陕西关中盆地地热资源及壳幔温度结构的地球物理分析

陕西关中盆地地下热水资源丰富,是中国典型的隐伏型中、低温地热资源分布区.为研究关中盆地中、低温地热系统形成机理,认识深部热源条件,利用地球物理方法分析了该区壳幔温度结构.结果表明:计算得到的居里面平均深度为25.0 km,莫霍面平均深度为36.6 km,地壳平均地温梯度为22.60℃·km-1,咸礼断阶、西安凹陷、固市...     

Deep Processes of Basin Evolution:A Case Study of the Southern Songliao Basin and Adjacent Area,NE China in Mesozoic-Cenozoic

In south of the Songliao Basin and adjacent area of NE China, there are several high conductive layers in crust and upper mantle. Those layers are interpreted as detachment and rheology, which represent some features of lithosphere, asthenosphere and Moho, and related to the crust-mantle structure of the continent in the study area. The differences of the crust-mantle structures in different places in the study area reflect the differences in the movement and evolution of asthenosphere, lithosphere and crust. The differences can be summarized as follows. (1) Along the south profile of MT, the buried depth of the surface of Moho is 31 ～34 km beneath the Liaohe Basin and 35～37 km beneath the west Liaoning area. Along the north profile of MT, the buried depth of Moho is 32～33 km beneath Changtu area and 36～37 km beneath Kailu area in southern Songliao Basin. The buried depth beneath the central of the Songliao Basin is 29 km.(2) The difference of thickness of lithosphere exists in the south area and the north area of Chifeng-Kaiyuan fault. The thickness of lithosphere is about 65～120 km in the south of the fault, thickening from east to west. The top surface of asthenosphere is highly uplifted in the Liaohe Basin and the highest point is about 65 km in buried depth. The thickness of lithosphere in the north of the fault is about 60～65 km, thinner about 25 km than that in the south of the fault (West Liaoning). Deep processes such as upwelling of mantle thermal flow, extension of lithosphere, underplating, and thinning and subsidence of crust, evidenced from the crust-mantle structures were the direct forces of the basin formation in the study area during the Mesozoic-Cenozoic.     

Three-stage tectonic subsidence and its implications for the evolution of conjugate margins of the southwest subbasin,South China Sea

To reveal the tectonic characteristics of the continental margins in the southwest subbasin(SWB) of the South China Sea,a long high-resolution seismic profile was studied using empty basin subsidence.We find that tectonic subsidence features on both margins are uniformly divided into three stages:(1) slow subsidence from Tg to 18.5 Ma(synrift stage);(2) extremely slow subsidence/uplift from18.5 to 16 Ma(spreading stage);and(3) accelerated subsidence from 16 to 0 Ma(post-spreading stage).This feature differs from the classic tectonic subsidence pattern of rifted basins,which exhibits fast subsidence during synrift stage and slow subsidence during the post-rift stage.The tectonic uplift occurred during the spreading stage and the magnitude increased from the continent to the ocean,which is likely related to mantle flow during seafloor spreading.We propose that lower crustal flow played a significant role in the tectonic evolution of the continental margins of the SWB.The lower crust of the SWB margins was warmer and therefore weaker,and more prone to flow beneath the faulting center,which compensated for the upper crustal thinning caused by brittle faulting during the synrift period and thus reduced the tectonic subsidence rate.During the spreading stage,faulting attenuated rapidly,and a necking zone appeared at the continentocean transition formed by lithospheric extension.With upwelling asthenosphere,small-scale secondary mantle convection occurred under the necking zone,which raised the continental margin isotherms and increased the buoyancy.Simultaneously,secondary mantle convection lifted the overriding crust,thus the overall subsidence rate decreased sharply or even reversed to uplift.After seafloor spreading,the effect of mantle convection faded away,and sediment loading drove the lower crust to flow landward.Thermal relaxation,lower crust flow,and vanish of secondary mantle convection together led to rapid subsidence in this stage.     

山西分区地壳速度模型的建立及应用

将山西地区划分为北部、中部和南部3个区域,利用2009～2019年山西省及周边50 km范围内的地震事件波形资料,使用线性拟合、折合走时及Hyposat批量定位等方法确定各分区的地壳速度模型.采用批量定位比较残差、PTD方法测定震源深度及非天然地震事件检验等方法对分区模型进行验证,结果显示,相对山西2015速度模型,分...     

