南天山乌什前陆逆冲褶皱构造带的晚新生代构造地貌特征与地震活动

乌什逆冲断褶带位于南天山库车前陆逆冲褶皱构造带的西段,对该地区晚新生代构造活动的研究有利于加深对南天山前陆逆冲构造带的认识。本文通过对卫星遥感影像和DEM数据的解译分析,并结合研究区野外考察及典型地震反射剖面的分析,表明乌什逆冲断褶带东部地貌演化受褶皱生长影响较为深刻,发育一系列由新到老的冲积扇和风口。台兰河中游河流阶地和冰碛物均被秋里塔格断层错断,阶地断距为3.1～6.7 m,台兰期冰碛物(M_2)断距约80 m。秋里塔格断裂第四纪以来水平缩短速率约为1.23～1.59 mm/a。西部地区发育一系列逆冲断层,并发育典型的活动断层陡坎。乌什凹陷地震活动也具有明显的西强东弱的特点,地震活动具有沿断层呈带状分布的特点。乌什逆冲断褶带位于南天山造山带东西构造的转换地带,地震活动西部明显强于东部,且具有呈带状沿南天山及其山前逆冲断裂带分布的特点。历史地震分析表明上个世纪以来该区域未有7级以上地震发生,但其西部地区6级以上地震频发,随着阿克苏地区区域经济的快速发展和人口的快速增长,乌什逆冲断褶带的地震活动性应该引起地质学家更加深入的关注和研究。     

铲式逆冲断层的地貌约束：以东天山尤路都斯盆地巴音背斜构造为例

将地表河流阶地变形特征与运动学模型、地貌年代相结合,可以推测出地下断层几何形态、断层变形量与变形速率.定量限定天山山间盆地不同褶皱冲断带的几何形态、运动学和变形速率是研究天山挤压应变吸收作用的关键.在天山东部的尤路都斯盆地内,开都河横穿巴音背斜构造发育并保存了较为完整的三级河流阶地.通过详细的野外考察发现,处于巴音背斜构造后翼位置的河流阶地具有宽阔、连续和逐渐倾斜的特点,符合通过翼部旋转运动而褶皱变形的铲式逆冲断层模型,其深部根植于平面断层斜坡.基于该运动学模型并结合阶地年代,得到巴音背斜构造下伏断层晚第四纪滑动速率为（0.35-0.06）～(0.35+0.16) mm/a,地壳缩短速率为（0.23-0.04）～(0.23+0.10)mm/a.对比尤路都斯盆地北部那拉提断裂的构造应变和GPS速率揭示的东天山南北向总地壳缩短速率,认为巴音背斜构造的变形作用占尤路都斯盆地总变形作用的15%～20%,进而容纳了～2%的东天山南北向地壳应变.东天山内部的山间盆地在天山变形量分配中占据重要作用.     

晚新生代以来天山南、北麓冲断作用的定量分析

利用地表地质、二维地震和钻、测井资料建立了两条横穿天山南、北麓库车河地区和金钩河—安集海河地区的构造剖面,从几何学和运动学的角度探讨新生代以来不同序次台阶状逆断层及其相关褶皱的叠加过程、以及叠加过程中断层形态、褶皱形态与位移量之间的定量关系。生长地层和生长不整合分析表明,上新世早期(4.2～5Ma)可能是天山南、北麓新生代冲断褶皱的主要形成期,发育自天山内部的台阶状逆断层在向两侧沉积盆地扩展过程中形成多个滑脱面和断坡,断层位移在断坡位置引发褶皱变形,从而形成南北方向背斜带成排分布的构造格局。在天山南麓库车河剖面中,控制库车地区构造变形的三条台阶状逆断层位移量分别为5.7km、6.3km和18km,它们的活动时代由老到新,而位移量却逐渐增大,反映新生代以来天山南麓的冲断作用可能存在一个加速的过程。按上述数值计算,渐新世(23Ma)以来的缩短速率为1.3mm/a,上新世(5.2±0.2Ma)以来的缩短速率为3.6mm/a。在天山北麓金钩河—安集海河剖面中,山前深部楔形体内的断层位移量为16.9km,但只有6km的位移量沿中上侏罗统西山窑组煤层内的滑脱面向北传递至第二排背斜带,而至第三排背斜带,位移量已递减为0.22～0.29km。以上新世早期(4.2～5Ma)作为构造活动时间,计算出该剖面上、下构造层上新世以来的缩短速率为2.6～3.1mm/a和3.8～4.5mm/a,其中下构造层内的山前深部楔形体、霍尔果斯深层背斜和安集海背斜的缩短速率分别为3.9～4.6mm/a、1.2～1.4mm/a和0.04～0.38mm/a,这说明由于断层位移量在向北传递过程中不断被褶皱作用吸收或沿反冲断层向南消减,各排背斜带的变形强度由南向北依次减弱。     

