共查询到19条相似文献,搜索用时 125 毫秒
1.
2.
宽谷及宽谷阶地的形成与流域内的构造抬升活动密切相关。文中在考察阿尔金北缘断裂东段雁丹图与长草沟宽谷的基础上 ,结合古气候资料 ,探讨了晚更新世晚期以来两地河流阶地所反映的构造抬升。雁丹图自约 16 1kaBP以来发育了 3级堆积阶地 (T1,T2 与T3) ,并出露埋藏主要宽谷。 3级阶地面年龄分别约为 16 1ka ,12 8ka ,6 2ka ,反映了 3次构造抬升的存在 ,代表了 3次构造抬升发生的时间。雁丹图自约 16 1kaBP以来的构造抬升速率约为 4 8~ 4 5mm/a ;12 8~ 6 2kaBP间的抬升速率约 6 4mm/a ;6 2kaBP以来为 3 1mm/a。长草沟在 7kaBP以来有 4级阶地发育 (T3,T2 ,T′1与T1) ,均为堆积阶地 ,并出露埋藏宽谷。其中T3与T2 出露埋藏主要宽谷 ,T′1与T1出露埋藏次要宽谷。T3,T2与T′13级阶地的阶地面年龄分别约为 7ka ,3ka,2 5ka。 4级阶地反映 2次构造抬升 ,一次在约 7kaBP ,一次在 3kaBP左右。自 7 0kaBP以来长草沟的抬升速率约为 5 9mm/a ,在 7~ 3 相似文献
3.
罗云山山前断裂中段土门-贾朱村晚第四纪断错地貌特征 总被引:2,自引:0,他引:2
罗云山山前断裂位于山西临汾盆地西侧,控制着盆地的西界。通过对该断裂1∶ 5万地质填图、对河流冲沟阶地及山前断错地貌的调查,介绍了罗云山山前断裂中段土门-贾朱村晚第四纪断错地貌特征。罗云山山前发育D1、D2、D3 等3 级洪积扇,罗云山山前断裂上升盘冲沟发育T1 ~ T5 等5 级阶地。D1 洪积扇与T1、T2 阶地形成于全新世早中期;D2 洪积扇与T3 阶地形成于晚更新世中晚期;D3 洪积扇与T4、T5 阶地形成于中更新世中晚期。罗云山山前断裂中段不同部位断错地貌特征差异较大,D1 洪积扇的断错在席坊沟一带断距约2. 9m;在金殿镇峪口村南西山前断错约3m。D2 洪积扇的断错在土门镇南西堡子村约2. 5m;在杨家庄村西山前断错约4m;在景村西山前断错约6m;在襄陵镇浪泉沟南西侧山前断错约7. 7m。罗云山山前断裂中段山前断错地貌明显,其最新活动时代为全新世。其中,土门段最新活动时代为全新世早期,龙祠段最新活动时代为全新世中晚期。罗云山山前断裂中段晚更新世中晚期以来活动速率为0. 18~ 0. 54mm / a,由北向南活动呈增强趋势;全新世早中期以来活动速率为0. 4 ~ 0. 9mm / a,断裂活动主要集中于席坊沟-峪口一带。罗云山山前断裂中段从晚更新世中晚期到全新世活动速率有增大的趋势,这与该断裂上升盘冲沟阶地从晚更新世中晚期到全新世抬升速率有增大的趋势以及临汾盆地从晚更新世晚期到全新世沉降速率也有增大的趋势具有较好的一致性。 相似文献
4.
