Apatite Fission-Track Thermochronology in the Tamusu Area,Bayingobi Basin,NW China,and its Geological Significance

The Bayingobi basin is located in the middle of Central Asia Orogenic Belt,at the intersection of Paleo-Asian Ocean and Tethys Ocean,as well as the junction of multiple tectonic plates.This unique tectonic setting underpins the basin's intricate history of tectonic activity.To unravel the multifaceted tectono-thermal evolution within the southwestern region of the basin and to elucidate the implications of sandstone-hosted uranium mineralization,granitic and clastic rock samples were collected from the Zongnai Mts.uplift and Yingejing depression,and apatite fission track(AFT)dating and thermal history simulation analysis were performed.AFT dating findings reveal that the apparent ages of all samples fall within the range of 244 Ma to 112 Ma.In particular,the bedrock of the Zongnai Mts.and Jurassic detrital apatite fission tracks have undergone complete annealing,capturing the uplift-cooling age.Meanwhile,the AFT ages of Cretaceous detrital rocks are either equivalent to or notably exceed the age of sedimentary strata,signifying the cooling age of the provenance.A comprehensive examination of AFT ages and palaeocurrent direction analyses suggests that the Cretaceous source in the Tamusu area predominantly originated from the central and southern sectors of the Zongnai Mts.uplift.However,at a certain juncture during the Late Early Cretaceous,the Cretaceous provenance expanded to include the northern part of the Zongnai Mts.uplift.Based on the results of thermal history simulations and previous studies,it is considered that the Tamusu area has undergone four distinct tectonic uplift events since the Late Paleozoic.The first is the Late Permian to Early Triassic(260-240 Ma),which is associated with the closure of the Paleo-Asian Ocean and the accretionary orogeny within the Alxa region.The second uplift event took place in the Early Jurassic(190-175 Ma)and corresponded to intraplate orogeny following the closure of the Paleo-Asian Ocean.The third uplift event is the Late Jurassic to Early Cretaceous(160-120 Ma),which is linked to the East Asia's position as the convergence center of multiple tectonic plates during this period.The fourth uplift event is linked to the Late Early Cretaceous(112-100 Ma),driven either by the westward subduction of the eastern Pacific plate or the mantle upwelling resulting from the Bangong-Nujiang oceanic lithosphere subduction and slab break-off.The primary stress orientation for the first three tectonic uplift phases approximated a nearly SN direction,while the fourth stage featured a principal stress direction of NW.The fourth tectonic uplift event of the Late Early Cretaceous and basaltic eruption thermal event during this period likely exerted a significant influence on the formation of the Tamusu sandstone-hosted uranium deposit.

Cenozoic Exhumation and Thrusting in the Northern Qilian Shan,Northeastern Margin of the Tibetan Plateau:Constraints from Sedimentological and Apatite Fission-Track Data

The Qilian Shan lies along the northeastern edge of the Tibetan Plateau. To constrain its deformation history, we conducted integrated research on Mesozoic-Cenozoic stratigraphic sections in the Jiuxi Basin immediately north of the mountain range. Paleocurrent measurements, sandstone compositional data, and facies analysis of Cenozoic stratigraphic sections suggest that the Jiuxi Basin received sediments from the Altyn Tagh Range in the northwest, initially in the Oligocene （-33 Ma）, depositing the Huoshaogou Formation in the northern part of the basin. Later, the source area of the Jiuxi Basin changed to the Qilian Shan in the south during Late Oligocene （-27 Ma）, which led to the deposition of the Baiyanghe Formation. We suggest that uplift of the northern Qilian Shan induced by thrusting began no later than the Late Oligocene. Fission-track analysis of apatite from the Qilian Shan yields further information about the deformation history of the northern Qilain Shan and the Jiuxi Basin. It shows that a period of rapid cooling, interpreted as exhumation, initiated in the Oligocene. We suggest that this exhumation marked the initial uplift of the Qilian Shan resulting from the India-Asia collision.

