郯庐断裂带安丘-莒县断裂江苏段古地震研究新进展

郯庐断裂带是中国东部活动性最强的断裂带,郯庐断裂带江苏段主要由5条分支断层组成,并于更新世强烈活动,其中安丘-莒县断裂持续活动至全新世,是1668年郯城■级特大地震的发震断裂。文中采用古地震探槽方法研究安丘-莒县断裂江苏段全新世以来的古地震事件,并采用¹⁴C测年方法确定古地震的时间。结合前人通过探槽揭露的古地震时间进行综合分析,认为安丘-莒县断裂江苏段全新世以来共有3次古地震事件,时间分别为距今3 000a以来、距今约6 000a和11 000a,垂直同震位移均约1m。1668年郯城8.5级地震在安丘-莒县断裂新沂段山前出露区存在地表破裂的迹象,在隐伏区表现为大量喷砂冒水现象,在探槽揭露的晚全新世地层中有密集的裂缝和砂脉。     

郯庐断裂带安丘-莒县断裂江苏段全新世活动的新证据

安丘-莒县断裂是郯庐断裂带内活动时代最新、地表形迹最明显、地震危险性最大的断裂,也是1668年郯城M8 1/2地震的发震断层。前人对郯城地震的地表破裂向S终止的位置存在多种观点,对该断裂江苏段的全新世活动情况也存在较大争议。文中通过在重岗山西侧和宿迁合欢路北侧开展的探槽开挖工作,发现了该断裂全新世活动的新证据,并对其最新活动时间进行了探讨。重岗山西侧后陈村探槽和宿迁合欢路北侧探槽都表明安丘-莒县断裂江苏段在全新世有过明显活动,推测最新一次古地震事件的发生时间为(4. 853±0. 012)～(2. 92±0. 3) ka BP。最新活动性质以走滑逆冲为主,剖面上获得的最大断错量为1m。未发现1668年郯城M81/2地震的地表破裂带到达江苏段的明确证据。     

郯庐断裂带莒县胡家孟晏地震破裂带的发现

郯庐断裂带是中国东部最主要的一条活动断裂带。在该断裂带中部,沂沭断裂东地堑的潍坊—嘉山段中发育了1条长360km的全新世活动断裂带(F5),在该全新世断裂带的北段和中段分别发生了公元70年的安丘地震和公元1668年的郯城地震。2003年底我们考察沭河断裂带时,在莒县境内发现了1条长约7km的地震破裂带,作为活动断层应该归属于F5断裂带,但其是一条独立的地震破裂段还是归属于1668年郯城8.5级地震破裂带有待于进一步的研究。尽管如此,探槽揭示出的上覆未经破坏的地层的14C年代表明,该破裂带在(2140±190)aBP以来没有过活动,因此我们认为其作为1条独立破裂段的可能性较大     

郯庐断裂带江苏段安丘-莒县断裂全新世活动及其构造意义

郯庐断裂带是中国东部重要的活动断裂带和边界构造带,其鲁苏段全新世活动断层的空间展布和古地震序列是地学关注的焦点问题,也是准确评价区域地震危险性的重要参数.以往研究工作多集中在郯庐断裂带地表地貌现象明显且有强震记录的山东段,而江苏段则研究程度相对较低,有关郯庐断裂带江苏段全新世活动断层范围和古地震序列问题存在争议.本文利用野外地质地貌调查、浅层地震勘探、钻孔联合剖面以及古地震探槽等多层次综合方法,重点开展郯庐断裂带江苏段全新世活动断层的分布和古地震序列研究.结果显示全新世时期,安丘-莒县断裂是郯庐断裂带江苏段的主要活动断层,且江苏全段该断层都是全新世活动断层.通过对比宿迁闸-皂河镇断裂南北安丘-莒县断裂的断层地貌和断层最新活动时间,并结合宿迁闸-皂河镇断裂在第四纪没有活动过等证据,推测该断层在全新世时期并不是区域阻碍破裂的断层.探槽揭示郯庐断裂带江苏段全新世两次古地震事件,事件Ⅰ限定在（6.2±0.3）-（13.4±0.7）ka B.P.之间,而事件Ⅱ限定在（2.5±0.1）ka B.P.到现今,全新世两次古地震间隔较长.基于构造类比法,安丘-莒县断裂具有深部孕震的构造特点,是区域未来强震的潜在发震构造.     

