华北克拉通破坏动力学过程研究中的几个构造问题

华北克拉通破坏问题,是通过对古生代时期和新生代以来华北东部岩石圈厚度、热状态、岩石圈地幔组成与时代等特征的比较研究中,逐渐认识到的一个重大的大陆构造动力学问题。岩石圈厚度的巨大变薄是克拉通破坏的重要标志之一,已有的构造动力学模型从不同角度着重讨论了克拉通岩石圈是如何减薄的问题,但由于岩石圈减薄远不是克拉通破坏的全部,因此,即使已有动力学模型可以对减薄过程给出比较合理的解释,也还难以成为克拉通破坏的综合动力学模型。文中针对目前流行的华北克拉通岩石圈减薄动力学模型存在的问题,提出了在构建克拉通破坏综合动力学模型时需要关注的一些主要构造问题:(1)从构造变形、沉积作用、火山活动及其事件序列特征角度,甄别和评价主动裂谷作用和被动裂谷作用在克拉通破坏过程中所发挥的作用;热 化学侵蚀岩石圈减薄模型可能需要与上述裂谷作用模型相结合,才可能成为克拉通岩石圈破坏的候选模型。(2)从拆沉相关岩浆侵入和火山活动时空演变规律、地壳表层快速隆起及相关沉积作用和构造变形、地壳热状态异常、拆沉引起的热弱化地壳对区域应力场的响应、拆沉导致的局部应力场模拟等方面展开研究,检验、充实或修正岩石圈拆沉模型。(3)从区域构造变形和相关沉积作用、火山活动相结合的综合研究角度,探索华北克拉通的破坏是在古老克拉通基础上的直接破坏,还是在古老克拉通基础上经历了造山作用过程之后的造山带伸展垮塌,这是涉及华北克拉通破坏动力学模型建立的根本问题之一。     

断陷湖盆早期浅水三角洲沉积——以高邮凹陷永安地区戴一段为例

浅水三角洲作为沉积学和油气勘探领域的热点,目前研究主要集中在大型拗陷型盆地内,对断陷湖盆关注较少。通过充分调研区域地质背景并结合永安地区戴一段的岩心、录井、测井、地震、分析化验等资料进行系统研究后认为,戴一段处于断陷早期,地形较为平缓,水体宽浅且波动频繁,气候温暖湿润,物源供给充足,具备形成浅水三角洲的有利沉积条件。研究区浅水三角洲为近源沉积,以牵引流为主;砂岩中多见强水动力沉积构造;垂向上发育进积、加积的沉积序列,具平行、亚平行及叠瓦状地震反射特征;以前缘亚相为主体,相带宽阔,可分为内、外前缘沉积,水下分流河道构成主要骨架砂体;在向湖推进过程中受沉积物可容纳空间与沉积物补给量比值(A/S)变化的影响较大,不同成因砂体类型及沉积样式呈现有规律的分布。基于以上分析,最终建立了断陷湖盆早期浅水三角洲的沉积模式,在一定程度上对丰富浅水三角洲的沉积学认识并拓展永安地区乃至整个高邮凹陷斜坡带油气勘探的领域和范围具有一定指导意义。     

Influence of fault reactivation during multiphase rifting: The Oseberg area,northern North Sea rift

Multiphase rifts tend to produce fault populations that evolve by the formation of new faults and reactivation of earlier faults. The resulting fault patterns tend to be complex and difficult to decipher. In this work we use seismic reflection data to examine the evolution of a normal fault network in the Oseberg Fault Block in the northern North Sea Rift System – a rift system that experienced Permian – Early Triassic and Middle Jurassic – Early Cretaceous rifting and exhibits N-S, NW-SE and NE-SW oriented faults.Both N-S- and NW-SE-striking faults were established during the Permian – Early Triassic rifting, as indicated by Triassic growth packages in their hanging walls. In contrast, the NE-SW-striking faults are younger, as they show no evidence of Permian – Early Triassic growth, and offset several N-S- and NW-SE-striking faults. Structural analysis show that a new population of NW-SE-striking faults formed in the Lower – Middle Jurassic (inter-rift period) together with reactivation of N-S-striking Permian – Early Triassic faults, indicating a NE-SW inter-rift extension direction.During the Middle Jurassic – Early Cretaceous rifting, faults of all orientations (N-S, NW-SE and NE-SW) were active. However, faults initiated during the Middle Jurassic – Early Cretaceous rifting show mainly N-S orientation, indicating E-W extension during this phase. These observations suggest a reorientation of the stress field from E-W during the Permian – Early Triassic rift phase to NE-SW during inter-rift fault growth and back to E-W during the Middle Jurassic – Early Cretaceous rift phase in the Oseberg area. Hence, the current study demonstrates that rift activity between established rift phases can locally develop faults with new orientations that add to the geometric and kinematic complexity of the final fault population.     