扬马延微陆块构造特征及火山型被动陆缘远端带构造演化模式

随着全球油气勘探的不断深入,北大西洋极地逐渐成为油气勘探研究的前沿领域,而扬马延矿区勘探程度极低。基于中海油冰岛矿区新采集的地震及重磁资料,结合其他有关扬马延微陆块最新的研究资料,开展了扬马延微陆块的地层和构造特征分析,以及与共轭盆地的对比,建立了扬马延火山型被动陆缘远端带的构造演化模式。研究表明:位于北大西洋格陵兰与挪威之间海域的扬马延微陆块,与北大西洋两侧陆架盆地古生代-中生代地层具有共轭特征;构造呈NE-SE向展布,发育拆离断裂体系,与挪威西部陆架盆地中生界拆离断裂体系具有相似性;构造内部受岩浆侵入及喷出等强烈影响,发育向海倾斜反射层(SDR)及岩浆溢流相沉积。在上述研究基础上,探讨了扬马延微陆块与格陵兰古陆和波罗的海古陆拉断分离的构造演化过程,认为扬马延在古生代-中生代与格陵兰古陆和波罗的海古陆为一体,在经历了古生代-中生代陆内碰撞、弱伸展到陆内裂谷和陆内热沉降后,受北大西洋拉开影响,经历了古近纪和新近纪火山型被动陆缘远端带的形成演化过程,在55 Ma第一次洋中脊扩张期,与波罗的海古陆挪威陆缘盆地分离,在25 Ma第二次洋脊跃迁时期,新生洋脊扩张导致扬马延微陆块与格陵兰古陆分离,在沉积与构造上开始与北大西洋火山型被动陆缘盆地产生分异,最终扬马延微陆块成为孤立在洋壳上的一个"弃子"。本次关于扬马延微陆块的研究揭示了火山型被动陆缘远端带在岩浆活动、拆离断裂作用下,减薄-破裂的残余陆壳及内部新生洋壳的构造面貌及板块构造背景下的演化过程。      

越南红河断裂带的深部结构、现今动力学与地震活动

展示了越南红河断裂带（RRFZ）的地壳结构，断裂与地震活动表现的主要特征，研究结果表明：（1）红河断裂带的莫霍面的深度在22－24km与30－32km之间变动，倾向北西；与之相反，此处地壳的结晶面则倾向北东且其在红河新生代拗陷的中部的深度只有8－9km。（2）在现代，红河断裂带受来自燕东方向的挤压影响，在此断裂带的北东部分明显有强烈的隆升和地震活动。（3）地震震中主要分布于7－20km的深度，大多数在10－16km的范围内。震中最小深度与最大震级之间的相关函数lgHmin=0.25Ms-0.30。（4）红河断裂带的主要孕震断裂为Lo河，Vinh Ninh,Chay河，红河，Fansipan及BinhLuc等断裂，在红河断裂带地区，最强的地震可达Mmax=5.6-6.0级，而最强烈的地震活动带在Chay河与红河一带地区。（5）红河断裂带地区区域地震危险性最高的可能在LunYen-YenBai和VietTri-Hanoi地区。     

Thermo-Rheological Structure and Passive Continental Margin Rifting in the Qiongdongnan Basin,South China Sea,China

To investigate the thermo-rheological structure and passive continental margin rifting in the Qiongdongnan Basin(QDNB),thermo-rheological models of two profiles across the western and eastern QDNB are presented.The continental shelf of western QDNB,having the lowest crustal extension factor,is recognized as the initial non-uniform extension crust model.This regime is referred to as the jelly sandwich-1(JS-1)regime,having a lower crustal ductile layer.The oceanward part of the western QDNB changes from the relatively strong JS-1 to the weak crème br?lée-1(CB-1)regime with a significantly thinned lower crust.However,the crustal extension in the eastern QDNB is significantly higher than that in the western QDNB,with conjugate faults extending deep into the lower crust.The central depression zone of the eastern QDNB is defined as the much stronger JS-2 regime,having a brittle deformation across the entire crust and upper mantle and characteristics of a cold and rigid oceanic crust.Unlike the widespread lower crustal high-velocity layers(HVLs)in the northern margin of the South China Sea,the HVLs are confined to the lower crustal base of the central depression zone of the QDNB.The HVLs of QDNB are the results of non-uniform extension with mantle underplating during the lower crustal-necking stage,which is facilitated by the lower crustal ductile layer and derived by mantle lat-eral flowing.The gigantic mantle low-velocity zone related to the Red River Fault should be a necessary factor for the east-west differential margin rifting process of QDNB,which may drive the lateral flowing in the mantle.     