老虎山地区的第四系以山麓洪积与山区河流阶地沉积为主, ̄14C法、TL法和扩散方程法测定的近40个年代样品表明:Ⅰ级阶地为全新统,阶地形成年龄为4086±100a—4578±60a;Ⅱ级阶地为晚更新世晚期沉积,阶地形成年龄为23Ka;Ⅲ级阶地为晚更新世早中期沉积,阶地形成年龄为72Ka;Ⅳ级阶地和Ⅴ级阶地为中更新世沉积,其阶地形成年龄分别为217±35Ka和378±60Ka;早更新统仅在局部出露,可能属早更新世早期的沉积。通过与兰州九洲台黄土剖面对比,发现Ⅰ—Ⅴ级阶地的形成年龄与标准剖面中的So、S_2、S_4等层古土壤形成年龄相一致。这说明河流层状地貌的形成。除了与构造抬升有关外,还与全球冷暖交替的大气候背景有着十分密切的内在联系 相似文献
5.
河流阶地面是一种时间性、连续性非常高的层状地貌面,利用跨断层地区的河流阶地变形可以定量地判别一个地区的断层活动性。青衣江横跨龙门山断裂带南段是一条区域性大河,由于龙门山南段构造活动强烈且河流阶地被侵蚀程度严重,为了在室内更好、更快地解译青衣江河流阶地,使野外调查工作更具有针对性,本文在龙门山南段青衣江流域小关子至飞仙村一段,采用航测遥感技术制作的2m分辨率DEM和1/5万数字高程模型,基于Arc GIS和MATLAB平台进行了阶地面提取和聚类分析,以模拟野外测量阶地的流程,试图通过计算机提取,快速获取该地区更多的残余地貌面,建立起较为完整的河流阶地纵剖面。研究结果表明:野外测量数据与计算机自动提取结果相似度较高,具有较好的一致性;在完整的阶地剖面中发现了芦山盆地内部阶地具有疑似拱曲现象;在大川-双石断裂附近阶地有翘起现象,推测芦山盆地西缘阶地拱曲是由大川-双石断裂东侧的一条未知断层引起的,大川-双石断裂附近阶地的翘起现象可能是在断层逆冲推覆过程中形成的,同时结合区域年代历史数据,推测该地区(芦山盆地至大川-双石断裂)至少在晚更新世曾发生过构造活动。 相似文献
6.
龙门山断裂带北段第四纪活动的地质地貌证据 总被引:26,自引:7,他引:19
以龙门山断裂带北段中的青川断裂、茶坝-林庵寺断裂沿线的地质地貌为研究对象,在青川断裂沿线的土关铺、大安,茶坝-林庵寺断裂上的薛家沟、胡家坝等地,对断裂附近的河流地貌进行了详细的构造地貌制图。龙门山断裂带北段所在地区的河流一般发育5级阶地,T1阶地拔河高度3~5m,为全新世堆积阶地。T2阶地拔河高度10m左右,为晚更新世基座阶地。T3阶地拔河高度一般为30~35m,为晚更新世早期形成的基座阶地。T4阶地拔河高度60~70m,残留的阶地砾石层中花岗岩、砂岩砾石已经被强风化,只保留砾石的形态。T5阶地拔河高度为90m左右,阶地堆积物被剥蚀殆尽。青川断裂、茶坝-林庵寺断裂在河流的T4和T5阶地上形成宽30~180m的断层槽地,深度达8~20m,T4阶地砾石层底面落差达10~15m。T3阶地上不发育断层槽地,或断层两盘的T3阶地拔河高度一致,一些地段断层被T3阶地砾石层覆盖。因此认为,这两条断裂在T3阶地形成之前,T4阶地形成之后有过强烈的活动 相似文献
7.
《地震研究》2016,(4)
根据野外调查结果,重点阐述了维西—乔后断裂南段的活动特征。研究表明,维西—乔后断裂南段在第四纪表现出明显的活动特征,运动性质以正断层作用为主。维西—乔后断裂南段对巍山第四纪盆地有着明显的控制作用,因受其影响盆地内阶地不对称发育。箐门口、佛堂村、洗澡塘探槽揭示该断裂断错了晚更新世堆积,被错最新地层14C年龄(15 430±60)a B.P.,OSL年龄为(11.6±1.6)ka,表明其最新活动时代在晚更新世末期。洗澡塘村断层地貌清晰,西河Ⅱ级阶地上发育高2 m左右的断层陡坎。根据阶地断层陡坎高度和阶地面形成年龄估算,晚更新世以来该断裂段垂直滑动速率约为0.18~0.32 mm/a。 相似文献
8.
