论江西双桥山群的底界问题

１∶５万庐山地区区域地质调查和专题研究,在星子县黄岭一带发现一套巨厚层状复成分的变质砾岩。根据该变质砾岩的砾石成分、变形组构及区域分布特点,以及上部（双桥山群）与下部（星子岩群）地层在变质与变形方面存在明显差别,认为变质砾岩应属于双桥山群的底部层位,是中元古界双桥山群与下伏下元古界星子岩群不整合关系的佐证。由于受后期构造叠加改造的影响,现今二者呈断层或隐蔽不整合接触关系。     

大别超高压岩石中石英的组构和变形

通过对大别地区不同超高压岩石和同一超高压岩石中不同变形期次石英的变形特征的研究 ,探讨超高压岩石折返时的流变学特征和状态。运用野外构造解析、组构分析、透射电镜和应变分析发现 ,除榴辉岩中静态重结晶石英外 ,其它超高压岩石中石英均发生了强烈的塑性变形 ,波状消光、变形纹、变形条带等极为常见。石英石榴岩中石英交叉滑移位错的发育 ,说明经历了高温位错蠕变 ,其代表的差异应力为Δσ =78.92MPa。石英脉的变形是超高压岩石折返到中地壳以后的角闪岩相退变峰期产物 ,其差异应力为Δσ =2 5 .2MPa。超高压二云母片岩中石英典型的糜棱结构代表的差异应力为 :Δσ =5 9.6 1MPa。大别超高压岩石可能是在构造应力比较低的情况下区域隆升的结果     

蛮寨滑坡变形特征及成因分析

通过蛮寨滑坡的调查与分析认为，特有的地质地貌条件及古滑体的存在，是该滑坡形成的内在原因，降雨及人为活动是滑坡的外在因素。蛮寨滑坡属危险性滑坡，目前处于蠕动变形阶段。     

高速铁路大断面黄土隧道二次衬砌施作时机研究

隧道工程二次衬砌施作时机是隧道界普遍关注的问题。依托正在修建的郑州-西安铁路客运专线大断面黄土隧道工程,以围岩及初期支护基本稳定速率作为二次衬砌施作时机判定指标,采用位移断面监测数据回归分析和数值分析相结合,建立基本稳定速率的理论求解方法,从而确定二次衬砌施作时机;同时,选取贺家庄隧道试验段作为工程实例,对高速铁路大断面黄土隧道二次衬砌施作时机进行研究。研究结果表明：当拱顶下沉变形速率值小于0.55 mm/d,边墙水平绝对收敛速率值小于0.11 mm/d时,即可进行二次衬砌施作。此次研究为类似工程的设计和施工提供了参考依据。     

大厚度自重湿陷性黄土湿陷变形特性水分入渗规律及地基处理方法研究

为研究大厚度自重湿陷性黄土的湿陷变形特性、水分入渗规律以及地基处理合理方法等问题,选择典型大厚度自重湿陷性黄土场地,进行了布置沉降观测点和埋设水分计的浸水试验以及挤密桩、DDC（孔内深层强夯）桩地基处理试验。试验结果表明,在水分入渗过程中,深度22.5～25.0 m以上土体易发生湿陷,该深度以下土体则含水率增加缓慢,达不到湿陷起始含水率,不易发生湿陷,因此该深度考虑可作为现场湿陷性评价的临界深度,也可作为大厚度湿陷性黄土地区进行地基处理时可参考的地基处理下限深度。DDC桩间距为1.0～1.4 m时,无论从挤密系数还是湿陷系数都能满足规范要求;挤密桩15 m试验区域沉降量较小,但其剩余湿陷量任未满足要求,这也佐证了关于22.5～25.0 m深度难于发生湿陷的结论。试验成果可作为今后大厚度自重湿陷性黄土地区工程建设以及黄土规范进一步修订的参考。     

Deformation patterns of upper Quaternary strata and their relation to active tectonics,Po Basin,Italy

Despite increased application of subsurface datasets below the limits of seismic resolution, reconstructing near‐surface deformation of shallow key stratigraphic markers beneath modern alluvial and coastal plains through sediment core analysis has received little attention. Highly resolved stratigraphy of Upper Pleistocene to Holocene (Marine Isotope Stage 5e to Marine Isotope Stage 1) alluvial, deltaic and coastal depositional systems across the southern Po Plain, down to 150 m depth, provides an unambiguous documentation on the deformation of previously flat‐lying strata that goes back in time beyond the limits of morphological, historical and palaeoseismic records. Five prominent key horizons, accurately selected on the basis of their sedimentological characteristics and typified for their fossil content, were used as highly effective stratigraphic markers (M1 to M5) that can be tracked for tens of kilometres across the basin. A facies‐controlled approach tied to a robust chronology (102 radiocarbon dates) reveals considerable deformation of laterally extensive nearshore (M1), continental (M2 and M3) and lagoon (M4 and M5) marker beds originally deposited in a horizontal position (M1, M4 and M5). The areas where antiformal geometries are best observed are remarkably coincident with the axes of buried ramp anticlines, across which new seismic images reveal substantially warped stratal geometries of Lower Pleistocene strata. The striking spatial coincidence of fold crests with the epicentres of historic and instrumental seismicity suggests that deformation of marker beds M1 to M5 might reflect, in part at least, syntectonically generated relief and, thus, active tectonism. Precise identification and lateral tracing of chronologically constrained stratigraphic markers in the ¹⁴C time window through combined sedimentological and palaeoecological data may delineate late Quaternary subsurface stratigraphic architecture at an unprecedented level of detail, outlining cryptic stratal geometries at the sub‐seismic scale. This approach is highly reproducible in tectonically active Quaternary depositional systems and can help to assess patterns of active deformation in the subsurface of modern alluvial and coastal plains worldwide.     