青藏高原中段活动断层运动速度及驱动机理

在大比例尺活动断层勘测调查基础上,通过测定典型断层位移和活动时代,计算重要活动断层运动速度,分析青藏高原中段地壳水平运动规律。发现青藏高原中段晚更新世～全新世发育大量iW-iWW一近EW向活动断裂,其中昆仑山活动断裂、可可西里南缘活动断裂、通天河活动断裂、崩错活动断裂、念青唐古拉山东麓活动断裂和雅鲁藏布江活动断裂水平运动速度达6～10mm／a,风火山活动断裂、乌丽活动断裂和雁石坪活动断裂水平运动速度达3～4mm／a,唐古拉山活动断裂与格仁错活动断裂水平运动速度约2mm／a。自晚更新世以来,青藏高原中段存在显著的地壳东向运动,相对于柴达木地块的地壳东向运动速度自南北两侧向中部逐步增大,至唐古拉山地区达最大值约40mm／a。青藏高原中段断裂活动、地壳运动与近SN向构造挤压及地壳内部东向水平剪切存在动力学成因联系。     

白利雅盆地构造地貌解析及鲜水河断裂北西段水平滑移速率

白利雅盆地位于青藏高原东部,鲜水河断裂带北西段炉霍活断层与达曲活断层的斜接部位.通过野外实际考查,结合Google Earth地图发现白利雅盆地发育一系列的构造地貌:断层三角面、坡中槽、断错阶地、废弃河道、裂陷湖和阶地面变形.盆地发育的4级阶地是构造成因.废弃河道是新的断裂活动形成的新冲沟、新河道——达曲,其快速下切,废弃老河道,形成狭长的‘U’型沟谷.鲜水河断裂的北西段炉霍活断层切过T3河流阶地,说明其(白利雅以北)是在大约14.92kaB.P.以后形成的,可能预示着构造应力场的变化和白利雅盆地形成.对盆地4级阶地(T1,T2,T3和T4)的河流沉积物光释光(OSL)测年结果分别是1.06±0.06kaB.P.,1.83±0.06kaB.P.,14.92±0.76kaB.P.和42.48±2.35kaB.P,代表了相应阶地的沉积年龄.这些结果与阶地前缘陡坎断错的距离计算显示,从42.48kaB.P.和14.92kaB.P.以来,断层走向平均移动速率分别为3.73mm/a和0.85mm/a,显示从中更新世晚期以来,鲜水河断裂带炉霍活断层水平滑移有减慢的趋势.在42.48 ～ 14.92kaB.P.,14.92～1.83kaB.P.和1.83 ～ 1.06kaB.P.,相邻阶地垂向隆升或河流下切的速率分别为0.14mm/a(T4～T3),4.66mm/a(T3 ～ T2)和5.19mm/a(T2～ T1),显示从中更新世晚期以来,阶地垂直隆升或河流下切有加快的趋势.     