塔里木盆地新元古代裂谷盆地层序样式

塔里木盆地是位于Rodinia超大陆边缘的小陆块,随着新元古代Rodinia超大陆裂解,在塔里木盆地周边和内部形成了大量裂谷盆地,通过对裂谷体系的演化和地层充填特征研究,对认识Rodinia超大陆的裂解过程具有重要意义。按照盆地动力学、层序地层学和沉积学等理论为指导,以露头、钻井和地震剖面为基础,进行不整合面、层序地层和沉积相研究,探讨层序样式及控制因素,分析塔里木盆地和扬子盆地裂谷演化过程的差异。塔里木盆地新元古代南华系—震旦系为1个一级层序,由两个一级不整合界面限定——Td(南华系/前南华系基底)和T1(震旦系/寒武系),其中Td界面为塔里木运动导致,即新元古代早期—中期Rodinia大陆裂解作用开始,而T1界面与塔里木板块内部表现为垂直上升作用的柯坪运动有关。按照裂谷盆地演化的三个阶段——快速裂陷期、稳定沉降期和裂谷萎缩期,分为3个二级层序。快速裂陷期为二级层序SQ1,发育大量小型地垒—地堑盆地,水体由浅变深,发育滨浅海相—河流—三角洲等沉积;稳定沉降期为二级层序SQ2,盆地连通性加强,形成统一的盆地,发育滨岸—三角洲—浅水陆棚—盆地相;裂谷盖处于裂谷萎缩阶段,受地幔柱冷却,地壳回弹影响,断裂活动减弱并逐渐停止,地层向隆起上超,地层分布范围广,主要发育碳酸盐岩台地相,该阶段构成二级层序SQ3。受到海平面变化、冰川和气候等因素控制,发育13个三级层序,其中冰期发育冰碛岩—盖帽碳酸盐岩的一类特殊三级层序。南华纪末期的Marinoan冰期是全球冰期事件,相应在中国南方扬子地区发育典型的南沱组冰碛岩和陡山沱组白云岩的组合,而塔里木盆地库鲁克塔格地区为特瑞爱肯组冰碛岩之上直接覆盖了扎摩提克组的粉砂岩地层,不发育盖帽碳酸盐岩。这和裂谷体系演化有关,塔里木裂谷盖形成的滞后了约70Ma,冰碛岩沉积之后,水体快速加深,碎屑物质供给充足,没有适合碳酸盐岩的生长环境。通过新元古代裂谷盆地的结构样式和层序地层研究,对认识新元古代构造、沉积环境,和烃源岩、储层的分布等具有重要在指导意义,而不同盆地之间大陆裂解响应过程的差异也是值得深入研究问题。     

The Neoproterozoic continental rift magmatism of the eastern Jiangnan orogen: new evidence from the mafic sheets in northern Zhejiang Province,South China

Massive mafic sheets were recently recognized intruding the Neoproterozoic strata in Fuyang area, eastern Jiangnan orogen. Geochronological, geochemical, and isotopic studies were carried out to understand their mantle source, crust–mantle interaction, and tectonic setting. LA-ICP-MS U-Pb zircon data indicate that the sheets were generated at 808 ± 7 Ma. The mafic sheets consist of two groups: high Ti and low Ti. They are enriched in light rare earth elements (LREE; 3.3–5.3 ppm) and show negligible Eu anomalies (δEu = 0.77–1.12). They also have strong large-ion lithophile element (LILE; Sr, K, Rb, Ba) enrichment, moderately strong high-field-strength element (HFSE) enrichment (except for Nb-Ta depletion), and positive εNd(t) (5.1–9.1). Geochemical and isotopic data indicate that the mafic sheets were generated from a depleted asthenospheric mantle source. The high-Ti mafic sheets have higher HFSE contents and less Nb-Ta depletion than the low Ti series, indicating a lower degree of partial melting and crustal contamination. The mafic sheets grew in a within-plate setting, concurrent with the ~820–750 Ma rifting events in the eastern Jiangnan orogen. They are likely related to the breakup of the Rodinia supercontinent.     

湘西通道地区新元古代长界橄榄辉石岩中单斜辉石矿物学特征及其板内裂谷成因论证

湘西通道地区长界橄榄辉石岩主要组成矿物为单斜辉石、橄榄石和斜长石,还具有少量的Ti—Fe氧化物。本文利用电子探针对江南造山带西段湘西通道地区长界橄榄辉石岩单斜辉石进行了详细的矿物学研究,研究结果表明单斜辉石属于顽透辉石和普通辉石。长界橄榄辉石岩单斜辉石较富镁而贫铁,并且还具有高硅、贫碱、低钙的特征,其母岩浆属于拉斑玄武系列。单斜辉石温压计算结果显示,橄榄辉石岩的形成温度为1260～1383℃,压力为1.5～2.6GPa,深度为50～86km,平均深度为73km。整体来看,长界橄榄辉石岩形成的温度基本与软流圈地幔的温度(1280～1350℃)相当,其形成深度为约73km的地幔深处,且在这种温压条件下,软流圈地幔可以发生减压熔融。单斜辉石的成分特征显示示长界橄榄辉石岩是板内拉斑玄武岩,指示其构造背景为裂谷环境。另外,单斜辉石具低的Al_2O_3(0.02%～5.51%)、TiO_2(0～0.46%)和Na_2O(0.01%～1.44%)的特征,这可能是单斜辉石寄主岩石岩浆源区受到俯冲熔体/流体的交代改造作用所导致。结合作者和前人的研究结果,我们推测长界橄榄辉石岩源区为软流圈地幔,其形成可能与裂谷作用导致软流圈物质上涌并发生熔融有关,且在形成长界橄榄辉石岩之前,软流圈地幔已经遭受过俯冲熔体/流体的交代改造作用。     