黄河在宁夏沙坡头形成了"几"字形河曲地貌,并在河曲凸岸发育了3级河流阶地。本文针对沙坡头大弯河流阶地特征、阶地年龄,以及大拐弯的成因进行了分析,探讨本区地貌发育的机制。结果表明:(1)沙坡头大弯3级河流阶地形成的主要原因是构造抬升作用,气候变化对此处阶地形成的作用不明显。在区域新构造活动强烈的背景下,约中更新世末期中卫盆地开始抬升,黄河河道被固定,河流下切形成本区的最高阶地T3;约在70kaB.P.、8kaB.P.形成T2、T1阶地。(2)沙坡头黄河大拐弯是由香山—天景山断裂左旋走滑位错,以及水流受地球自转偏向力的河流内生动力共同作用的结果,并且河流的内生动力作用远大于前者的贡献。 相似文献
9.
10.
《地震地质》2017,(3)
基于华山山前断裂1︰5万活动断层填图成果,对断裂沿线地层地貌、断层三角面、河流阶地、陡坎地貌以及典型断错剖面等进行了详细的研究。研究表明:1)华山山前断裂按几何结构、断错地貌表现分西段(蓝田—华县段)、中段(华县—华阴段)及东段(华阴—灵宝段)3段;2)西段及东段断裂错断了T_2阶地及马兰黄土,T_1阶地跨断裂连续,测年结果表明,T_2阶地形成于晚更新世中期,T_1阶地形成于全新世早期,由此得出西段及东段断裂在晚更新世有过活动,全新世以来活动弱或不活动;3)中段断错地貌显著,河谷两侧发育Ⅲ级阶地,跨断裂阶地均被错断,测年结果表明:T_1阶地形成于2~3kaBP,T_2阶地形成于6~7kaBP,T_3阶地形成于60~70kaBP,结合阶地陡坎高度,得出不同时段的平均垂直滑动速率:T_3—T_2时期0.4mm/a;T_2—T_1时期1.1mm/a;T_1以来1.6mm/a;4)中段在晚更新世晚期以来发生过多次活动,在石堤峪、沟峪等地见漫滩陡坎,结合文化层及炭样年龄,可知漫滩形成于距今400~600a,对比历史地震资料,漫滩陡坎应为华县1556年地震的遗迹;5)结合前人研究认为,公元1556年华县81/2级地震的发震构造为华山山前断裂及渭南塬前断裂,其它断裂是否参与有待进一步研究。 相似文献
11.
12.
The Dengdengshan and Chijiaciwo faults situate in the northeast flank of Kuantanshan uplift at the eastern terminal of Altyn Tagh fault zone, striking northwest as a whole and extending 19 kilometers and 6.5 kilometers for the Dengdengshan and Chijiaciwo Fault, respectively. Based on satellite image interpretation, trenching, faulted geomorphology surveying and samples dating etc., we researched the new active characteristics of the faults. Three-levels of geomorphic surfaces, i.e. the erosion rock platform, terrace I and terrace Ⅱ, could be found in the northeast side of Kuantanshan Mountain. The Dengdengshan Fault dislocated all geomorphic surfaces except terrace I, and the general height of scarp is about 1.5 meters, with the maximum reaching 2.6 meters. Three paleoseismic events are determined since late Pleistocene through trenching, and the total displacement of three events is about 2.7 meters, the average vertical dislocation of each event changed from 0.5 to 1.2 meters. By collecting age samples and dating, the event Ⅰ occurred about 5ka BP, event Ⅱ occurred about 20ka BP, and event Ⅲ occurred about 35ka BP. The recurrence interval is about 15ka BP; and the vertical slip rate since the late Pleistocene is about 0.04mm/a.