VARIATIONS IN CRUSTAL THICKNESS OF THE KANE TRANSFORM IN THE NORTH ATLANTIC OCEAN

A new approach was taken to investigate the crustal stucture of the Kane transform and its aseismic extension, using high quality bathymetry and gravity data. The gravity signatures associated with variations in crustal thickness of the transform were isolated from the observed free-air anomaly,was continued downward to the mean depth of the crust/mantle interface and converted on to the relief onthat surface. The crustal thickness of the transform was then calculated by subtracting seawater depth from the depth of the gravity-inferred crust/mantle interface. 3-D gravity investigation results indicate that the Kane transform and adjacent areas are associated with a crust thinner than normal oceanic crust. The transform trough is largely underlain by a crust less than 4.5kin thick and in the nodal basins the crust may be as thin as 3 kin. The crust beneath the fracture zone valley is 4 - 5.5 km thick. The rift valleys on the spreading segments are also characterized by thin crust (4 - 5 km thick). Thin oceanic crust extends to 20-30 km from the transform axis,except for some localized places such as the inside comerhighs adjoining the ridge-transform intersections. These gravity-inferred results match fairly well with limited published seismic results. Thinning of the crust is mainly attributable to a thin layer 3, which in turn may be explained by the combined effects of reduced magma supply at the ends of the spreading segments and tectonic activities in the region.     

张渤地震构造带中西段及邻区深部构造探测

利用穿过张渤地震构造带中西段及邻区的多条地震测深资料．详细研究了张渤地震构造带中西段及邻区的地壳深部速度结构与构造。结果表明,该区地壳深部速度结构与构造在纵向和横向上具有明显的不均一性。在三河-平谷8级震区、延庆-怀来盆地及张家口附近地区莫霍面埋深分别为35、39和42km,其地壳厚度由东至西逐渐增加。该区基底断裂发育。在其深部,根据地震波动力学及运动学特征和二维速度结构中的地震界面与速度等值线起伏变化推测,在大兴、延庆、涿鹿等地均存在深部断裂带,在深部断裂带一侧或两侧的上地壳存在6．0km／s左右的低速层（体）。     

青藏高原东南缘壳幔力学耦合及其动力学意义

现代大陆动力学及构造学研究认为,壳内软弱带控制着地壳与地幔间相互作用的强弱,制约岩石圈层间的耦合关系,同时也影响地块的相互作用方式。这种耦合作用可以通过比较不同深度的形变和应力的相关特征来分析。青藏高原东南缘20～35 km的深度广泛存在低速带,有可能在现今地震及构造活动区内由壳内部分熔融承担了潜在的解耦功能。基于1999～2015年GPS坐标时间序列数据得到速度场,结合前人给出的SKS剪切波分裂数据,分析该区水平方向形变耦合特征;同时搜集莫霍面和岩石圈底面形变数据,给出垂向上的形变耦合特征。利用EGM2008重力模型的11～36阶球谐系数计算青藏高原东南缘岩石圈底面地幔对流应力场;搜集并整理2000年至今的1 131个震源机制解数据,采用区域应力张量阻尼反演法得到该区多震层应力场;进一步分析两种应力场的相关性。在ABAQUS软件中建立青藏高原东南缘岩石圈三维粘弹性有限元模型,同时加入上地壳的边界位移约束条件和底面地幔对流拖曳力加载条件,分别对水平方向和垂直方向的应力应变作分析,并给出强震剖面结果,探讨壳幔耦合强震孕育机制,据此分析青藏高原东南缘各个断层的地震危险性。研究认为,应力的不均匀发展是应变能积累的关键,同时垂向上圈层间的耦合关系极大地影响块体间的作用方式;壳内软弱带广泛发育的块体应力出现分层现象,边缘区域横向纵向应力变化明显,与之接触的上伏地壳地震危险性较高。     

板块构造单元划分方法探讨——以青藏高原为例

作者认为板块构造单元划分应遵循4个基本原则,即系统原则、时空原则、层次原则,综合原则。在此基础上,提出岩石圈板块、地壳板段、构造沉积环境、板片构造(薄皮构造)四级划分方案。青藏高原岩石圈厚度120—170km,地壳厚度大密度低,上地幔厚度小密度大,莫霍面呈一“盆地”状。上地壳厚15—30km;壳内低速层厚5—10km,呈南浅北深产出;下地壳平均厚25km,藏北、青南有明显分层,藏南与固体上地幔成突变,缺少壳幔层。壳幔混合层,埋深50—65km,厚度13—21km。固体上地幔,平均厚度50—70km。本文将青藏高原划分为5个板块(一级单元),7个板段(二级单元),30个构造沉积环境(三级单元),着重对主要板块构造单元包容的主要板段特征进行了分析与研究,对秦祁昆板块构造域的范围与演化特征给予了分析。     

