fault. However, Zhang et al.(2017)used low-temperature thermochronology to study the cooling history of the Gongga rock mass, and suggested that the Yalahe Fault is now inactive and the latest activity of the Xianshuihe Fault has moved westward over the Selaha Fault. The Yalahe Fault is the only segment of the Xianshuihe Fault that lacks records of the strong historical earthquakes. Moreover, the Yalahe Fault is located in the alpine valley area, and the previous traffic conditions were very bad. Thus, the previous research on fault activity of the fault relied mainly on the interpretation of remote sensing, and the uncertainty was relatively large. Through remote sensing and field investigation, we found the geological and geomorphological evidence for Holocene activity of the Yalahe Fault. Moreover, we found a well-preserved seismic surface rupture zone with a length of about 10km near the Yariacuo and the co-seismic offsets of the earthquake are about 2.5~3.5m. In addition, we also advance the new active fault track of the Yalahe Fault to Yala Town near Kangding County. In Wangmu and Yala Town, we found the geological evidence for the latest fault activity that the Holocene alluvial fans were dislocated by the fault. These evidences suggest that the Yalahe Fault is a Holocene active fault, and has the seismogenic tectonic condition to produce a large earthquake, just like the Selaha and Zheduotang Faults. These also provide seismic geological evidence for the strain distribution model of the Kangding-Huiyuansi segment of the Xianshuihe Fault.     

THE TECTONIC ACTIVITY CHARACTERISTICS OF AWANCANG FAULT IN THE LATE QUATERNARY,THE SUB-STRAND OF THE EASTERN KUNLUN FAULT

It is well known that the slip rate of Kunlun Fault descends at the east segment, but little known about the Awancang Fault and its role in strain partitioning with Kunlun Fault. Whether the sub-strand(Awancang Fault) can rupture simultaneously with Kunlun Fault remains unknown. Based on field investigations, aerial-photo morphological analysis, topographic surveys and ¹⁴C dating of alluvial surfaces, we used displaced terrace risers to estimate geological slip rates along the Awancang Fault, which lies on the western margin of the Ruoergai Basin and the eastern edge of the Tibetan plateau, the results indicate that the slip rate is 3mm/a in the middle Holocene, similar to the reduced value of the Kunlun Fault. The fault consists of two segments with strike N50° W, located at distance about 16km, and converged to single stand to the SE direction. Our results demonstrate that the Awancang fault zone is predominantly left-lateral with a small amount of northeast-verging thrust component. The slip rates decrease sharply about 4mm/a from west to east between the intersection zone of the Awancang Fault and Kunlun Fault. Together with our previous trenching results on the Kunlun Fault, the comparison with slip rates at the Kunlun fault zone suggests that the Awancang fault zone has an important role in strain partitioning for east extension of Kunlun Fault in eastern Tibet. At the same time, the 15km long surface rupture zone of the southeast segment was found at the Awancang Fault. By dating the latest faulted geomorphologic surface, the last event may be since the 1766±54 Cal a BP. Through analysis of the trench, there are four paleoearthquake events identified recurring in situ on the Awancang Fault and the latest event is since (850±30)a BP. The slip rate of the Awancang Fault is almost equivalent to the descending value of the eastern part of the east Kunlun Fault, which can well explain the slip rate decreasing of the eastern part of the east Kunlun Fault(the Maqin-Maqu segment)and the characteristics of the structure dynamics of the eastern edge of the Tibet Plateau. The falling slip rate gradient of the eastern Kunlun Fault corresponds to the geometric characteristic. It is the Awancang Fault, the strand of the East Kunlun Fault that accommodates the strain distribution of the eastward extension of the east Kunlun Fault. This study is helpful to seismic hazard assessment and understanding the deformation mechanism in eastern Tibet.