Cenozoic Exhumation of Larsemann Hills,East Antarctica:Evidence from Apatite Fission-track Thermochronology

Does Cenozoic exhumation occur in the Larsemann Hills, East Antarctica？ In the present paper, we conducted an apatite fission-track thermochronologic study across the Larsemann Hills of East Antarctica. Our work reveals a Cenozoic exhumation event at 49.8 ± 12 Ma, which we interpret to be a result of exhumation caused by crustal extension. Within the uncertainty of our age determination, the timing of extension in East Antarctica determined by our study is coeval with the onset time of rifting in West Antarctica at c.55 Ma. The apatite fission-track cooling ages vary systematically in space, indicating a coherent block rotation of the Larsemann Hills region from c.50 Ma to c.10 Ma. This pattern of block tilting was locally disrupted by normal faulting along the Larsemann Hills detachment fault at c.5.4 Ma. The regional extension in the Larsemann Hills, East Antarctica was the result of tectonic evolution in this area, and may be related to the global extension. Through the discussion of Pan-Gondwanaland movement, and Mesozoic and Cenozoic extensions in West and East Antarctica and adjacent areas, we suggest that the protracted Cenozoic cooling over the Larsemann Hills area was caused by extensional tectonics related to separation and formation of the India Ocean at the time of Gondwanaland breakup.

Tectonic-thermal history and hydrocarbon potential of the Pearl River Mouth Basin,northern South China Sea:Insights from borehole apatite fission-track thermochronology

The Pearl River Mouth Basin(PRMB)is one of the most petroliferous basins on the northern margin of the South China Sea.Knowledge of the thermal history of the PRMB is significant for understanding its tectonic evolution and for unraveling its poorly studied source-rock maturation history.Our investigations in this study are based on apatite fission-track(AFT)thermochronology analysis of 12 cutting samples from 4 boreholes.Both AFT ages and length data suggested that the PRMB has experienced quite complicated thermal evolution.Thermal history modeling results unraveled four successive events of heating separated by three stages of cooling since the early Middle Eocene.The cooling events occurred approximately in the Late Eocene,early Oligocene,and the Late Miocene,possibly attributed to the Zhuqiong II Event,Nanhai Event,and Dongsha Event,respectively.The erosion amount during the first cooling stage is roughly estimated to be about 455-712 m,with an erosion rate of 0.08-0.12 mm/a.The second erosion-driven cooling is stronger than the first one,with an erosion amount of about 747-814 m and an erosion rate between about 0.13-0.21 mm/a.The erosion amount calculated related to the third cooling event varies from 800 m to 3419 m,which is speculative due to the possible influence of the magmatic activity.

Cenozoic Exhumation History of the East Kunlun Orogenic Belt Constrained by Apatite Fission-Track Thermochronology

Objective The East Kunlun Orogenic belt constitutes the first marked change in the topographic reliefs north of the Qinghai-Tibet Plateau.The Cenozoic tectonic evolution of this orogenic belt is crucial for understanding the remote deformational effects of the Eurasian plate collision and the migration track at the northern margin of the plateau.However,when and how the uplift occurred remains

Apatite fission-track study on the thermo-tectonic history of the Huainan Coalfield in Anhui Province, China: Tectonic implications for the potential coalbed methane resource

Coalbed methane (CBM) is a kind of burgeoning and enormously potential clean energy resource, and the temperature of the thermogenic CBM generation is close to that of the partial annealing zone (PAZ) of apatite fission tracks (AFT). In this study the thermo-tectonic history of the Huainan Coalfield and the potential CBM resource were studied and discussed by using the AFT method. The AFT data indicate that the apparent ages of AFT vary from 45.5 to 199.1 Ma. They are younger than the ages of their host strata (255–1800 Ma) except one sample, and the single-grain ages of AFT can be classified as a single age group for each sample. In combination with the geological setting, modeling results of the AFT ages, average lengths, and the thermal history based on the AFT single-grain ages and length distributions, some preliminary conclusions can be drawn as follows: (1) at least three thermo-tectonic events (in the periods of ～240, 140 and 80 Ma, respectively) have occurred in the study area since the Late Paleozoic. The occurrence of both the first (during 240–220 Ma) and second (during 160–120 Ma) thermo-tectonic events is possibly responsible for the establishment of the patterns of gas generation and reservoir formation. The second thermo-tectonic event also led to slight accumulation of hydrocarbons and generation of thermogenic gas; (2) the AFT ages of most coal-bearing strata lie between 50 and 70 Ma. They should represent the cooling ages and the ages of inferred uplift and denudation, as well as the possible CBM release history. Therefore, the maximum burial depth of coal-bearing strata and the denudation thickness of the overlying strata are over 3000 and 2000 m in the Upper Cretaceous and Paleogene series, respectively; and (3) subsequently, a spot of secondary biogenic and scarcely thermogenic gas generation occurred due to negligible sedimentation during the Neogene and Quaternary periods. Thus, it can be presumed that subsequent tectonism would destroy the CBM reservoir after its formation in the Huainan Coalfield, especially in its structural development region. These AFT data may be helpful for a better understanding of the thermo-tectonic history of the Huainan Coalfield, as well as of CBM generation, storage and release in the Huainan Coalfield.

