华北地台北缘地球物理场特征与金属矿床预测

对华北地台北缘的地球物理场特征进行了探讨,根据重、磁异常数据反演计算了该地区的莫霍界面、居里界面、磁性界面的起伏.利用地球物理场资料和反演计算结果对该地区的构造格架和断裂进行了推断,同时预测了9个成矿远景区:(1)集宁一呼和浩特金成矿区;(2)张家口一赤城金、银多金属成矿区;(3)密云一高岭金、铜成矿区;(4)青龙一马兰庄金成矿区;(5)秦皇岛、金多金属成矿区;(6)郝家营多金属成矿区;(7)承德地区金、多金属成矿区;(8)赤峰一喀喇沁旗金成矿区;(9)宁城东金、多金属成矿区.     

石门台自然保护区水资源及其利用保护

介绍了广东英德市北部山区石门台自然保护区的自然地理条件、水文效应、水资源特点及其开发利用现状 ,提出对水资源的保护管理措施 ,促进自然环境良性循环 ,促进水资源可持续利用和社会经济发展。     

巴音宝力格隆起带中新生代盆地砂岩型铀矿成矿地质条件及远景分析

本根据野外调查及室内系列编图成果，分析了巴音宝力格隆起带中新生代盆地砂岩型铀矿成矿地质条件，认为下白里统巴彦花组是中新生代盆地的找矿目的层位，并存在古河道与潜水层间氧化带两种砂岩型铀矿类型。巴彦毛都、准巴彦塔拉、乌里雅斯太和伊勒门盆地是形成砂岩型铀矿的远景盆地。     

填土引发的桩基负摩阻力问题及其灌浆处理技术

阐述了填土地基的沉降计算方法，分析了填土引发桩基负摩阻力的机理及危害，探讨了采用压力灌浆技术加固填土地基、消除桩基负摩阻力、控制桩基沉降的加固机理、施工工艺和应用效果。     

内蒙古东乌珠穆沁旗沙麦地区中-新生代伸展构造特征研究

介绍了伸展构造概念与研究现状，沙麦地区中—新生代伸展构造基本特征与形成机制。认为区内中—新生代盆地是地壳呈北西西—南东东向伸展的结果，地壳的伸展演化并不连续，呈现幕式伸展的特点。     

中国大陆活动地块的运动与应变状态

从地壳运动与应变的角度给出了活动地块的定义,根据中国大陆及周边地区最近几年GPS观测得到的由1598个GPS站速度组成的统一速度场,估计了各个活动地块的运动与应变参数,分析了各个活动地块的运动与应变状态。中国大陆各地块存在一致的向东运动分量,但其南北分量是不一致的。西部地块存在一致的向北运动分量,东部地块存在一致的向南运动分量。在90°E以东,从喜马拉雅地块向NE方向,各地块的运动方向按顺时针方向旋转,各地块的运动速率是不相同的。从总体上看是西部大、东部小,南部大、北部小,西部大约是东部的3～4倍。各地块主压应变方向的空间分布是不相同的。在90°E以西各地块的主应变方向基本上为SN向,在青藏高原的东北部各地块的主压应变方向基本为NE向,在青藏高原东南部各地块的主压应变方向绕喜马拉雅构造东端顺时针方向旋转。各地块的主应变与剪应变率也是不同的,其中喜马拉雅、天山地块的主压和最大剪应变率最高,其次是拉萨、羌塘、滇西南、祁连与川滇地块。东部各地块的应变率较小。根据应变状态推测,喜马拉雅地块南北向的缩短速率为(15.2±1.5)mm/a,仍然是现今构造活动最强烈的地区,其次是天山地块,天山地块南北向的缩短速率为(10.1±0.9)mm/a。这两个地块目前仍处于隆升状态,从面应变看,面膨胀在中国大陆占优势,东部基本都是膨胀区,在西部面压缩与面膨胀从南向北相间分布。中国大陆的大多数东西向或近东西向断裂两侧的相对运动都是左旋或类似左旋走滑型的,大多数南北向断裂两侧的相对运动都是右旋或类似右旋走滑型的。GPS测定的阿尔金断裂中部的左旋走滑速为(4.8±1.3)mm/a,鲜水河断裂的左旋走滑速为(9.8±2.2)mm/a。地块边界断裂带的运动为地块运动创造了条件,地块及其边界的运动是协调一致的统一的,各个地块的活动程度是不相同的,统计检验结果表明,大多数地块之间的相对运动是显著的与非常显著的,这证明活动地块是客观存在的,喜马拉雅、拉萨、天山、羌塘和滇西南是活动最强烈的地块,中蒙、中朝西、阿拉善和华南是较稳定的地块,印度、太平洋、菲律宾板块与欧亚板块的互相作用力是中国大陆地块运动的主要驱动力。青藏高原地壳物质在印度板块NNE向的强烈推挤下,向NNE和NE方向运动,由于受到北部、东北部和东部地块的阻挡,经高原的东南部向印度洋方向运移,     