The Chijiaciwo Fault, however, dislocated all three geomorphic surfaces, and the general scarp height is about 2.0 meters with the maximum up to 4.0 meters. Three paleoseismic events are determined since late Pleistocene through trenching, and the total displacement of three events is about 3.25 meters, the average vertical dislocation of each event changed from 0.75 to 1.5 meters, and the vertical slip rate since the late Pleistocene is about 0.06mm/a. Although the age constraint of paleoearthquakes on Chijiaciwo Fault is not as good as that of Dengdengshan Fault, the latest event on Chijiaciwo Fault is later than Dengdengshan Fault's. Furthermore, we infer that the recurrence interval of Chijiaciwo Fault is 15ka BP, which is close to that of Dengdengshan Fault.
The latest event on Chijiaciwo Fault is later than the Dengdengshan Fault's, and the vertical displacement and the slip rate of a single event in late Quaternary are both larger than that of Dengdengshan Fault. Additionally, a 5-kilometer-long discontinuity segment exists between these two faults and is covered by Quaternary alluvial sand gravel. All these indicate that the activity of the Chijiaciwo Fault and Dengdengshan Fault has obvious segmentation feature.
The size of Chijiaciwo Fault and Dengdengshan Fault are small, and the vertical slip rate of 0.04~0.06mm/a is far smaller than that of Qilianshan Fault and the NW-striking faults in Jiuxi Basin. All these indeicate that the tectonic deformation of this region is mainly concentrated on Hexi Corrider and the interior of Tibet Plateau, while the activties of Chijiaciwo and Dengdengshan faults are characterized by slow slip rate, long recurrence interval(more than 10ka)and slow tectonic deformation. 相似文献
13.
14.
CHRONOSTRATIGRAPHIC CLASSIFICATION OF ZOIGE BASIN SINCE LATE PLEISTOCENE AND ITS TECTONIC-CLIMATE SIGNIFICANCE 
下载免费PDF全文
下载免费PDF全文 Since stratigraphic formation is influenced by tectonic activities and climate since late Pleistocene,it is important to build the stratigraphic sequence to improve the research of active tectonics,climatic change and landform factors.Zoige Basin is located in the eastern edge of Tibet Plateau where the tectonic is active and the Chinese monsoon is strong.The research of stratigraphic sequence is closely related to the tectonic activities and climate changes.Based on 26 typical stratum profiles revealed by lacustrine boreholes,terraces,peat deposits and trenching,203 isotope dating data were obtained by AMS and OSL methods.We conduct a stratigraphic correlation and classification in Zoige Basin since the Late Pleistocene.Sedimentary cycles are divided into six sedimentary rhythms (75~42ka,42~37ka,37~20ka,16~11ka,11~4ka and 4~0ka) and six marker beds (fine sand of 75~55ka and 22~20ka,gray silt deposit or gravel deposit of 13~9ka,black sandy clay containing carbonaceous deposits of 4ka,2ka and 0.3ka).There is a close relation between strata and tectonic-climate.On the one hand,sedimentary cycles coincide with climate change and have a good correspondence with ocean oxygen isotope.On the other hand,sedimentation characteristics is influenced by the persistent activities in neotectonic period of the east Kunlun fault zone on the north side and the Longrize fault zone on the west side.Marker beds and sedimentary cycles are compared with the strata in adjacent areas.It shows that climate change is the main factor affecting sedimentary cycle.The difference of stratum thickness and its spatial distribution is also affected by tectonic activity. 相似文献
15.
Three groups of alluvial terraces together with the modern floodplain mark the Postglacial development of the middle part of the Dane Valley, Cheshire. These are a High terrace group of late Pleistocene age, a Middle terrace group of late Pleistocene to early Holocene age, a Low terrace of mid–late Holocene age, and a modern (post ca. 1840 AD) floodplain. A chronology of erosion, deposition, and landform development since mid-Holocene times is established in this paper on the basis of terrace morphology, stratigraphy, sedimentology, soil analysis, magnetic mineral analysis, and four radiocarbon dates. After dissection of the Middle terrace during the early to mid-Holocene, a long period of lateral activity by the river was followed by a major aggradation phase, which formed the Low terrace surface. This was followed by dissection during the last ca. 300 years and the development of the modern floodplain since ca. 1840 AD. Various explanations for the changes during the Holocene are considered; the Low terrace aggradation appears to be related to a major phase of mediaeval soil erosion. 相似文献
16.