1970年通海Ms7.7地震后青藏高原东南部小江断裂带和红河断裂带的库仑应力变化研究

基于1970年通海MS7.7地震的破裂参数,利用模型对不同岩石圈流变特性下库仑破裂应力的变化进行研究,探讨通海地震的静态同震变形和短期震后变形对小江断裂带和红河断裂带上潜在地震活动的影响。结果表明,这2条断裂带的一些断裂段在深度7.5 km处库仑破裂应力增量(ΔCFS)的震时变化达到0.12~0.50 bar,48 a后由于下地壳和上地幔的应力松弛,相同位置的库仑破裂应力增量高达0.22~0.90 bar。说明1970年通海MS7.7地震增强了小江断裂带和红河断裂带上潜在的地震活动性,在将来的地震工作中应加强对其的研究,并通过增加野外观测的方式监测其地震活动与地壳运动模式。     

Tectonic Characteristics and Evolution of Bohai Bay Basin, China

Synthetical analyzing the deep geophysical data within Bohai bay basin the authors detect the deep crustal structure presenting high geothermal flux, thinned crust and arched Moho discontinuity, and the basin basement belongs to rigid continental crust. The development of the basin was controlled by two - dimensional faults in NNE and NWW directions. The tectonic units of the basin can be subdivided into three structural divisions: the east, middle and west division. The basin is considered as a continental rift. The tectonic background and regional right - lateral stress field during the late Cretaceous and Paleogene were a compound result of the Kula Plate W - directional subducting under Eurasia Continental Plate in 80 ～ 74Ma and the Philippine sea Plate W -directional subducting under the Eurasia Continental Plate since 60Ma, the long-rang effect of the India Continental Plate wedging into the Eurasia Continental Plate and of the Siberia Plate SE - directional relatively moving.     

深地震测深揭示的济阳坳陷地壳结构特征

对穿过济阳坳陷的3条深地震测深剖面进行解释、对比分析显示,济阳坳陷地壳结构分为上、中、下3层,莫霍面深度在31 km左右,区域起伏变化不大,深浅部构造呈镜像对称关系。济阳坳陷内中地壳存在低速体发育,为其顶面滑脱层的发育以及滑脱构造的形成提供了必要条件,也导致上下地壳厚度的横向变化存在差异。惠民凹陷下方Pm震相之前出现P4震相表明,其莫霍面以壳幔过渡带形式存在;东营凹陷下方Pm震相尖锐,其莫霍面则表现为一级间断面性质,体现了不同凹陷深部壳幔作用的差异。结论表明,济阳坳陷地壳结构具有典型的华北地区地壳结构特征,上下地壳厚度横向变化差异与滑脱构造密切相关,而莫霍面性质差异与深部软流圈上涌以及下地壳小规模拆沉有关。     

利用卫星重力资料反演地壳及岩石圈厚度

地球外部重力场由地球内部物质分布所决定,由于地壳与地幔、岩石圈与软流圈存在着较大的物性差异,利用重力资料可以确定莫霍面和岩石圈底面深度。基于上述结论,利用ＯＳＵ９１全球重力位模型数据进行了反演,计算结果表明,地壳和岩石圈厚度与地形相关,大陆地壳、岩石圈较厚,海洋则相反。     

The study of magnetic anomalies over Davis Strait

Magnetic data collected during several cruises in Davis Strait show north-south lineations over most of the area. The central positive magnetic zone coincides well with a major gravity low. These results suggest that the magnetic anomalies were produced by seafloor spreading and that the gravity low marks an extinct spreading center in Davis Strait. Comparison between the geomagnetic polarity time-scale and dated anomalies in Labrador Sea suggests identification of anomalies 13–27 (37 to 62 MY). In southern Davis Strait (63°N), the spreading rates are 8.4 mm/y. east of the spreading center, and 2.7 mm/y to the west. In northern Davis Strait (66°N), the spreading rates are 4.5 mm/y east of the spreading center, and 2.1 mm/y to the west. Seafloor spreading in Davis Strait was there-fore very asymmetrical, with decreasing rates from south to north. Spreading is interpreted as having begun at 61–63 M and ending at 37 MY. Three fracture zones have been delineated, suggesting oblique spreading about the ridge axis in the Davis Strait. A distinct northeast-southwest anomaly zone is interpreted as the, expression of faults caused by volcanically-induced vertical crustal movements, and not by spreading-related horizontal crustal movement. Faulting along this northeast-southwest anomaly zone is inferred to have occurred after the spreading and before 30 MY. The magnetic anomalies off Cape Dyer are proposed to be different from the anomalies striking in northeast-southwest direction. The Cape Dyer anomaly is interpreted as being formed at 58 MY while the northeast-southwest anomaly zone formed more recently. This work was carried out at Department of Geology and Centre for Marine Geology, Dalhousie University, Halifax, N. S. Canada.     