郯庐断裂带青峰岭断层上最新一次古地震事件

郯庐断裂是我国东部一条古老而今仍在活动的巨型断裂带,它经历了长期复杂的形成演化过程,对区域构造、沉积古地理、岩浆活动、成矿作用和地震活动等有重要控制作用.其总体走向北北东,一般由2～4条或更多近于平行延伸的断层组成宽达10～40 km的断裂带,切穿中国东部不同性质的大地构造单元,绵延2 400 km以上(方仲景等,1986).1668年7月25日8.5级强烈地震发生在郯庐断裂带中昌邑-大店断层(F1)上,造成了北起莒县南至郯城130 km的地震破裂带(李家灵等,1994;晁洪太等,1995).古地震研究表明,昌邑-大店断层(F1)上,全新世以来共发现了3次、震级相等于8级的古地震事件.最新一次发生在距今3 500 a,重复间隔约为3 500 a(林伟凡,高维明,1987).安丘-莒县断裂(F5)没有参与1668年地震地表破裂,它是一条晚更新世活动断层(郑朗荪等,1988;高维明等,1988;晁洪太等,1994),且被怀疑是公元前70年安丘7级地震的地震断层(晁洪太等,1994).青峰岭断层段是安丘-莒县断裂的组成部分,晚更新世活动强烈,但未发现全新世中晚期活动的证据(宋方敏等,2005).本研究通过对莒县青峰岭地震断层陡坎的考察,用探槽开挖、古地震标志(Yeats,1996;Anthony et al,2003;Klinger et al,2003;邓起东等,1984)识别、第四纪地层年代测试和确定古地震年代的逐次限定的方法(毛凤英,张培震,1995),确定了青峰岭地震断层上最新一次古地震事件的发生年代和破裂参数,突破了郯庐断裂带中段北部没有强烈地震的认识,对郯庐断裂带中段北部潜在地震危险性评价具有重要的科学价值.     

台阵资料反演沂沭断裂破碎带性质

正郯庐断裂带山东段又称沂沭断裂带,发生了中国大陆东部最大历史地震,即1668年郯城级地震,安丘—莒县断裂是其主要的破裂段;该断裂现代小震密集成带,显示深部破裂区仍未愈合。野外考察显示,位于莒南县左山次级破裂段出露长度8 km,走向N15—20°E,倾向南东,倾角70°—80°,其中位于莒南县岭泉镇左山村西的地震断层遗址显示,山脊断错接近10 m。沂沭断裂带作为郯庐深大断裂的一部分,由4条主干断裂组成了"两堑夹一垒"构造形     

郯庐断裂带安徽明光段紫阳山探槽及其意义

郯庐断裂带安徽省内段落属于该断裂带的南段,断裂构造复杂,总体上断层活动性要弱于断裂带的山东、江苏段。近年来笔者多次在苏皖交界地区开展野外地质地貌调查,发现淮河南北两侧的地形地貌存在较大差异。本研究以淮河以南的郯庐断裂带东支断裂明光段为探查重点,在明光紫阳山北侧跨断层开挖地质探槽。探槽(Tc1)显示断层表现为逆冲、张裂等活动形式,且断层向上延伸错动晚第四纪地层;结合年代样品测试结果,表明该段断层晚第四纪以来有较强的活动,最新活动时代可达晚更新世-全新世早期;探槽揭露的断层表现出多种活动形式,显示了明光段断层活动的多期次性和区域构造应力场的复杂性。     

郯庐断裂带合肥段五河—合肥断裂构造特征

五河—合肥断裂是郯庐断裂带的西边界断裂,该断裂穿过合肥市城区,是1条规模较大、切割较深的隐伏活动断裂.为了研究该断裂的浅部结构特征、空间展布以及断裂活动性,我们利用2015年在合肥盆地完成的深地震反射剖面数据,采用初至波层析成像方法得到了郯庐断裂带合肥段的浅层P波速度结构和构造形态;考虑到仅根据速度结构剖面还难以确定断裂的准确位置、断层上断点埋深、断层的近地表构造组合样式等特征,研究中跨五河—合肥断裂还完成了2条高分辨率的浅层地震反射剖面.研究结果表明：郯庐断裂带合肥段是一个由多条主干断裂构成的复杂构造带,近地表速度结构表现为凹隆相间的构造特征,且沉积盖层厚度明显受到郯庐断裂带分支断裂的影响和控制.五河—合肥断裂在P波速度结构剖面表现为高速和低速区的分界,对断裂两侧的地层沉积具有重要的控制作用,该断裂向下错断了盆地基底,向上错断了埋深21~35 m的中更新统下部地层,其最新活动时代为中更新世早期.研究结果不仅为进一步认识五河—合肥断裂浅部构造形态提供了地震学依据,还可为该区断裂两侧的城镇规划和建设中避让活动断层提供基础资料.     

