排序方式: 共有4条查询结果,搜索用时 0 毫秒
1
1.
现今中国大陆地壳运动与活动块体模型 总被引:68,自引:2,他引:68
通过分析中国地壳运动观测网络GPS数据特别是1999年与2001年区域网数据, 我们初步得到了中国大陆地壳运动速度场, 并用统计分析的方法从高密度台站速度场中区分出9个独立活动块体和2个广泛形变带, 求出活动块体刚体运动欧拉极和相邻块体间相互运动速率. 结果显示中国大陆形变场似可分为3类区域 第1类区包括青藏高原内部区域和天山造山带, 形变在全区域内广泛分布; 第3类区包括塔里木盆地及南北带以东地区, 形变场表现为活动块体, 内部稳定, 形变局限在狭窄的边界带内; 第2类区则处在青藏高原的边缘带, 如柴达木、祁连、西宁、川滇菱形南块体等, 这类区形变场特征处在第1, 3类区之间, 虽然还能保持一定的块体完整性, 但块体的尺度和强度已不如第3类地区. 通过分析各类区域岩石圈结构以及形变模式我们可以得出初步推断 中国大陆地壳形变模式主要由地壳结构所控制. 中国大陆东部和塔里木盆地地区地壳介质有相当强度, 形变表现为刚性块体的相互运动. 而印度板块的北向挤压造成青藏高原和天山的隆起并产生巨厚地壳, 壳内温度上升, 下地壳低速高导层发育, 介质呈较强黏塑性, 地壳脆性层在下地壳塑性流变场作用下产生各种类型的、多层次的形变, 且分布广泛而不局限于少量块体边界地区. 青藏高原边缘的第2类地区地壳结构为第1, 3类地区之间的过渡区, 其形变特征也介于第1, 3类地区之间, 为强度较低的较小活动块体在边界作用力下的运动与变形. 相似文献
2.
目前,在我国相继有不少地震台站(网)研究了适合该地区的测定持续时间震级的方法,并建立了相应的公式。本文利用兰州有线传输台网记录的甘肃及邻区的470个地震资料,建立了6个有线传输台和武威无线传输台网的4个子台的M_D震级公式,初步建立了兰州电传台网的M_D震级系统。本文还对M_D与M_L两种震级测量精度做了初步评价,简要分析了放大倍数v对M_D震级的影响。 相似文献
3.
对青藏高原北部东昆仑破裂带大地震之间的应力转移和断层相互作用进行研究. 考虑1937年以来沿此破裂带发生的5个M≥7的地震:1937年M7.5花石峡地震,1963年MS7.1都兰地震,1973年MS7.3玛尼地震,1997年MW7.5玛尼地震和2001年MW7.8可可西里地震,模拟了黏弹性成层介质中地震断层错动产生的应力演化过程,并计算了在后续地震破裂面上产生的库仑破裂应力变化. 结果表明,前面4个地震均造成2001年可可西里地震断层面上库仑破裂应力的增加,并且中地壳和下地壳的黏弹性松弛效应使得库仑破裂应力场随着时间的推移而逐渐加强. 在计算过程中定量估计了可可西里地震发生时前面4个地震同震形变和黏弹性松弛导致可可西里地震破裂面上库仑破裂应力变化之间的比值,发现前3个地震由黏弹性松弛造成的变化远远大于同震形变所造成的变化. 可可西里地震之后应力场的模拟表明东昆仑断层中段的东大滩-西大滩断层段(位于可可西里地震破裂以东及都兰地震以西)的库仑破裂应力显著增加,变化值达0.05~0.1 MPa,预示这一地区地震危险性的增加. 相似文献
4.
We obtain the preliminary result of crustal deformation velocity field for the Chinese con-tinent by analyzing GPS data from the Crustal Motion Observation Network of China (CMONOC), particularly the data from the regional networks of CMONOC observed in 1999 and 2001. We de-lineate 9 tectonically active blocks and 2 broadly distributed deformation zones out of a denseGPS velocity field, and derive block motion Euler poles for the blocks and their relative motionrates. Our result reveals that there are 3 categories of deformation patterns in the Chinese conti-nent. The first category, associated with the interior of the Tibetan Plateau and the Tianshan oro-genic belt, shows broadly distributed deformation within the regions. The third category, associatedwith the Tarim Basin and the region east of the north-south seismic belt of China, shows block-likemotion, with deformation accommodated along the block boundaries only. The second category, mainly associated with the borderland of the Tibetan Plateau, such as the Qaidam, Qilian, Xining(in eastern Qinghai), and the Diamond-shaped (in western Sichuan and Yunnan) blocks, has thedeformation pattern between the first and the third, i.e. these regions appear to deform block-like,but with smaller sizes and less strength for the blocks. Based on the analysis of the lithosphericstructures and the deformation patterns of the regions above, we come to the inference that thedeformation modes of the Chinese continental crust are mainly controlled by the crustal structure.The crust of the eastern China and the Tarim Basin is mechanically strong, and its deformationtakes the form of relative motion between rigid blocks. On the other hand, the northward indentation of the Indian plate into the Asia continent has created the uplift of the Tibetan Plateau and the Tianshan Mountains, thickened their crust, and raised the temperature in the crust. The lower crust thus has become ductile, evidenced in low seismic velocity and high electric conductivity observed. The brittle part of the crust, driven by the visco-plastic flow of the lower crust, deforms extensively at all scales. The regions of the second category located at the borderland of the Tibetan Plateau are at the transition zone between the regions of the first and the third categories in terms of the crustal structure. Driven by the lateral boundary forces, their deformation style is also between the two, in the form of block motion and deformation with smaller blocks and less internal strength. 相似文献
1