Crustal structure revealed by a deep seismic sounding profile of Baijing-Gaoming-Jinwan in the Pearl River Delta

The Pearl River Estuary area, located in the middle part of the southern China coastal seismic belt, has long been considered a potential source of strong earthquakes above magnitude 7.0. To scientifically assess the potential strong earthquake risk in this area, a three-dimensional artificial seismic sounding experiment, consisting of a receiving array and seabed seismograph, was performed to reveal the deep crustal structure in this region. We used artificial ship-borne air-gun excitation shots as sources, and fixed and mobile stations as receivers to record seismic data from May to August 2015. This paper presents results along a line from the western side of the Pearl River Estuary to the western side of the Baijing-Gaoming-Jinwan profile. A two-dimensional velocity structure was constructed using seismic travel-time tomography. The inversion results show that the Moho depth is 27 km in the coastal area and 30 km in the northwest of the Pearl River Estuary area, indicating that the crust thins from land to sea. Two structural discontinuities and multiple low-velocity anomalies appear in the crustal section. Inside both discontinuity zones, a low-velocity layer, with a minimum velocity of 6.05 km s~(-1), exists at a depth of about 15 km, and another, with a minimum velocity of 6.37 km s~(-1), exists at a depth of about 21.5 km between the middle and lower crust. These low velocities suggest that the discontinuities may consist of partly molten material. Earthquakes with magnitudes higher than 5.0 occurred in the low-velocity layer along the profile. The deep Kaiping-Enping fault, rooted in the crust, may be one of the most important channels for deep material upwelling and is related to tectonic movement since the Cretaceous in the Pearl River Delta tectonic rift basin.     

新疆南天山地区地壳三维速度结构：来自近震层析成像的结果

利用新疆测震台网在南天山地区架设的固定和流动台站记录的近8 a的观测资料,通过近震走时层析成像技术获得地壳三维速度结构,并利用三维速度结构对该区域的近震事件进行重定位。重定位后走时残差均方根由1.29 s减小为0.64 s,震源位置的不确定性约为0.1 km。三维速度结构显示,区域内速度结构表现出明显的横向和纵向不均匀性,5 km深度处,阿图什背斜和柯坪断裂以北表现为高速异常,以南表现为低速异常,波速比整体上以高值为主;15 km和20 km深度处,研究区P波速度主要以高速异常为主;25~30 km深度处,研究区内P波高速异常转变为以近NE向低速异常为主,波速比也以近NE向低值异常为主。区域内地震活动性与地壳速度结构具有较强的对应性,震源主要集中在P波高低速交界处的高速区域,同时波速比也偏向高波速比一侧。震源位置集中区的下方存在低速条带,该条带可为应变能的积累和释放提供有利的环境基础。     

3D主动源地震折射/反射联合快速波前成像研究

基于深地震测深震相记录特征及最新发展起来的快速波前追踪方法,利用理论合成的3D主动源地震折射/反射数据,对强速度对比及复杂Moho结构的重建进行数值模拟计算。结果表明,折射震相Pg对上地壳细结构有较高的分辨,宽角反射震相PmP可较好地约束中下地壳及Moho界面的细结构特征,但对浅部结构的分辨力较差,折射和反射地震的联合成像可有效恢复深浅部3D空间的强速度对比结构及Moho界面形态特征。     

辽宁及邻区S波速度结构反演

利用辽宁及邻区70台地震仪2012年噪声连续波形记录,基于背景噪声层析成像法获取研究区下方10~40 s的相速度结构。利用得到的基阶面波相速度频散曲线,通过马尔科夫链蒙特卡洛(MCMC)法反演研究区下方10~40 km深度处的三维S波速度结构。结果表明,研究区浅层及中上地壳的S波速度分布与地形地貌有较好的对应关系,高低速过渡带更易形成孕震区。中下地壳至上地幔顶部的S波速度结构更多受控于莫霍面的起伏状态及深大断裂。海城至大连最后延伸至辽东湾的区域下方30~40 km深度范围内一直存在一个“弧形”的低速异常体,推测该区域存在热物质上涌现象。纵剖面C-C′的辽阳至伊通段下方15 km处存在椭圆形低速体。