郯庐断裂带安丘—莒县断裂南段(郯城—淮河)晚第四纪活动特征

通过系统的野外地质地貌调查、浅层地震勘探、钻孔联合剖面和古地震探槽等多方法手段,重点开展郯庐断裂带安丘—莒县断裂南段晚第四纪活动特征研究。结果显示安丘—莒县断裂南段在浅部由2支高倾角兼有挤压逆冲分量的断层组成,其中一支出露地表,以右旋走滑运动为主兼有逆冲分量,是全新世活动断层,而另一支为晚更新世活动断层。     

伊通—舒兰断裂带四平—靠山段14C定年及构造意义

1 研究背景 郯城—庐江断裂带(郯庐断裂带)是我国东部规模最大、延伸最长的深大断裂带,也是我国地震危险性最高的断裂构造之一.据史料记载,1668年郯城8?级地震(史称郯城大地震,位于郯城、临沂、临沭三县交界处)发生在该断裂潍坊—嘉山段郯城附近.近年来,郯庐断裂带第四纪活动地质证据被陆续发现,如郯庐断裂带江苏段全新世活动(曹筠等, 2018)以及郯庐断裂带北段(依兰—伊通断裂黑龙江通河段、吉林舒兰段,以往认为不具活动性)第四纪晚期活动证据(闵伟等,2013).此外,一些原有第四纪活动段,如新沂—五河段、乌云山—合肥段(郑颖平等,2014)等,也在近年被发现了活动证据.     

NEW EVIDENCES OF HOLOCENE ACTIVITY IN THE JIANGSU SEGMENT OF ANQIU-JUXIAN FAULT OF THE TANLU FAULT ZONE

Anqiu-Juxian Fault is an important fault in the Tanlu fault zone, with the largest seismic risk, the most recent activity date and the most obvious surface traces. It is also the seismogenic fault of the Tancheng M8 1/2 earthquake in 1668. There are many different views about the southern termination location of surface rupture of the Tancheng earthquake and the Holocene activity in Jiangsu segment of this fault. Research on the latest activity time of the Jiangsu segment of Anqiu-Juxian Fault, particularly the termination location of surface rupture of the Tancheng earthquake, is of great significance to the assessment of its earthquake potential and seismic risk. Based on trench excavation on the Jiangsu segment of Anqiu-Juxian Fault, we discuss the time and characteristics of its latest activity. Multiple geological sections from southern Maling Mountain to Chonggang Mountain indicate that there was an ancient seismic event occurring in Holocene on the Jiangsu segment of Anqiu-Juxian Fault. We suggest the time of the latest seismic event is about(4.853±0.012)~(2.92±0.3)ka BP by dating results. The latest activity is characterized by thrust strike-slip faulting, with the maximum displacement of 1m. Combined with the fault rupture characteristics of each section, it is inferred that only one large-scale paleo-earthquake event occurred on the Jiangsu segment of Anqiu-Juxian Fault since the Holocene. The upper parts of the fault are covered by horizontal sand layers, not only on the trench in the west of Chonggang mountain but also on the trench in Hehuan Road in Suqian city, which indicates that the main part of the Jiangsu segment of Anqiu-Juxian Fault was probably not the surface rupture zone of the 1668 Tancheng M8 1/2 earthquake. In short, the Jiangsu segment of Anqiu-Juxian Fault has experienced many paleo-earthquake events since the late Pleistocene, with obvious activity during the Holocene. The seismic activities of the Jiangsu segment of Anqiu-Juxian Fault have the characteristics of large magnitude and low frequency. The Jiangsu segment of Anqiu-Juxian Fault has the deep tectonic and seismic-geological backgrounds of big earthquakes generation and should be highly valued by scientists.     

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     

Tectonic Features of the M_S8.0 Wenchuan Earthquake and Its Aftershocks

The M8.0 Wenchuan earthquake occurred on the Longmenshan fault zone. Based on field investigation of the surface rupture and focal mechanism study of the aftershocks, we discuss the geological relationship of the main, secondary and triggered ruptures. The main rupture is about 200km long and can be divided into the south part and the north part. The south part consists of two parallel fault zones characterized by reverse faulting, with several parallel secondary ruptures on the hanging wall of the main fault, and the north part is a single main fault zone characterized by lateral strike-slip and reverse faulting. Compared to a 300km long aftershock distribution, the surface rupture only occupies 200km, and the remaining 100km on the northeast of the main rupture was triggered by aftershocks. Study on the ruptures of this earthquake will be useful for studying the earthquake risk evolution on the Longmenshan fault system.     