地震的标度与孕震断层的强度

在构造学和地震力学方面，两个重要而又未解决的问题是孕震断层的强度和一次地震的地震矩随破裂面积或破裂长度的变化关系。本文将说明，通常分别处理的这两个问题从根基本上是相关的。按已有的报道，走滑和倾滑地震的地震矩与破裂面积和地震矩与破裂长度关系的数据是离散的，但本文论证了数据实际并不离散，只不过是反映了失稳破坏的断层的强度差异。本文推导出了表达大、小地震之间连续标度的关系式，并证明，断层带的孔隙压力是将走滑型和倾滑型地震联合起来归结为一种作用机制的标度参数。还论证了对于大地震，在大约15km之上断层带孔隙压力在静水压力与接近静岩压力之间连续变化，在此深度之下，有明确的向接近静岩孔隙压力过渡的证据。这些结果对板块构造学、震源物理学，以及从力学上作地震灾害评估均具有重要的意义。     

青藏铁路昆仑山隧道工程地质条件

主要论述了昆仑山隧道这一高原冻土隧道的工程地质条件, 特别就隧道区多年冻土的认识及具体的工作方法、古冰川作用及冰锥的分布及其成因和隧道山体地下水情况分析等做了较为详尽的描述, 为隧道设计、施工提供了科学的地质依据及工程措施意见.     

Movement and strain conditions of active blocks in the Chinese mainland

The definition of active block is given from the angles of crustal deformation and strain. The movement and strain parameters of active blocks are estimated according to the unified velocity field composed of the velocities at 1598 GPS stations obtained from GPS measurements carried out in the past years in the Chinese mainland and the surrounding areas. The movement and strain conditions of the blocks are analyzed. The active blocks in the Chinese mainland have a consistent E-trending movement component, but its N and S components are not consistent. The blocks in the western part have a consistent N-trending movement and the blocks in the eastern part have a consistent S-trending movement. In the area to the east of 90°E, that is the area from Himalayas block towards NE, the movement direction of the blocks rotates clockwisely and the movement rates of the blocks are different. Generally, the movement rate is large in the west and south and small in the east and north with a difference of 3 to 4 times between the rates in the west and east. The distributions of principal compressive strain directions of the blocks are also different. The principal strain of the blocks located to the west of 90oE is basically in the SN direction, the principal compressive strain of the blocks in the northeastern part of Qingzang plateau is roughly in the NE direction and the direction of principal compressive strain of the blocks in the southeastern part of Qingzang plateau rounds clockwisely the east end of Himalayas structure. In addition, the principal strain and shear strain rates of the blocks are also different. The Himalayas and Tianshan blocks have the largest principal compressive strain and the maximum shear strain rate. Then, Lhasa, Qiangtang, Southwest Yunnan (SW Yunnan), Qilian and Sichuan-Yunan (Chuan-Dian) blocks followed. The strain rate of the blocks in the eastern part is smaller. The estimation based on the stain condition indicates that Himalayas block is still the area with the most intensive tectonic activity and it shortens in the NS direction at the rate of 15.2±1.5 mm/a. Tianshan block ranks the second and it shortens in the NS direction at the rate of 10.1±0.9 mm/a. At present, the two blocks are still uprising. It can be seen from superficial strain that the Chinese mainland is predominated by superficial expansion. Almost the total area in the eastern part of the Chinese mainland is expanded, while in the western part, the superficial compression and expansion are alternatively distributed from the south to the north. In the Chinese mainland, most EW-trending or proximate EW-trending faults have the left-lateral or left-lateral strike-slip relative movements along both sides, and most NS-trending faults have the right-lateral or right-lateral strike-slip relative movements along both sides. According to the data from GPS measurements the left-lateral strike-slip rate is 4.8±1.3 mm/a in the central part of Altun fault and 9.8±2.2 mm/a on Xianshuihe fault. The movement of the fault along the block boundary has provided the condition for block movement, so the movements of the block and its boundary are consistent, but the movement levels of the blocks are different. The statistic results indicate that the relative movement between most blocks is quite significant, which proves that active blocks exist. Himalayas, Tianshan, Qiangtang and SW Yunnan blocks have the most intensive movement; China-Mongolia, China-Korea (China-Korea), Alxa and South China blocks are rather stable. The mutual action of India, Pacific and Philippine Sea plates versus Eurasia plate is the principal driving force to the block movement in the Chinese mainland. Under the NNE-trending intensive press from India plate, the crustal matter of Qingzang plateau moves to the NNE and NE directions, then is hindered by the blocks located in the northern, northeastern and eastern parts. The crustal matter moves towards the Indian Ocean by the southeastern part of the plateau.