利用地震矩张量反演地壳运动水平速度场的理论和方法

根据地震矩张量反演地壳水平形变速度包括两个主要步骤：（１）由震源机制解计算地壳的平均应变率；（２）由应变率求速度场。文中对反演的理论与方法作了详细论述，并讨论了速度场内的相对大地转动和线性结构的整体转动以及速度场的误差椭圆的计算方法     

地形变信息流合成用于首都圈震情判定的研究

将首都圈大量的跨断层流动短水准、短基线资料进行了全时空的处理,先后有四点组斜率法和信息标准化方法将全部资料处理成标准化信息流,然后分别进行效益判定,从中选择出了七项信息效益指标相对最好的资料进行了信息合成,合成后得到了比较好的结果。     

张北6.2级地震前河北北部的地壳形变异常

对河北省地震局掌握的张北６．２级地震前河北北部及邻省山西的地壳形变资料利用周期滤波,调和分析两种方法进行了分析处理,获得异常１２项,其中趋势异常１０项,短临异常２项。本文分析了这些异常的特性及张北地震的关系,同时针对这些异常分析了形变手段地震预报的现状及当前的困难,并探讨了今后的对策。     

Nature and growth rate of the Northern Izu–Bonin (Ogasawara) arc crust and their implications for continental crust formation

The bulk composition of the continental crust throughout geological history is thought by most previous workers to be andesitic. This assumption of an andesitic bulk composition led to an early hypothesis by 72 ) that the continental crust was created by arc magmatism. This hypothesis for the origin of continental crust was challenged by several authors because: (i) the mean rate of arc crust addition obtained by 50 ) is too small to account for some certain phases of rapid crustal growth; and (ii) the bulk composition of ocean island arcs, the main contributor to the Archean and early Proterozoic crust, is basaltic rather than andesitic ( 4 ; 49 ). New data from the Northern Izu–Bonin arc are presented here which support the 72 ) hypothesis for the origin of the continental crust by andesitic arc magma. A geological interpretation of P wave crustal structure obtained from the Northern Izu–Bonin arc by 66 ) indicates that the arc crust has four distinctive lithologic layers: from top to bottom: (i) a 0.5–2-km-thick layer of basic to intermediate volcaniclastic, lava and hemipelagite (layer A); (ii) a 2–5-km-thick basic to intermediate volcaniclastics, lavas and intrusive layer (layer B); (iii) a 2–7-km-thick layer of felsic (tonalitic) rocks (layer C); and (iv) a 4–7-km-thick layer of mafic igneous rocks (layer D). The chemical composition of the upper and middle part of the northern Izu–Bonin arc is estimated to be similar to the average continental crust by 73 ). The rate of igneous addition of the Northern Izu–Bonin arc since its initial 45-Ma magmatism was calculated as 80 km³/km per million years. This rate of addition is considered to be a reasonable estimate for all arcs in the western Pacific. Using this rate, the global rate of crustal growth is estimated to be 2.96 km³/year which exceeds the average rate of crustal growth since the formation of the Earth (1.76 km³/year). Based on this estimate of continental growth and the previously documented sediment subduction and tectonic erosion rate (1.8 km³/year, 24 ), several examples of growth curves of the continental crust are presented here. These growth curves suggest that at least 50% of the present volume of the continental crust can be explained by arc magmatism. This conclusion indicates that arc magmatism is the most important contributor to the formation of continental crust, especially at the upper crustal level.     

Crustal structure beneath the Faroe Islands and the Faroe–Iceland Ridge

We have mapped the transition from the continental Faroe block (the Faroe Islands and surrounding shelf) to the thickened oceanic crust of the Faroe–Iceland Ridge in the North Atlantic using the results of a detailed sea-to-land seismic profile with wide-angle to normal-incidence recordings of explosive and airgun shots fired at sea along the Faroe–Iceland Ridge. Interpretation of all available seismic and gravity data indicates that this aseismic ridge is composed of 30±3-km-thick oceanic crust, with a gradual transition to ancient continental crust from 100 to 40 km northwest of the Faroe Islands, close to the shelf edge. This confirms that the crust beneath the Faroe Islands, which may be up to 46 km thick, comprises continental material in agreement with previous seismic and geochemical results. Results suggest that the upper 5.2±0.7 km of the Faroe crust consists of Tertiary basalts generated during continental breakup, overlying the continental crust beneath. The lower crust, where seismic constraint is poor, may exhibit high seismic velocities (7.1–7.6 km s⁻¹) which we attribute to underplating or intrusion by mafic melts during continental breakup in the early Tertiary.     

Application of revised ray tracing migration to imagine lateral variations of seismic fabric corresponding to different tectonic styles in the northern Apennines

Migration of zero-offset seismic sections of deep crust can be done with methods based on ray tracing. We modify the classical ray tracing migration method (RTM), introducing a consistency check to control whether back-propagated rays satisfy the condition of strict normal incidence at the migrated reflector. A synthetic test shows the effectiveness of the method; in particular the control of normal incidence allows elimination of physically inconsistent reflectors from the migrated section. Then RTM is applied to a crustal seismic profile acquired in central Italy, using a velocity model obtained from wide-angle data that reproduces the gross structures of the Apenninic crust. The lateral variation of the seismic fabric shown from the migrated section reveals the presence of coexisting extensional and compressional tectonic regimes. Kinematic diffraction modelling gives additional information about both the distribution of seismic velocities and major active geodynamic processes in the upper lithosphere. The migrated section supports the subdivision of northern Apennines in two tectonic regions: a stretched upper plate (Tuscany and northern Thyrrenian), supported by a rise of the asthenosphere, and a downwarped lower plate (Adria), subducted below the mountain belt.