祁连山东段童子坝河阶地对气候变化与新构造运动的响应

通过对祁连山东段童子坝河各级阶地的年代和变形程度进行测定,得到了河流阶地的形成年代和过程,推算出民乐—大马营逆断裂的活动强度和速率,并分析了阶地形成和气候变化之间的关系。童子坝河5级阶地(年龄分别为16.70±1.81 calka BP、10 092.5±27.5 cal a BP、8127.5±72.5 cal a BP、2900±60 cal a BP、282.5±17.5 cal a BP)均形成于气候由冷转暖的阶段,属于气候成因阶地。基于断裂两侧阶地面的平面几何形态并结合上、下盘阶地横剖面同级阶地的高差,得到T4、T3、T2和T1阶地在民乐—大马营断裂处的垂直位错分别为10.6±3.1m、5.0±2.6 m、2.0±1.9 m和1.9±1.3 m,推算出全新世以来民乐—大马营断裂的垂直滑动速率为1.05±0.31 mm/a,水平缩短速率为1.02±0.60 mm/a。     

南天山库车褶皱冲断带构造几何学和运动学

印度板块与欧亚大陆的汇聚作用和持续碰撞使中亚内陆沿天山、昆仑山、阿尔金山发生变形,山脉前沿发育褶皱冲断带。南天山库车褶皱冲断带中段库车河地区发育3～4排东西走向的逆冲(掩)断层和相关褶皱,逆冲(掩)断层由北向南扩展,断层和褶皱的形成时代自北向南逐渐变新,北部山前带的变形发生于前中新世,南部秋立塔克背斜带和亚肯背斜带的变形时代为上新世(5.2±0.2Ma)。通过构造几何学和运动学分析,作者提出了库车褶皱冲断带的构造变形方式和演化模型。     

河流阶地演化与构造抬升速率——以天山北麓晚第四纪河流作用为例

构造地貌学重点关注构造和地表过程对于地形地貌演化的差异化作用,构造活动速率则是评估这种影响的一个重要指标。利用河流阶地数据计算河流下切速率从而约束构造抬升速率是常用的方法,但由于阶地成因复杂,这一方法具有不确定性。对于山前河流地貌序列,基于背斜段与未变形段的阶地拔河高度差以及阶地面形成年龄,计算得到的河流下切速率可在一定程度上消除气候等因素的影响,因此可用于估算背斜自阶地形成以来的平均抬升速率。基于该方法,本文通过研究天山北麓乌鲁木齐河、塔西河、玛纳斯河、金钩河、安集海河及奎屯河等河流在背斜段发育的主要阶地,分析了背斜抬升速率及其时空特征。天山北麓发育3排逆断裂一背斜带,结果表明位于第Ⅱ排逆断裂一背斜带的吐谷鲁背斜自约13ka以来的抬升速率为3.52mm/a,同时期霍尔果斯背斜构造抬升速率为4.8mm/a,玛纳斯背斜东端的抬升速率相对较小,为2ram/a;第Ⅲ排构造带中的独山子背斜全新世抬升速率仅为1.2~1.9mm/a。这可能表明,自山前向盆地方向晚第四纪背斜抬升速率大致呈减小趋势,与背斜地壳缩短量的空间分布规律基本一致。更多的阶地年龄数据有助于更好地揭示天山北麓晚第四纪背斜构造活动特征。     

库车再生前陆盆地冲断构造楔特征

库车再生前陆盆地冲断构造楔由一系列向南运动的逆冲断层和相关褶皱组成。冲断楔的北部以断层转折褶皱、断层传播褶皱、双重逆冲构造为主。断层楔的前缘发育了很好的滑脱膝折背斜,全为盲断层控制,形成隐蔽式前锋。冲断层的就位从中新世开始,自北向南迁移,前锋的构造形成在第四纪。造成逆冲断层的地壳水平缩短作用速度在中新世较慢,平均为0．355mm/a,上新世中期达0．82mm/a,而到上新世晚期和第四纪速度增大了约一个数量级,达到1．29－3mm/a。     