ANALYSIS OF THE LATE QUATERNARY ACTIVITY ALONG THE WENCHUAN-MAOXIAN FAULT -MIDDLE OF THE BACK-RANGE FAULT AT THE LONGMENSHAN FAULT ZONE 下载免费PDF全文
下载免费PDF全文 The Longmenshan fault zone is located in eastern margin of Tibetan plateau and bounded on the east by Sichuan Basin, and tectonically the location is very important. It has a deep impact on the topography, geomorphology, geological structure and seismicity of southwestern China. It is primarily composed of multiple parallel thrust faults, namely, from northwest to southeast, the back-range, the central, the front-range and the piedmont hidden faults, respectively. The MS8.0 Wenchuan earthquake of 12th May 2008 ruptured the central and the front-range faults. But the earthquake didn't rupture the back-range fault. This shows that these two faults are both active in Holocene. But until now, we don't know exactly the activity of the back-range fault. The back-range fault consists of the Pingwu-Qingchuan Fault, the Wenchuan-Maoxian Fault and the Gengda-Longdong Fault. Through satellite image(Google Earth)interpretation, combining with field investigation, we preliminarily found out that five steps of alluvial platforms or terraces have been developed in Minjiang region along the Wenchuan-Maoxian Fault. T1 and T2 terraces are more continuous than T3, T4 and T5 terraces. Combining with the previous work, we discuss the formation ages of the terraces and conclude, analyze and summarize the existing researches about the terraces of Minjiang River. We constrain the ages of T1, T2, T3, T4 and T5 surfaces to 3~10ka BP,~20ka BP, 40~50ka BP, 60ka BP and 80ka BP, respectively. Combining with geomorphologic structural interpretation, measurements of the cross sections of the terraces by differential GPS and detailed site visits including terraces, gullies and other geologic landforms along the fault, we have reason to consider that the Wenchuan-Maoxian Fault was active between the formation age of T3 and T2 terrace, but inactive since T2 terrace formed. Its latest active period should be the middle and late time of late Pleistocene, and there is no activity since the Holocene. Combining with the knowledge that the central and the front-range faults are both Quaternary active faults, the activity of Longmenshan fault zone should have shifted to the central and the front-range faults which are closer to the basin, this indicates that the Longmenshan thrust belt fits the "Piggyback Type" to some extent. 相似文献
17.
FAULTED LANDFORM AND SLIP RATE OF THE JINGHE SECTION OF THE BOLOKENU-AQIKEKUDUKE FAULT SINCE THE LATE PLEISTOCENE 下载免费PDF全文
下载免费PDF全文 The Bolokonu-Aqikekuduke fault zone(Bo-A Fault)is the plate convergence boundary between the middle and the northern Tianshan. Bo-A Fault is an inherited right-lateral strike-slip active fault and obliquely cuts the Tianshan Mountains to the northwest. Accurately constrained fault activity and slip rate is crucial for understanding the tectonic deformation mechanism, strain rate distribution and regional seismic hazard. Based on the interpretation of satellite remote sensing images and topographic surveys, this paper divides the alluvial fans in the southeast of Jinghe River into four phases, Fan1, Fan2, Fan3 and Fan4 by geomorphological elevation, water density, depth of cut, etc. This paper interprets gullies and terrace scarps by high-resolution LiDAR topographic data. Right-laterally offset gullies, fault scarps and terrace scarps are distributed in Fan1, Fan2b and Fan3. We have identified a total of 30 right-laterally offset gullies and terrace scarps. Minimum right-lateral displacement is about 6m and the maximum right-lateral displacements are(414±10)m, (91±5)m and(39±1)m on Fan2b, Fan3a and Fan3b. The landform scarp dividing Fan2b and Fan3a is offset right-laterally by (212±11)m. Combining the work done by the predecessors in the northern foothills of the Tianshan Mountains with Guliya ice core climate curve, this paper concludes that the undercut age of alluvial fan are 56~64ka, 35~41ka, 10~14ka in the Tianshan Mountains. The slip rate of Bo-A Fault since the formation of the Fan2b, Fan3a and Fan3b of the alluvial-proluvial fan is 3.3~3.7mm/a, 2.2~2.6mm/a and 2.7~3.9mm/a. The right-lateral strike-slip rate since the late Pleistocene is obtained to be 3.1±0.3mm/a based on high-resolution LiDAR topographic data and Monte Carlo analysis. 相似文献
18.