江南造山带西段桂北龙胜地区金车辉长岩矿物化学研究及其地质意义

桂北龙胜地区位于江南造山带西段,本文利用电子探针对桂北龙胜地区金车辉长岩单斜辉石和斜长石进行了详细的矿物学和矿物化学研究,研究表明单斜辉石的成分为Wo27~28En47~57Fs15~22,属于普通辉石,斜长石的成分为An1.35~9.05Ab90.34~97.45Or0.36~1.05,为钠长石。单斜辉石温压估算结果显示,其形成温度为1 250~1 350℃,该温度基本与软流圈地幔温度(1 280~1 350℃)相当,其形成压力为1.31~2.25 GPa,对应深度为43.2~74.3 km。单斜辉石成分特征指示金车辉长岩为板内拉斑玄武岩,结合区域地质特征,推测金车辉长岩是裂谷构造背景下软流圈地幔物质上涌并发生减压熔融的产物。     

The Cenozoic Volcanoes in Northeast China

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Review of the tectonics of the Levant Rift system: the structural significance of oblique continental breakup

The Levant Rift system is an elongated series of structural basins that extends for more than 1000 km from the northern Red Sea to southern Anatolia. The system consists of three major segments, the Jordan Rift in the south, El Gharb–Kara-Su Rift in the north, and the Lebanese Fault splay in between. The rifted parts of this structural system are accompanied by intensively uplifted margins that mirror-image the basinal pattern, namely, the deeper the basin—the higher its margins, and vice versa. Uplifts also occur along the fault splay section. The Jordan Rift comprises axial basins that diminish in size from the south northwards, and are separated from each other by shallow threshold zones along the axis of the rift, where the margins are also subdued. The Lebanese Fault splay consists of five faults that emerge from the northern edge of the Jordan Rift and trend like a fan between the north and the northeast. One of these faults connects the Jordan and El Gharb–Kara-Su rifts. The Levant Rift and its uplifted margins started to develop in the middle-late Miocene, and most of the structural development occurred in the Plio-Pleistocene.The Levant Rift system is characterized by its oblique displacement, and evidence for both dip-slip and strike-slip displacement was measured on its faults. Earthquakes also indicate that same mixed pattern, some of them show strike-slip offset, and others normal. It is generally conceded that the amount of normal offset along the boundary faults of the Rift system reaches 8–10 km, but the lateral displacement is disputed, and offsets ranging from 11 to 107 km were suggested. Assessment of the available data led us to suggest that the sinistral offset along the Levant Rift system is approximately 10–20 km. The similarity between the vertical and the lateral displacements, the basin and threshold structural pattern of the Rift, model experiments in oblique rifting, as well as the significant tectonic resemblance to the Red Sea and the East African rifts, indicate that the Levant Rift is the product of continental breakup, and it is probably an emerging oceanic spreading center.     

用瑞利面波研究东亚及西太平洋地壳上地幔三维结构

用分布于欧亚大陆及西太平洋地区106个宽频带数字地震台站约20000多个长周期波形记录,挑选出沿10600条大圆路径传播的瑞利面波,采用频散分析及波形拟合反演方法,对东亚及西太平洋边缘海地区地壳上地幔进行高分辨率三维层析成像。高分辨率速度成像表明,从上地壳到70km深,在东亚东部及西太平洋边缘海地区均为高速分布,西部以青藏高原为中心呈极低速分布。从100km至250km深,在东亚东部及西太平洋边缘海,自北向南显示出一条宽约2500km~4000km,长约8000km的巨型低速异常带。深度为300km~400km的平面图上,速度差异幅度不大,塔里木至扬子地块仍然显示为高速分布。东、西两部份岩石圈与软流圈的结构有着巨大的差异。西部主要是印度板块与欧亚板块碰撞引起的岩石圈汇聚增厚区;东部则主要是由于软流圈上涌(地幔热物质上升)引起的岩石圈拉张减薄区。古新世印度板块与欧亚板块的碰撞,岩石圈板片以低角度下插到青藏高原之下,引起高原隆起和地壳增厚,西部地区成为岩石圈汇聚区。中生代中晚期东亚大陆东缘岩石圈解体,软流圈物质上涌,岩石圈减薄张裂,形成巨型低速带,并演化为东亚裂谷系。现今的西太平洋边缘海、沟弧盆体系,是新生代中晚期太平洋板块、澳大利亚板块与欧亚板块相互作用形成的。