对汶川地震小鱼洞地表破裂带的调查分析

2008年5月12日的汶川8.0级地震使龙门山断裂带形成了3条同震地表破裂带,这表明有多条活动断层同时参与地震破裂,其过程复杂,现象丰富。本文对小鱼洞地表破裂带及其与另2条地表破裂带的交汇区域进行了野外调查,并对小鱼洞地表破裂带的活动性质和展布特征进行了分析。小鱼洞地表破裂带位于彭州市小鱼洞镇附近,是汶川8.0级地震形成的一条走向NW的逆冲并具有左旋走滑分量的同震地表变形带。调查结果显示,小鱼洞地表破裂带表现出明显的分段性特征：小鱼洞镇一带的中段,逆冲量和走滑量最大;小鱼洞镇向东南方向延伸的南段,逆冲量和走滑量逐渐变小;小鱼洞镇向西北方向进入山区的北段,则表现为以逆冲为主的活动性质。     

甘孜-玉树断裂当江段地表破裂遗迹与1738年玉树西北地震的讨论

对历史记载的公元1738年玉树西北地震的震级及其发震构造目前仍存有争议。卫星影像解译和野外调查发现沿甘孜-玉树断裂当江段分布一条长约75km的左旋走滑地震地表破裂带,其最大同震水平位移约2.1m。综合分析该地表破裂带特征、探槽揭露信息、测年结果以及历史文献记载等资料,认为当江段应为1738年玉树西北地震的发震断层,基于震例类比和经验公式估算该次地震的震级为71/2级。沿甘孜-玉树断裂的历史地震破裂分布显示,玉树段在隆宝镇以西存在近50km长的破裂空段;当江段距1738年地震的离逝时间也可能已经接近其地震复发周期,上述两个段落未来均存在大震危险。     

UAV Remote Sensing Information Acquisition and Analysis of MS5.4 Earthquake in Baicheng County,Xinjiang

以2021年3月24日新疆维吾尔自治区阿克苏地区拜城县M_S5.4地震为例,利用无人机进行灾区航拍,结合现场调查完成灾区地表破裂情况、建筑物毁坏程度、道路毁坏程度无人机遥感灾情获取与分析。研究结果表明,此次拜城地震产生长约5 km的地表破裂带,主破裂带具有左旋走滑特征,与主压应力场方向一致;受地震动、地表破裂、场地类型及土壤成分等因素影响,地表破裂带周边老旧砖木结构房屋不同程度受损,乡村道路不同程度破坏;此次地震造成的地表破裂和震害分布情况受断裂带控制。     

Characteristics of Late Quaternary Activity of the Gadê Segment in the Madoi-Gadê Fault Zone

Madoi-Gadê fault is an active fault in the Bayan Har block.According to field investigation,there is an earthquake surface rupture fairly well preserved on the Gadê segment of the Madoi-Gadê fault zone.The length of the rupture is approximately 50km,with a general strike of NW.The maximum horizontal sinistral displacement is about 7.6m and the maximum vertical displacement is about 4m.A large number of earthquake traces are to be found along the rupture zone,and the phenomena on the surface rupture are also...     

从两个地表破裂点的几何学与运动学特征分析汶川地震的破裂方式

汶川MS8.0地震的地表破裂出现在中央和前山2条断裂上,分别形成了235km和72km长的地震地表破裂带,而且地表破裂表现出复杂的几何学和运动学特征。文中选取了中央断裂上虹口乡桐麻坎和擂鼓镇石岩村2个地表破裂点,通过几何学与运动学特征分析其地表破裂方式。桐麻坎的白沙河河床上4条右阶斜列的主破裂西南侧发育了一条反冲断层坎,精细地形测量反映出了破裂带内的断块特征与破裂过程中的地表掀斜;擂鼓镇石岩村逆冲破裂前缘的2条次级断层形成叠瓦式结构,地貌上表现为挠曲和其上部的地震鼓包。该两点地表破裂的几何学、运动学特征分析表明,本次地震在龙门山中央断裂上的破裂方式以逆冲为主,兼有右旋走滑。这一结果与美国地质调查局、哈佛大学和中国地震台网中心提供的震源机制解基本一致。此外,桐麻坎和石岩村横切破裂带的地形剖面显示出不同的地表掀斜方向,这种不一致主要由于前者位于断裂挠曲后缘,后者位于断裂挠曲前缘     

