灰色理论应用于轨道交通一号线一期工程承重墩沉降分析

介绍了沉降监测数据处理理论方法,讨论了灰色模型法预测沉降的过程,分析了武汉轨道交通一期工程承重墩沉降监测数据,结果表明其基础是基本稳定的。     

GPS-RTK技术在地籍测量中的应用研究

将RTK技术应用于地籍测量中,分析了RTK在地籍控制测量和碎部测量的可行性,阐述了该技术应用于地籍测量中所遇到的问题并进行了深入研究,提出了相应对策.     

地球物理学中的电磁场正演与反演

本文在近年来众多的地球物理研究者的研究基础上，总结了当前地电磁模型正反演已有成果，定量分析了各种主要正反演的性能测试，指出不同正反演法的优点、缺点以及应用范围局限，提出了各种方法的发展趋势以及当前计算地球物理领域的核心内容，指出了计算地球物理领域的数值模拟发展方向.     

南岭稀土花岗岩、钨锡花岗岩及其成矿作用的对比

南岭地区的钨锡和稀土矿床都与花岗岩类有直接成因联系,但二者的成矿作用有许多不同之处.钨锡是典型的热液成矿,而稀土则主要形成于风化作用.随着花岗岩类的分异演化,岩石中的W、Sn等元素含量逐渐增加,因此钨锡等矿床主要与高度分异演化的晚阶段小岩体有关;但是稀土的表现与钨锡不同,由于花岗岩类的分异演化导致稀土栽体黑云母及许多副矿物的减少,因此稀土元素含量在晚阶段岩体中反而降低.赣南的五里亭-大吉山岩体、桂东北的花山-姑婆山岩体等提供了很好的范例.因此,南岭地区与风化壳型稀土矿床有关的岩石主要有:印支期准铝质花岗岩,燕山期A型花岗岩,燕山中-晚期黑云母二长花岗岩等.     

江苏省风能资源重新估算与分布研究

利用1971—2000年江苏省67个台站的多气象要素资料,挑选风能资源评估的代表年,重新计算江苏省风能资源状况,发现与上世纪80年代全国风能评估结果以及90年代的评估结果有很大差异,全省风能总储量估算为3.03×1010W,实际可开发量约为0.24×1010W。风能资源在江苏沿海和海岛比较丰富,是未来开发的重点区域,而在绝大部分内陆地区风能贫乏,贫乏区占据全省的92.2%。     

Fractal analysis applied to faults and earthquakes——A case study of China

Ｆｒａｃｔａｌａｎａｌｙｓｉｓａｐｐｌｉｅｄｔｏｆａｕｌｔｓａｎｄｅａｒｔｈｑｕａｋｅｓ———ＡｃａｓｅｓｔｕｄｙｏｆＣｈｉｎａＪＩＡＮＷＡＮＧ（王建）ＸＩＡＯＨＵＡＺＨＵ（朱晓华）ＹＯＮＧＨＵＩＸＵ（徐永辉）ＤｅｐａｒｔｍｅｎｔｏｆＧｅｏｇ...     

Burst strain disturbance—A new test study on fracture precursor

ＩｎｔｒｏｄｕｃｔｉｏｎＢｅｆｏｒｅａｎｅａｒｔｈｑｕａｋｅｏｃｕｕｒｓ,ｄｅｆｏｒｍａｔｉｏｎｖａｒｉａｔｉｏｎｓｏｂｖｉｏｕｓｌｙａｐｐｅａｒｉｎｓｅｉｓｍｏｇｅｎｉｃａｒｅａａｎｄｎｅａｒｂｙｗｈｉｃｈｗｅｒｅｒｅｐｏｒｔｅｄａｌｏｔ．Ｅａｒｌ...     

我国东部新生代玄武岩岩石化学的一些探讨

新生代是地球上玄武质岩浆的主要活动期。在我国东部,新生代玄武岩分布也极广泛,由北往南自大兴安岭、松辽盆地经华北、苏闽浙至台湾、海南岛以及近海大陆架均有不同程度的出露。时间上从老第三纪至史期均有玄武岩喷发活动。     

Lg Coda Q and its Relation to the Geology and Tectonics of the Middle East

—Regional seismograms were collected to image the lateral variations of Lg coda Q at 1 Hz (Q ₀?) and its frequency dependence <(eta)> in the Middle East using a back-projection method. The data include 124 vertical-component traces recorded at 10 stations during the period 1986–1996. The resulting images reveal lateral variations in both Q ₀ and <eta>. In the Turkish and Iranian Plateaus, a highly deformed and tectonically active region, Q ₀ ranges between about 150 and 300, with the lowest values occurring in western Anatolia where extremely high heat flow has been measured. The low Q ₀ values found in this region agree with those found in other tectonically active regions of the world. Throughout most of the Arabian Peninsula, a relatively stable region, Q ₀ varies between 350 and 450, being highest in the shield area and lowest in the eastern basins. All values are considerably lower than those found in most other stable regions. Low Q values throughout the Middle East may be caused by interstitial fluids that have migrated to the crust from the upper mantle, where they were probably generated by hydrothermal reactions at elevated temperatures known to occur there. Low Q ₀ values (about 250) are also found in the Oman folded zone, a region with thick sedimentary deposits. <eta> varies inversely with Q ₀ throughout most of the Middle East, with lower values (0.4–0.5) in the Arabian Peninsula and higher values (0.6–0.8) in Iran and Turkey. Q ₀ and <eta> are both low in the Oman folded zone and western Anatolia.     

Seismic Velocity and Q Structure of the Middle Eastern Crust and Upper Mantle from Surface-wave Dispersion and Attenuation

—Observed velocities and attenuation of fundamental-mode Rayleigh waves in the period range 7–82 sec were inverted for shear-wave velocity and shear-wave Q structure in the Middle East using a two-station method. Additional information on Q structure variation within each region was obtained by studying amplitude spectra of fundamental-mode and higher-mode Rayleigh waves. We obtained models for the Turkish and Iranian Plateaus (Region 1), areas surrounding and including the Black and Caspian Seas (Region 2), and the Arabian Peninsula (Region 3). The effect of continent-ocean boundaries and mixed paths in Region 2 may lead to unrealistic features in the models obtained there. At lower crustal and upper-mantle depths, shear velocities are similar in all three regions. Shear velocities vary significantly in the uppermost 10 km of the crust, being 3.21, 2.85, and 3.39 km/s for Regions 1, 2, and 3, respectively. Q models obtained from an inversion of interstation attenuation data show that crustal shear-wave Q is highest in Region 3 and lowest in Region 1. Q’s for the upper 10 km of the crust are 63, 71, and 201 for Regions 1, 2, and 3, respectively. Crustal Q’s at 30 km depth for the three regions are about 51, 71, and 134. The lower crustal Q values contrast sharply with results from stable continental regions where shear-wave Q may reach one thousand or more. These low values may indicate that fluids reside in faults, cracks, and permeable rock at lower crustal, as well as upper crustal depths due to convergence and intense deformation at all depths in the Middle Eastern crust.