Detrital apatite fission track constraints on Cenozoic tectonic evolution of the northeastern Qinghai-Tibet Plateau, China： Evidence from Cenozoic strata in Lulehe section, Northern Qaidam Basin

The Northern Qaidam Basin is located at the northeastern part of the Qinghai-Tibetan Plateau. It contains very thick Cenozoic terrestrial clastic sediments, which records the formation of the northern Qaidam Basin due to compressional deformation during the Indo-Asian collision. In this paper, we used detrital apatite fission-track thermochronology, including 4 sandstones and 2 conglomerates samples from the Lulehe section, to reveal the Cenozoic evolution of the northern Qaidam Basin. Fission-track dating indicated the source region of the Lulehe section has experiencedimportant cooling and uplifting in the Late Cretaceous(at ~85.1 Ma and ~65 Ma) and the Eocene(~52 Ma), respectively. The AFT age distribution on the section suggested that the provenance of Lulehe section sediments were mainly derived from the south Qilian Shan(Qilian Mountains) and Altun Shan(Altun Mountains), and two significantly provenance changes may occur at 43.4-46.1 Ma and ~37.8 Ma, respectively. The results may have strong constrains on the Cenozoic deformation and tectonic evolution of the northern Qaidam Basin and Qinghai-Tibet Plateau.

川东弧形带三维构造扩展的AFT记录

对川东弧形褶皱带北段、中段和南段的三条剖面,进行了7件样品的磷灰石裂变径迹(AFT)测试,结合前人已发表的4件样品,分析模拟了主要背斜的隆升-剥露热历史.结果表明川东弧形带主体构造变形时间为135→65Ma,即早白垩世早期到晚白垩世晚期.进而建立并对比了三条剖面的构造变形时序,揭示出川东弧形带的三维构造扩展历史:(1)平行于构造线走向,表现为从中心向两翼的构造扩展,弧形带中段的构造变形最早,起始时间为早白垩世早期(约135Ma),北段和南段的变形较晚,起始时间为早白垩世晚期(约100 Ma);(2)垂直于构造线走向,在弧形带北段和中段均表现为由东向西的构造扩展,而在弧形带南段,由于受到前缘华蓥山断裂的影响,表现为自西向东的变形时序.川东弧形带的三维构造扩展历史暗示了"弯山构造"的成因模式,以及华蓥山先存断裂对弧形构造的限制作用.

Mesozoic Tectonothermal Evolution of the Southern Central Asian Orogenic Belt: Evidence from Apatite Fission-Track Thermochronology in Shalazha Mountain, Inner Mongolia