RESEARCH ON THE CHARACTERISTICS OF QUATERNARY ACTIVITIES OF SU-XI-CHANG FAULT

Running across the urban areas of Changzhou, Wuxi and Suzhou, the NW-trending Su-Xi-Chang Fault is an important buried fault in Yangtze River Delta. In the respect of structural geomorphology, hilly landform is developed along the southwest side of the Su-Xi-Chang Fault, and a series of lakes and relatively low-lying depressions are developed on its northeast side, which is an important landform and neotectonic boundary line. The fault controlled the Jurassic and Cretaceous stratigraphic sedimentary and Cenozoic volcanic activities, and also has obvious control effects on the modern geomorphology and Quaternary stratigraphic distribution. Su-Xi-Chang Fault is one of the target faults of the project "Urban active fault exploration and seismic risk assessment in Changzhou City" and "Urban active fault exploration and seismic risk assessment in Suzhou City". Hidden in the ground with thick cover layer, few researches have been done on this fault in the past. The study on the activity characteristics and the latest activity era of the Su-Xi-Chang Fault is of great significance for the prevention and reduction of earthquake disaster losses caused by the destructive earthquakes to the cities of Changzhou, Wuxi and Suzhou. Based on shallow seismic exploration and drilling joint profiling method, Quaternary activities and distribution characteristics of the Su-Xi-Chang Fault are analyzed systematically. Shallow seismic exploration results show that the south branch of the Su-Xi-Chang Fault in Suzhou area is dominated by normal faulting, dipping to the north-east, with a dip angle of about 60° and a displacement of 3~5m on the bedrock surface. The north branch of the Su-Xi-Chang Fault in Changzhou area is dominated by normal faulting, dipping to the south, with a dip angle of about 55°~70° and a displacement of 4~12m on the bedrock surface. All breakpoints of Su-Xi-Chang Fault on the seismic exploration profiles show that only the bedrock surface was dislocated, not the interior strata of the Quaternary. On the drilling joint profile in the Dongqiao site of Suzhou, the latest activity of the south branch of Su-Xi-Chang Fault is manifested as reverse faulting, with maximum displacement of 2.9m in the upper part of Lower Pleistocene, and the Middle Pleistocene has not been dislocated by the fault. The fault acts as normal fault in the Pre-Quaternary strata, with a displacement of 3.7m in the Neogene stratum. On the drilling joint profile in the Chaoyang Road site of Changzhou, the latest activity of the north branch of Su-Xi-Chang Fault is manifested as reverse faulting too, with maximum displacement of 2.8m in the bottom layer of the Middle Pleistocene. The fault acts as normal fault in the Pre-Quaternary strata, with a displacement of 10.2m in the bedrock surface. Combining the above results, we conclude that the latest activity era of Su-Xi-Chang Fault is early Middle Pleistocene. The Su-Xi-Chang Fault was dominated by the sinistral normal faulting in the pre-Quaternary period, and turned into sinistral reverse faulting after the early Pleistocene, with displacement of about 3m in the Quaternary strata. The maximum magnitude of potential earthquake on the Su-Xi-Chang Fault is estimated to be 6.0.     

Evidence for a seafloor rupture of the Carboneras Fault Zone (southern Spain): Relation to the 1522 Almería earthquake?

High-resolution sea floor imaging (narrow beam sediment profiler) yields evidence for an offshore rupture along a strand of the Carboneras Fault Zone (CFZ) in the Gulf of Almería off southern Spain. The observed faults affect the seafloor and cut the Late Holocene sedimentary cover, hence the faults are regarded as active and the escarpments as relatively fresh. Seafloor faulting is associated with escarpments, fissures, pressure ridges, folds, and reverse faults indicating sinistral strike-slip faulting with a significant vertical displacement. Adjacent to the major fault zone secondary phenomena such as submarine slumps and slides are observed. The observed fresh escarpments imply an offshore rupture during a major earthquake along the CFZ. The southern Iberian margin and the Afro-Eurasian convergence zone form an area of moderate seismicity. However, some major events occurred, such as the 1522 Almería earthquake (EMS IX; [IGN (2005) Instituto Geografico Nacional, www.ign.es]), which affected large areas in the western Mediterranean. Different epicentral areas have been suspected, mainly along the 50 km long sinistral CFZ; however, no on-shore surface ruptures and paleoseismological evidences for this event have been found. Based on our data, a new epicentral area is proposed in the Gulf of Almería precisely along the observed sea floor rupture area, where the CFZ extend at least for 100 km offshore. Our findings suggest a specific seismic hazards and tsunami potential for offshore active and seismogenic faults in the Alborán Sea.