19.
Based on the 1︰50000 active fault geological mapping, combining with high-precision remote imaging, field geological investigation and dating technique, the paper investigates the stratum, topography and faulted landforms of the Huashan Piedmont Fault. Research shows that the Huashan Piedmont Fault can be divided into Lantian to Huaxian section (the west section), Huaxian to Huayin section (the middle section) and Huayin to Lingbao section (the east section) according to the respective different fault activity.
The fault in Lantian to Huaxian section is mainly contacted by loess and bedrock. Bedrock fault plane has already become unsmooth and mirror surfaces or striations can not be seen due to the erosion of running water and wind. 10~20m high fault scarps can be seen ahead of mountain in the north section near Mayu gully and Qiaoyu gully, and we can see Malan loess faulted profiles in some gully walls. In this section terraces are mainly composed of T1 and T2 which formed in the early stage of Holocene and late Pleistocene respectively. Field investigation shows that T1 is continuous and T2 is dislocated across the fault. These indicate that in this section the fault has been active in the late Pleistocene and its activity becomes weaker or no longer active after that.
In the section between Huaxian and Huayin, neotectonics is very obvious, fault triangular facets are clearly visible and fault scarps are in linear distribution. Terrace T1, T2 and T3 develop well on both sides of most gullies. Dating data shows that T1 forms in 2~3ka BP, T2 forms in 6~7ka BP, and T3 forms in 60~70ka BP. All terraces are faulted in this section, combing with average ages and scarp heights of terraces, we calculate the average vertical slip rates during the period of T3 to T2, T2 to T1 and since the formation of T1, which are 0.4mm/a, 1.1mm/a and 1.6mm/a, and among them, 1.1mm/a can roughly represent as the average vertical slip rate since the middle stage of Holocene. Fault has been active several times since the late period of late Pleistocene according to fault profiles, in addition, Tanyu west trench also reveals the dislocation of the culture layer of(0.31~0.27)a BP. 1~2m high scarps of floodplains which formed in(400~600)a BP can be seen at Shidiyu gully and Gouyu gully. In contrast with historical earthquake data, we consider that the faulted culture layer exposed by Tanyu west trench and the scarps of floodplains are the remains of Huanxian MS8½ earthquake.
The fault in Huayin to Lingbao section is also mainly contacted by loess and mountain bedrock. Malan loess faulted profiles can be seen at many river outlets of mountains. Terrace geomorphic feature is similar with that in the west section, T1 is covered by thin incompact Holocene sand loam, and T2 is covered by Malan loess. OSL dating shows that T2 formed in the early to middle stage of late Pleistocene. Field investigation shows that T1 is continuous and T2 is dislocated across the fault. These also indicate that in this section fault was active in the late Pleistocene and its activity becomes weaker or no longer active since Holocene.
According to this study combined with former researches, we incline to the view that the seismogenic structure of Huanxian MS8½ earthquake is the Huashan Piedmont Fault and the Northern Margin Fault of Weinan Loess, as for whether there are other faults or not awaits further study. 相似文献