Mesozoic intracontinental orogeny and deformation were widespread within the southern Central Asian Orogenic Belt(CAOB). Chronological constraints remain unclear when assessing the Mesozoic evolution of the central segment of this region. The tectonic belt of Shalazha Mountain located in the center of this region is an ideal place to decode the deformation process. Apatite fission-track(AFT) thermochronology in Shalazha Mountain is applied to constrain the Mesozoic tectonothermal evolution of the central segment of southern CAOB. The bedrock AFT ages range from 161.8 ± 6.9 to 137.0 ± 7.3 Ma, and the first reported detrital AFT obtained from Lower Cretaceous strata shows three age peaks: P1(ca. 178 Ma), P2(ca. 149 Ma) and P3(ca. 105.6 Ma). Bedrock thermal history modeling indicates that Shalazha Mountain have experienced three stages of differential cooling: Late Triassic–Early Jurassic(~230–174 Ma), Late Jurassic–Earliest Cretaceous(~174–135 Ma) and later(~135 Ma). The first two cooling stages are well preserved by the detrital AFT thermochronological result(P1, P2) from the adjacent Lower Cretaceous strata, while P3(ca. 105.6 Ma) records coeval volcanic activity. Furthermore, our data uncover that hanging wall samples cooled faster between the Late Triassic and the Early Cretaceous than those from the footwall of Shalazha thrust fault, which synchronizes with the cooling of the Shalazha Mountain and implies significant two-stage thrust fault activation between ca. 230 and 135 Ma. These new low-temperature thermochronological results from the Shalazha Mountain region and nearby reveal three main phases of differential tectonothermal events representing the Mesozoic reactivation of the central segment of the southern CAOB. In our interpretations, the initial rapid uplift in the Late Triassic was possibly associated with intracontinental orogenesis of the CAOB. Subsequent Middle Jurassic–Earliest Cretaceous cooling is highly consistent with the Mesozoic intense intraplate compression that occurred in the southern CAOB, and is interpreted as a record of closure of the Mongol-Okhotsk Ocean. Then widespread Cretaceous denudation and burial in the adjacent fault basin could be linked with the oblique subduction of the Izanagi Plate along the eastern Eurasian Plate, creating a northeast-trending normal fault and synchronous extension. However, our AFT thermochronometry detects no intense Cenozoic reactivation information of Shalazha Mountain region.

Combined apatite fission-track dating, chlorine and REE content analysis by LA-ICPMS

As one of the best established low temperature thermochronology techniques,apatite fission-track(AFT)analysis has proved an important tool for constraining a wide variety of upper crustal processes,e.g.,landscape evolution,hydrocarbon exploration and tectonics[1].The most common method employed for AFT analysis is the external detector method(EDM)[1]and this involves the thermal neutron irradiation of samples for determination of

Exhumation and Deformation of the Daba Shan Orocline as Determined from Modern River Sands Apatite Fission-Track

The Daba Shan orocline is located at the northeastern margin of the Sichuan Basin and has been inferred as a foreland thrust-fold belt of the Qinling Orogen since the Late Triassic.A complete understanding of rock exhumation history is critical to elucidate how and when this typical orocline structure is developed.Detrital apatite fission-track dating of modern river sands is employed to reveal the regional exhumation history of the Daba Shan orocline.Four age peaks are identified and interpreted as the results of tectonic exhumation.Two older age peaks at ~150–140 and ~116–86 Ma are agreement with two main shortening deformation episodes of the Yanshanian Movement in the eastern China.The other two younger age peaks at ~69 and ~37 Ma support that the Daba Shan was reactivated by the Late Cretaceous to Cenozoic deformation which were likely related to the subduction of the Pacific Ocean and eastward growth of the Tibetan Plateau,respectively.It is worth noting that in contrast to the ~150–140 Ma rapid rock uplift and exhumation,the Middle Cretaceous exhumation(~116–86 Ma) shifted southward and continued to spread to southern tips of the Daba Shan.These exhumation variations in temporal and spatial allow a southward thrust deformation with piggyback style during the Yanshanian.

四川盆地地表剥蚀量恢复及其意义

磷灰石裂变径迹（AFT）热隆升史模拟能够定量恢复盆地四维动态热隆升剥蚀过程。根据四川盆地93件磷灰石裂变径迹样品定量热史模拟表明,晚白垩世以来盆地发生了广泛的阶段式抬升剥蚀作用,即晚白垩世（65 Ma前）快速隆升剥蚀、古近纪（65-23 Ma前左右）缓慢隆升剥蚀、新近纪（23 Ma前至今）快速隆升剥蚀。晚白垩世至今盆地范围内隆升剥蚀总厚度普遍大于2.5 km,新近纪快速隆升剥蚀幅度普遍大于1 km。进一步结合31组镜质体反射率反演校正剥蚀量数据,编绘阶段性（晚白垩世以来和新近纪）四川盆地地表剥蚀量等厚图,综合表明晚白垩世以来四川盆地隆升剥蚀量等值线展布格局发生根本变化,即早期主要以NE向展布格局为主（具近NE向和E-W向特征）,新近纪则主要以近E-W向展布格局、盆地南北分异（北部地区隆升剥蚀量普遍小于2 km,南部地区普遍大于2 km）为主。四川盆地大中型油气田空间分布与晚中生代-新生代低剥蚀量具有密切联系。