西南天山阿图什背斜晚第四纪的阶段性隆升

摘要：西南天山山前的阿图什背斜带是晚第四纪以来强烈活动的褶皱带,博古孜河横切背斜构造的中段,在背斜区形成6级基座阶地,为晚第四纪以来阿图什背斜阶段性褶皱隆起的地貌标志。 用差分GPS测量阶地纵剖面,发现T1、T2和T4阶地面在背斜的北翼坡向北,与河流的流向相反。T1、T2和T5阶地面在背斜的南翼坡向南,平均坡度分别为0.9°、1.2°和1.8°,远大于现代河床的平均坡度角0.5°。通过细颗粒石英和细颗粒混合矿物的光释光简单多片再生法(SMAR)测年,确定博古孜河T1、T2、T3、T4和T5阶地的形成年龄分别为距今约(25.0±2.6)、(42.7±4.4)、(63.1±6.3)、(96.9±9.9)和(120±10) ka BP。晚第四纪不同时段博古孜河的下切速率具有不均匀性,其中T3和T4阶地的下切速率分别为049和044 mm/a,T1 、T2和T5阶地的下切速率分别为12、169和136 mm/a。博古孜河分别在(120±10)～(96.9±9.9) ka、(42.7±4.4)～(25.0±2.6) ka和(25.0±2.6) ka至今的3个时段发生强烈的下切,应是阿图什背斜带在该时段快速构造隆起导致河流加速下切。     

青藏铁路风火山段晚第四纪断裂活动分析

地表地质调查发现,第四纪期间在风火山逆冲-褶皱构造带以发生近东西向的伸展变形为特征。在该构造带中形成切割早期近东西向挤压变形构造带、指示近东西向伸展变形、整体沿北60°东向展布的二道沟断陷盆地。断裂活动的地质、地貌证据表明,控制该盆地晚第四纪断陷的主边界断裂位于其北缘,是一条断续延伸达24 km左右、可能兼具左旋走滑性质的正断层。根据该区晚第四纪沉积物的分布和时代,并对断裂所错动的晚第四纪地质-地貌体进行初步的年代学分析,可以初步断定该断裂的晚第四纪垂直活动速率应该介于0.2~0.4 mm/a之间。     

青藏高原西北部帕米尔东北缘构造地貌与活动构造研究

新生代以来,印度板块与欧亚大陆的碰撞和持续的汇聚在青藏高原西北部的帕米尔地区造成了强烈的陆内变形,形成一系列典型的构造地貌。文章在卫片解译、DEM数据处理的基础上,结合野外地质、地貌观察与测量,对帕米尔东北缘的构造地貌与活动构造特征进行了研究,取得以下认识： 1)在英吉沙地区,通过测量地貌变形面计算出英吉沙背斜隆起高度约为230m,并利用面积平衡法估算出英吉沙背斜的最小构造缩短量约为110m,参考前人的年代学数据计算出英吉沙背斜在中更新世以来的最低隆升速率约为0.23mm/a,最小构造缩短速率约为0.11mm/a; 2)在帕米尔前缘,乌泊尔断裂为一条伴随右旋走滑分量的逆冲断裂,该断裂的右旋走滑作用错断了古近纪地层及流过断裂的河流,通过测量单次地震造成的水系错断量并参考前人研究的该地区大震复发周期约为1000年,估算出该断裂的平均走滑速率为 4.0～6.8mm/a,并推测断裂开始活动的时间大约在 2.2～3.0Ma以前; 3)对喀什地区构造地貌特征的观察与研究表明,明尧勒－喀什背斜和阿图什－踏浪河背斜可能分别为帕米尔东北缘西昆仑山山前冲断带和西南天山山前冲断带的前缘,该地区以西,帕米尔东北缘西昆仑山和西南天山两大构造系统已经发生了碰撞和拼贴。     

Geomorphic response to growing fault-related folds: example from the foothills of central Taiwan

