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山东地区地震动衰减和场地响应的研究 总被引:3,自引:0,他引:3
采用Atkirlsorl方法,基于遗传算法反演山东地区非弹性衰减Q值,在此基础上利用Moya等方法进行了台站的场地响应的测算。数据分析使用的是山东数字地震台网最早正式运行的8个数字台站记录的所有地震,采用信噪比方法挑选出质量较高的16次地震,对记录谱进行路径校正后参与计算得到每个台站的场地响应值。研究结果表明:在所研究的频率范围内非弹性衰减Q值和频率f有很好的线性关系,Q(f)9=297.4f^0.558;8个数字地震台中的7个基岩台均没显示出明显的放大作用。1个井下摆台站场地响应在高频部分衰减很快。 相似文献
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根据江苏数字地震台网(包含邻区共享台站)73个数字地震台记录的49次地震事件的波形资料,用Atkinson方法对江苏地区的非弹性衰减Q值进行了计算,得到研究区介质非弹性衰减平均Q值随频率f的关系式为Q(f)=272.1·f~(0.5575),并用Moya方法计算并得到了研究区内63个台站的场地响应。结果表明,江苏境内25个地面基岩台的场地响应为1~20Hz,放大倍数基本在1附近波动,符合基岩台基的特征。14个井下台站场地响应形态相同,表现为低频放大,高频部分迅速衰减。根据Brune模型计算并获得了江苏及邻区2010年10月至2015年3月58个M_L2.5以上地震的震源参数,结果表明,近震震级与地震矩、震源尺度和拐角频率的相关性较好,而与应力降的关系不明显,且应力降与震源尺度的关系也不明显。 相似文献
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采用分布于鄂尔多斯地块及其周缘的32个地震台站记录到的19次地震事件共487条数字化波形记录, 利用遗传算法反演得到了整个鄂尔多斯地块地壳内S波的三段几何扩散参数、S波非弹性衰减Q值随频率变化的关系式、32个台站的场地响应以及19次地震的震源参数. 计算结果表明, 鄂尔多斯地块地壳内S波非弹性衰减在1 Hz处的Q值比地质构造活跃地区的结果要大得多. 32个地震台站的场地响应在高频部分除个别台站外基本没有表现出明显的放大效应,但在低频区间部分台站之间有一定的差异. 19次地震事件的地震矩对数值与震级ML有很好的线性关系. 相似文献
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根据山西数字地震台网14个地震台的310条波形资料,研究了山西地区的非弹性衰减系数;采用Atkinson和Moya方法,研究了各台的场地响应和几种震源参数,并对这两种方法的反演结果进行了对比分析. 得到山西地区非弹性衰减Q值随频率f的关系为Q(f)=323.2f 0.506;得到的14个台站的场地响应均没有显示出明显的放大效应,这与山西台站均处于岩石地基相符;得到了拐角频率与地震矩、地震矩与应力降、震源半径与应力降之间存在依赖关系. 相似文献
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安徽地区地震波衰减、场地响应及震源新参数的测定 总被引:5,自引:2,他引:5
根据安徽数字地震台网7个地震台的143条波形资料,研究了安徽地区的衰减模型和各台站的场地响应。采用三段几何衰减模型拟合,得到了安徽及邻近地区的几何衰减函数,得到安徽地区非弹性衰减Q值随频率f的关系为Q(f)=235.3×f0.616;7个台站的场地响应均无明显的放大效应,这与它们均处于岩石地基相符;并在本地区地震预测研究中尝试使用新参数,进行了初步的应用。 相似文献
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《中国科学:地球科学(英文版)》2014,(12)
正SCIENCE CHINA Earth Sciences,an academic journal cosponsored by the Chinese Academy of Sciences and the National Natural Science Foundation of China,and published by Science China Press and Springer,is committed to publishing high-quality,original results in both basic and applied research. 相似文献
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《中国科学:地球科学(英文版)》2014,(9)
正SCIENCE CHINA Earth Sciences,an academic journal cosponsored by the Chinese Academy of Sciences and the National Natural Science Foundation of China,and published by Science China Press and Springer,is committed to publishing high-quality,original results in 相似文献
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In natural waters arsenic concentrations up to a few milligrams per litre were measured. The natural content of arsenic found in soils varies between 0.01 mg/kg and a few hundred milligrams per kilogram. Anthropogenic sources of arsenic in the environment are the smelting of ores, the burning of coal, and the use of arsenic compounds in many products and production processes in the past. A lot of arsenic compounds are toxic and cause acute and chronic poisoning. In aqueous environment the inorganic arsenic species arsenite (As(III)) and arsenate (As(V)) are the most abundant species. The mobility of these species is influenced by the pH value, the redox potential, and the presence of adsorbents such as oxides and hydroxides of Fe(III), Al(III), Mn(III/IV), humic substances, and clay minerals. 相似文献
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《中国科学:地球科学(英文版)》2014,(3)
正SCIENCE CHINA Earth Sciences,an academic journal cosponsored by the Chinese Academy of Sciences and the National Natural Science Foundation of China,and published by Science China Press and Springer,is committed to publishing high-quality,original results in both basic and applied research. 相似文献
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《国际泥沙研究》2014,(4)
正Director:Shangfu Kuang,China Vice-directors:Chunhong Hu,China Duihu Ning,China Guangquan Liu,China The International Research and Training Center on Erosion and Sedimentation(IRTCES)was jointly set up by the Government of China and UNESCO on July 21,1984.It aims at the promotion of international exchange of knowledge and cooperation in the studies of erosion and 相似文献
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Richard D. Hey 《地球表面变化过程与地形》1979,4(1):59-72
Feedback mechanisms, which operate upstream through drawdown and backwater effects and downstream through sediment discharge are responsible for channel evolution. By combining these mechanisms with channel processes it euables a dynamic process-response model to be developed to simulate the initial evolution of straight gravel-bed channels. When erosion commences on a land surface, sediment entrained in the headwater reach by hydraulic action is selectively transported, deposited and reworked. This produces a damped oscillation between degradation and aggradation as the channel and valley respond to spatial and temporal variations in sediment calibre and hydraulic conditions. The initial cut and fill phases are responsible for valley incision and floodplain development while secondary and subsequent activity can produce river terraces. Eventually sediment entrainment in the headwaters declines as slopes are reduced. Subsequent channel evolution is relatively insignificant because it is dependent on local weathering activity producing material that can be transported on declining slopes. Therefore landforms produced during the initial phase of development, when local weathering was non-limiting, dominate the landscape. 相似文献