郯庐断裂带对鲁西隆升过程的影响:磷灰石裂变径迹证据

郯庐断裂带(TLFZ)是一条贯穿华北的NNE向巨型断裂带。新生代以来,在郯庐断裂带的两侧及其内部发生了显著的伸展构造变形,形成了泰安-莱芜-蒙阴NW向断陷盆地群,并使鲁西块体发生了急剧的陆内伸展隆升。本文在前人研究的基础上,分别在鲁西沂山、徂徕山和蒙山三处进行了大量的样品采集,总计完成了25个样品的测试,获得了一系列新的磷灰石裂变径迹(AFT)年代学结果。结合前人已发表的裂变径迹结果,对鲁西地区新生代与伸展变形有关的剥露-隆升作用的时空分布特征、隆升剥露模式及隆升幅度进行分析,并揭示郯庐断裂带在鲁西新生代热隆升过程中的影响。主要认识有:1)新生代以来,鲁西主要经历了始新世-早渐新世和新近纪以来两期快速剥露-隆升阶段。2)始新世-早渐新世主要表现为幕式差异性快速剥露-隆升,鲁西南受NW向断层控制形成向北、向东的掀斜抬升作用,鲁西北受NE向断裂控制,形成向北、向西的掀斜抬升作用。新近纪以来,进入相对低速区域性剥露-隆升阶段。3)AFT模拟显示,与始新世-早渐新世的幕式快速剥露-隆升相比,中新世以来,鲁西剥露-隆升速率相对减小,但剥蚀量剥露-抬升量较大。故鲁西整体抬升于中新世以来。4)结合前人研究成果,新生代以来,鲁西宏观上受郯庐断裂带伸展活动影响,越靠近郯庐断裂带剥蚀量越大,局部受NW或NE向断裂控制。

东喜马拉雅构造结更新世两期抬升-剥露事件的裂变径迹证据

对出露在东喜马拉雅构造结南迦巴瓦地区那木拉峰的片麻岩进行了系统垂向上的磷灰石裂变径迹取样分析，在3393～4537m取样高程内的10个样品获得的磷灰石裂变径迹分析结果显示：中值年龄在0．64—1．58Ma之间，平均封闭径迹长度在14．0～15．2μm之间，标准偏差在1．0～3．5μm之间。其中，径迹长度数据为这一地区的首次报道，可以为数据分析的可靠性提供重要保证。通过利用裂变径迹的“香蕉图”模式分析，在这批年龄结果中进一步区分出了代表混合年龄的样品组分和代表事件年龄的样品组分。事件年龄揭示这一地区在更新世有两期抬升-剥露事件的记录，时间分别为1．10±0．24Ma和0．65±0．08Ma。而磷灰石裂变径迹年龄在剖面线上的空间分布显示山体内部的高海拔地区年龄较新，向边缘低海拔地区逐渐变老的趋势。这种分布特征与早期多雄拉-那木拉褶皱构造变形无关，是东喜马拉雅构造结地区正处于快速抬升-剥露过程中的一种指示。据地温梯度30～40％／km推算的1Ma以来的平均视剥露速率约为2．43～3．24mm／a。而结合前人的研究成果分析，这一地区快速地抬升-剥露过程可能自3Ma已发生。东喜马拉雅构造结1．10Ma和0．65Ma的抬升-剥露事件可以与青藏高原隆起过程中周缘地区的“昆黄运动”、气候转型和沙漠化等同期响应事件在年代学上建立联系。青藏高原的周缘隆起在更新世时期表现出的活动响应具有准同时的特征。