In this paper we concentrate particularly on the geomorphological indicators left by active tectonics. In the central foothills of Taiwan, we used topography, drainage pattern and structural data to perform quantitative morphometric analysis and to determine relative age of fault-related anticlines. The Tiehchen, Tatu and Pakua ridge belt is a fault-related anticline system located in the hanging wall of the Changhua fault along the western thrust front of the foothills. Geomorphic systems are analysed with intent to detect the various responses of landforms and drainage pattern to late Quaternary deformation. Topography and drainage basin register uplift and are valuable tools to discriminate lateral propagation of an active frontal fold. Geomorphic field evidence and quantitative morphometric parameters are used to define the evolution of the rising anticline ridges and to infer tectonism style along an active front. Geometry of alluvial fans, formed along the frontal side of the anticlines, and weathered terrace deposits provide relevant information on neotectonics. Knowledge concerning these younger anticline ridges, makes this area a good example of an actively forming mountain front. We discuss in detail the origin of N045°, N095 and N120° trending oblique fault scarps which delimite numerous fault blocks. The fault scarps morphology is characterized by imbricate talus facets. Steeper topography accompanied by breaks in the slope along some transverse profiles, seems to correspond to the traces of successive uplifts.     

Trenching exposures of the surface rupture of 2008 Mw 7.9 Wenchuan earthquake,China: Implications for coseismic deformation and paleoseismology along the Central Longmen Shan thrust fault

The May 12, 2008, Mw 7.9 Wenchuan earthquake was induced by failure of two of the major faults of the Longmen Shan thrust fault zone along the eastern margin of Tibet Plateau. Our study focused on trenches across the Yingxiu–Bichuan fault, the central fault in the Longmen Shan belt that has a coseismic surface break of more than 200 km long. Trenching excavation across the 2008 earthquake rupture on three representative sites reveals the styles and amounts of the deformation and paleoseismicity along the Longmen Shan fault. Styles of coseismic deformation along the 2008 earthquake rupture at these three sites represent three models of deformation along a thrust fault. Two of the three trench exposures reveal one pre-2008 earthquake event, which is coincident with the pre-existing scarps. Based on the observation of exposed stratigraphy and structures in the trenches and the geomorphic expressions on ground surface, we interpret the 2008 earthquake as a characteristic earthquake along this fault. The interval of reoccurrence of large earthquake events on the Central Longmen Shan fault (the Yingxiu–Beichuan fault) can be inferred to be about 11,000 years according to ¹⁴C and OSL dating. The amounts of the vertical displacement and shortening across the surface rupture during the 2008 earthquake are determined to be 1.0–2.8 m and 0.15–1.32 m, respectively. The shortening rate and uplift rate are then estimated to be 0.09–0.12 mm/yr and 0.18–0.2 mm/yr, respectively. It is indicated that the deformation is absorbed mainly not by shortening, but by uplift along the rupture during the 2008 earthquake.     

Active Characteristics and Paleoearthquakes in the West Kalpin Nappe Since the Holocene,SW Tianshan Mountain

the Kalpin nappe is an important multiple thrust system. It is important to study the Cenozoic tectonic of the Tianshan Mountain. Holocene active characteristics and paleoearthquake of the Kalpin nappe can be used to evaluate the neotectonic of this area. In this paper, we accurately measured the fault scarp in the front of three thrust-fold faults and analyzed paleoearthquake events in the trenches of the Kalpin nappe. Using the ¹⁰Be exposure age, we obtained those geomorphic surface ages and paleoearthquake times. The result showed that the slip rates of the west Kalpintag fault, aozitag fault and the tuoketag fault were 1.45(+1.68/-0.44) mm/a, 0.81(+0.35/-0.19) mm/a and (0.3±0.05) mm/a, respectively since the Holocene. The slip rate indicated that the increased activity transferred from back-row fault to front-row fault and accorded with the piggy-back propagation model in the Tianshan Mountain. Displacements and recurrence intervals of paleoearthquakes was similar to the slip rate characteristics. It also showed paleoearthquakes in the front row fault were stronger than paleoearthquakes of the back row fault. The strong paleoearthquake which caused the highest surface rupture happened in the Kalpintag fault. The interval of paleoearthquakes was about 4 ka and the displacement of every paleoearthquake was about 3 m in the west Kalpintag fault; the interval of paleoearthquakes was about 2 ka and the displacement of every paleoearthquake was about 1m in the aozitag fault; the tuoketag fault ruptured only one paleoearthquake since 7 ka. The Piqiang tear fault was the tectonic result of different shortening rate between the west Kalpin system and the east Kalpin system. The shortening rate of west Kalpin system was obviously stronger than the east Kalpin system. The huge separation distance was near 20 km between the east and the west back-row fault. Because the slip rate of system transferred to the front-row fault in the piggy-back propagation model, the separation distance (~4 km) between the east and the west front-row fault was increasing.     