Progressive,episodic deformation in the Mexican Fold–Thrust Belt (central Mexico): evidence from isotopic dating of folds and faults

We used illite Ar/Ar dating to obtain absolute ages of folds and shear zones formed within the Mexican Fold–Thrust Belt (MFTB). The methodology takes advantage of illite dating in folded, clay-bearing layers and the ability to obtain accurate ages from small-size fractions of illite using encapsulated Ar analysis. We applied our approach to a cross-section that involves folded Aptian–Cenomanian shale-bentonitic layers interbedded with carbonates of the Zimapán (ZB) and Tampico–Misantla (TMB) Cretaceous basins in central-eastern Mexico. Basinal carbonates were buried by syn-tectonic turbidites and inverted during the formation of the MFTB in the Late Cretaceous. Results from folds and shear zones record different pulses of deformation within this thin-skinned orogenic wedge.

Mineralogical compositions, variations in illite polytypes, illite crystallite size (CS), and Ar/Ar ages were obtained from several size fractions in limbs and hinges of the folds and in the shear zones. 1M_d-illite polytype (with CS of 6–9 nm) dominates in two folds in the TMB while 2M₁-illlite (with CS of 14–30 nm) dominates in the third fold, in the ZB, and in the fold/shear zone. From west (higher grade) to east (lower grade): Ar retention ages indicate shearing occurred at ~84 Ma in the westernmost shear zone, folding at ~82 Ma in the ZB with subsequent localized shearing at ~77 Ma, and Ar total gas ages constrain the time of folding at ~64 Ma on the west side of the TMB and ~44 Ma on the eastern edge. These results are consistent with the age and distribution of syn-tectonic turbidites and indicate episodic progression of deformation from west to east.     

轻量砂变形及强度特性三轴试验研究

通过三轴试验系统研究了新型土工材料--轻量砂的变形及强度特性。结果表明,不同的配比、龄期使轻量砂具有不同的原生结构强度,围压使不同原生结构强度的土样处于剪胀或剪缩状态,导致发生应变硬化、应变软化以及相应状态下孔压的3种对应形态变化。变形模量随EPS（发泡聚苯乙烯）球粒掺入比的增大而线性减小,随水泥掺入比、龄期增大而线性增大,相同配比的土样变形模量与围压关系不大;三轴抗压强度随EPS球粒掺入比增大而呈负指数关系减小,随水泥掺入比、龄期、围压增大而线性增大,存在水泥掺入比阀值;土骨架转换效应对于土样强度的影响很大,造成了土体单轴、三轴抗压强度分带,高水泥掺入比能够大大弱化EPS颗粒的土骨架效应。结合前人成果,系统地研究了轻量砂密度、无侧限抗压强度的影响因素,引入材料学中比强的概念,提出了单价比强图结合配方公式的方法,对轻量土砂进行配方优化。分析了轻量土砂应力-应变关系转型问题,提出采用无侧限抗压强度来表征不同配比、龄期轻量土砂的原生结构强度。通过试验与数理统计,建立临界围压与原生结构强度的关系,为数值模拟计算与建立本构模型奠定了基础。     

安阳矿区双全井田岩性结构与煤体变形的关系

煤体变形程度控制着煤与瓦斯突出和煤层气的可开发性,煤体结构空间展布预测是人们长期关注的焦点。以岩体力学和分形几何学基本理论为指导,以安阳矿区双全井田为例,通过计算岩体强度因子和分形维数,系统探讨了岩性结构对煤体变形的影响。研究表明,岩体强度因子和分形维数与断层和测井曲线判识的煤体结构之间存在密切关系:低强度因子和分形维数区,煤体易发生韧性变形,软煤发育;高强度因子和分形维数区,煤体(和岩体)以脆性变形为主,以断层发育为特征。这一结论为井田构造发育特征和软煤空间展布所证实。岩体力学和分形几何学的引入,为煤体结构空间展布区域预测提供了一种新途径。     

Multistage Deformation in the Northeastern Segment of the Jiangshao Fault (Suture) Belt: Constraints for the Relationship between the Yangtze Plate and the Cathaysia Old Land

Multistage deformation events have occurred in the northeastern Jiangshao Fault (Suture) Belt. The earliest two are ductile deformation events. The first is the ca. 820 Ma top-to-the-northwest ductile thrusting, which directly resulted from the collision between the Cathaysia Old Land and the Chencai Arc (?) during the Late Neoproterozoic, and the Jiangnan Orogenic Belt that formed as the ocean closed between the Yangtze Plate and the jointed Cathaysia Old Land and the Chencai Arc due to continuous compression. The second is the ductile left-lateral strike-slipping that occurred in the latest Early Paleozoic. Since the Jinning period, all deformation events represent the reactivation or inversion of intraplate structures due to the collisions between the North China and Yangtze plates during the Triassic and between the Philippine Sea and Eurasian plates during the Cenozoic. In the Triassic, brittle right-lateral strike-slipping and subsequent top-to-the south thrusting occurred along the whole northeastern Jiangshao Fault Zone because of the collision between the North China and Yangtze plates. In the Late Mesozoic, regional extension took place across southeastern China. In the Cenozoic, the collision between the Philippine Sea and Eurasian plates resulted in brittle thrusts along the whole Jiangnan Old land in the Miocene. The Jiangshao Fault Belt is a weak zone in the crust with long history, and its reactivation is one of important characteristics of the deformation in South China; however, late-stage deformation events did not occur beyond the Jiangnan Old Land and most of them are parallel to the strike of the Old Land, which is similar to the Cenozoic deformation in Central Asia. In addition, the Jiangnan old Land is not a collisional boundary between the Yangtze Plate and Cathaysia Old Land in the Triassic.