合肥盆地构造热演化的裂变径迹证据

运用裂变径迹分析方法,探讨分析了合肥盆地中新生代的构造热演化特征.上白垩统和古近系下段样品的磷灰石裂变径迹(AFl)数据主体表现为靠近部分退火带顶部温度(±65℃)有轻度退火,由此估算晚白垩世至古近纪早期合肥盆地断陷阶段的古地温梯度接近38℃/km,高于盆地现今地温梯度(27.5℃/km).下白垩统、侏罗系及二叠系样品的AFT年龄(97.5～2.5Ma)和锆石裂变径迹(ZFT)年龄(118～104Ma)均明显小于其相应的地层年龄,AFT年龄-深度分布呈现冷却型曲线形态,且由古部分退火带、冷却带或前完全退火带及其深部的今部分退火带组成,指示早白垩世的一次构造热事件和其随后的抬升冷却过程.基于AFT曲线的温度分带模式和流体包裹体测温数据的综合约束,推算合肥盆地早白垩世走滑压陷阶段的古地温梯度接近67℃/km.径迹年龄分布、AFT曲线拐点年龄和区域抬升剥蚀时间的对比分析结果表明,合肥盆地在早白垩世构造热事件之后的104Ma以来总体处于抬升冷却过程,后期快速抬升冷却事件主要发生在±55Ma.

北大巴山凤凰山基底隆起晚中生代构造隆升历史--磷灰石裂变径迹测年约束

对采自于北大巴山凤凰山基底隆起8个样品的磷灰石裂变径迹年代学分析和热历史模拟表明,凤凰山基底隆起陆内造山运动结束后的隆升历史大致可以划分为2个阶段:早白垩世中晚期(135±5～95±5 Ma)缓慢隆升,晚白垩世(95±5～65±5 Ma)快速隆升。大巴山北缘韧性剪切带黑云母^(40)Ar-^(39)Ar坪年龄证实大巴山北缘中晚侏罗世(165.7±1.9 Ma～161.2 Ma)存在快速隆升剥蚀,其与大巴山强烈陆内造山作用阶段有关;早白垩世中晚期缓慢隆升代表了陆内造山结束后的稳定阶段;晚白垩世快速隆升为一次区域性隆升事件,在秦岭、大别和武当等地区均有反映,隆升过程中伴随着强烈的伸展垮塌作用,沿秦岭造山带发育一系列伸展断陷盆地。区域对比分析表明,凤凰山基底隆起隆升历史与黄陵、汉南地块接近,但与武当地块存在明显区别,反映了秦岭造山带的不均一隆升过程。南大巴山前陆带1个样品的热史模拟结果显示,南大巴山前陆带自早白垩世以来与凤凰山基底隆起经历了一致的隆升过程。

北京千家店地区侏罗系后城组磷灰石裂变径迹分析及其地质意义

运用裂变径迹分析方法,探讨分析了千家店地区侏罗系后城组地层的构造热演化特征.千家店地区后城组上段三个磷灰石样品,AFT年龄集中在85.7～76.0Ma,小于其相应的地层年龄;平均封闭径迹长度为9.4～10.8μm,小于初始径迹长度(16.3±0.9μm),呈非对称的单峰态分布,标准偏差为2.1～2.5.后城组下段的三个AFT样品,AFT年龄集中在82.6～62.4Ma,小于其相应的地层年龄,也小于上段层位的AFT年龄;平均封闭径迹长度仅为7.2～7.7μm,远小于初始径迹长度(16.3±0.9μm),其中YQ-07样品的封闭径迹长度呈似双峰态分布,标准偏差达到3.1;显然,侏罗系样品经历了明显的中度退火行为,最大温度可能接近于90℃.AFT年龄和封闭径迹长度的规律性变化主要是由于埋深不同引起的温度差异造成的.裂变径迹热历史模拟结果表明,沉积物自进入盆地充填埋藏一直到115Ma左右,盆地沉积物达到最大埋深3000多米,盆地温度达到最大值90℃多,这一过程沉积速率达到66.7m/Ma.115Ma之后盆地处于相对稳定期,没有明显的温度波动,直到6Ma左右温度以11.7℃/Ma的速度突然下降,表明侏罗系地层遭受剥蚀,迅速上升、快速冷却直至地表,剥露速率超过了500m/Ma.