Submarine and onshore end moraines in southern Newfoundland: implications for the history of late Wisconsinan ice retreat

Recessional positions of the Newfoundland ice sheet 14-9 ka BP are represented by fjord-mouth submarine moraines, fjord-head emerged ice-contact marine deltas, and inland moraine belts. The arcuate submarine moraines have steep frontal ramparts and comprise up to 80 m of acoustically incoherent ice-contact sediment (or till) interfingered distally with glaciomarine sediment that began to be deposited c. 14.2 ka BP. The moraines formed by stabilization of ice that calved rapidly back along troughs on the continental shelf. The ice front retreated to fjord-heads and stabilized to form ice-contact delta terraces declining in elevation westward from +26 m to just below present sea level. Stratified glaciomarine sediments accumulated in fjords, while currents outside fjords eroded the upper part of the glaciomarine deposits, forming an unconformity bracketed by dates of 12.8 and 8.5 ka BP. The delta terraces are broadly correlated with the 12.7 ka BP Robinson's Head readvance west of the area. The ice front retreated inland, pausing three or four times to form lines of small bouldery stillstand moraines, heads of outwash, sidehill meltwater channels, and beaded eskers. Lake-sediment cores across this belt yield dated pollen evidence of three climatic reversals to which the moraines are equated: the Killarney Oscillation c. 11.2 ka BP, the Younger Dryas chronozone 11.0-10.4 ka BP, and an unnamed cold event c. 9.7 ka BP. Relative sea level fell in the early Holocene because of crustal rebound, so that outwash and other alluvium accumulated in deltas now submerged due to relative sea-level rise.     

天山北缘河流阶地形成及构造变形定量分析

新生代以来,北天山山前发育了3排冲断褶皱带。新生代晚期一系列河流普遍穿过这3排冲断褶皱带并发育了三级河流阶地。在最新构造活动的影响下,河流阶地普遍发生变形,遭受抬升。利用光释光及14C年代学方法确定了塔西河三级阶地的形成年龄,并实际测量了三级阶地的高程。结果表明吐谷鲁背斜的构造抬升速率在32．85-28．75 ka问为9．50-12．57 mm／a,12-13 ka间为9．67-14．5 mm／a,全新世则增至10．79-23．44mm／a,天山基底的平均隆升速率达到3．39-3．86mm／a。通过对天山最高一级夷平面、野外实测侏罗纪地层高程及天山发育的煤层的相对隆升速率的研究则表明天山自24 Ma以来平均的隆升速率约为0．085-0．146 mm／a。结合对北天山其他主要河流阶地的观察及研究可以看出自晚更新世一全新世以来,天山北缘的最新构造活动具有不断加快的特征。     

Quaternary Geology and Faulting in the Damxung-Yangbajain Basin

The detailed geological mapping, conducted in the Damxung-Yangbajain basin, shows that there are many types of deposits formed since the Pliocene. The oldest sediments are formed during the Pliocene. The most prominent sediments are three sets of moraines and fluvioglacial deposits. The ESR, U-series and OSL dates indicate they are formed about 700-500 ka B.P., 250-125 ka B.P. and 75-12 ka B.P. respectively and indicate that there are three glacial periods since the mid-Pleistocene in the Nyainqentanglha Range. Along the southeast side of the Nyainqentanglha Range, the main southeast dipping fault zone which bounds the Damxung-Yangbajain Graben on its western edge was mapped. The fault zone consists of three secondary fault zones and their initiation ages that the fault zones became active gradually decrease southeastward. Prominent faulting occurred in about 700-500 ka B.P., 350-220 ka B.P., -140 ka B.P. and 70-50 ka B.P. since the mid-Pleistocene. The height of fault scarps which offset the sediments f