鄂尔多斯盆地西南部三叠纪末抬升剥蚀事件及热年代学记录

三叠纪末期大型鄂尔多斯盆地遭受了中生代成盆以来首次较大规模的抬升剥蚀,显著改造了中晚三叠世延长期盆地面貌,并控制了侏罗纪早期沉积格局和油藏分布,对盆地演化及矿产资源分布产生了重要影响。本文利用地质及大量钻井资料揭示了该期构造事件对盆地的剥蚀改造特征,盆地及周邻地区磷灰石裂变径迹年代学记录并约束了此次构造抬升的时限与过程;综合周邻区域构造研究成果,探讨了其发育的动力学背景。结果表明,鄂尔多斯盆地三叠纪末期的剥蚀具西南强、东北弱的特点,西南部大范围内延长组地层残缺不全,剥蚀量最大可达1000余米;前侏罗纪沉积古地貌总体呈西南高、北东低的特点;其抬升时间始于205~190Ma,西南部稍早于盆地腹部,抬升速率大于1℃/Myr,可持续至中侏罗世(约160Ma)。该期抬升剥蚀事件范围可涉及至盆地西南缘更广阔的区域,与同期秦岭造山带内出现的快速抬升冷却事件具有较好的时空耦合关系,是对秦岭造山带区域构造环境转变的响应和纪录。该研究丰富和发展了三叠纪末期构造事件在华北克拉通的影响,对该区油气、煤炭资源的进一步勘探和评价提供了新的思路,具有一定的现实意义。

Continental accretion and incremental deformation in the thermochronologic evolution of the Lesser Caucasus

Apatite fission-track analysis and thermochronologic statistical modeling of Precambrian-Oligocenc plutonic and metamorphic rocks from the Lesser Caucasus resolve two discrete cooling episodes.Cooling occurred during incremental crustal shortening due to obduction and continental accretion along the margins of the northern branch of the Neotethys.(1)The thermochronometric record of a Late Cretaceous(Turonian-Maastrichtian)cooling/exhumation event,coeval to widespread ophiolite obduction,is still present only in a relatively small area of the upper plate of the Amasia-Sevan-Akera(ASA)suture zone,i.e.the suture marking the final closure of the northern Neotethys during the Paleogene.Such area has not been affected by significant later exhumation.(2)Rapid cooling/exhumation occurred in the Early-Middle Miocene in both the lower and upper plates of the ASA suture zone,obscuring previous thermochronologic signatures over most of the study area.Miocene contractional reactivation of the ASA suture zone occurred contemporaneously with the main phase of shortening and exhumation along the Bitlis suture zone marking the closure of the southern branch of the Neotethys and the ensuing ArabiaEurasia collision.Miocene collisional stress from the Bitlis suture zone was transmitted northward across the Anatolian hinterland,which was left relatively undeformed,and focused along preexisting structural discontinuities such as the eastern Pontides and the ASA suture zone.

雅鲁藏布江中下游流域地貌差异演化的岩屑磷灰石裂变径迹证据

以西藏米林派为分界点,雅鲁藏布江中下游显示了截然不同的河流特性,下游的雅鲁藏布大峡谷作为世界第一大峡谷,围绕南迦巴瓦峰形成了马蹄形大拐弯,与中游的宽谷河道显著不同.分析了雅鲁藏布大峡谷上游米林河段和大峡谷下游地东河段的河床砂岩屑磷灰石裂变径迹(AFT)数据结果.分析显示,米林河段AFT年龄集中在10.7和26.8Ma,地东河段AFT显示年龄集中在2.5,7.1和12.6Ma.由于河床砂岩屑是上游方向裂点向下到岩屑沉积点之间流域地质体经剥蚀和水流分选平均后的产物,据此可以推定,米林上游到加查河段流域的地质体和大峡谷下游地东以上到直白河段流域的地质体经历了不同的冷却历史.从统计的结果上看,米林以上到加查的中游河段地质体经历了两个不同阶段的冷却,分别为10.7和26.8Ma前后,雅鲁藏布大峡谷所在流域地质体的冷却主要发生于2.5Ma前后,这一结果证实,以南迦巴瓦峰为核心的东喜马拉雅构造结在2.5Ma以来经历了快速和独特的构造地貌演化过程.雅鲁藏布大峡谷与雅鲁藏布江中游河段的流域属于相同的大地构造单元,即冈底斯岩带、雅鲁藏布缝合带和特提斯喜马拉雅带.但是,二者热史演化的迥然差异显示,雅鲁藏布大峡谷河段流域地质体在2.5Ma以来的冷却过程似乎不是区域构造作用的结果,显示其可能与气候因素引起的强烈剥蚀作用密切相关.