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971.
阐述河北永清MS 4.3地震构造背景和地震活动特征,依据仪器烈度,通过对地震现场调查点评定烈度,根据极震区震感现象和分布范围,确定极震区影响烈度为Ⅴ度,并圈定地震烈度图分布范围,分析此次地震震害特征。 相似文献
972.
2016年7月31日苍梧MS 5.4地震的发生,标志着东南沿海地震带第5活跃幕的开始。通过该地震序列、震源机制、强震动记录、地震地质背景,地震灾害及震前异常变化,分析此次MS 5.4地震活动及震害特征,为广西地区强震震后趋势判断、强震响应提供依据,并对地震前后采用的应急对策及发挥的作用进行论述。 相似文献
973.
地震发生后,强震动观测台网可以获取灾区分布式台站位置的强震动记录,通过基于这些强震动记录得到的地震动参数可以快速地评估地震烈度的空间分布,以迅速判定不同地区的受灾程度,尤其是地震极震区的分布范围,为政府开展应急救援并合理地分配救援力量、物资等提供依据,以保证救援人员及时、准确地到达极震区展开搜救工作,减少人民群众的生命财产损失。本文介绍了国内外7种地震仪器的烈度计算方法,基于四川九寨沟M7.0级地震获取的强震动记录,对这7种方法的计算烈度值进行了对比分析。结果表明,各方法计算的仪器烈度与宏观烈度的差值均在1度误差范围以内,均显示了良好的实用性,且行业标准法和综合判别法两者的计算结果较为一致。 相似文献
974.
深渊观测是开展深渊科学研究的前提。文章介绍了2020年7月"东方红3"船在马里亚纳海沟"挑战者深渊"附近完成的一次海洋调查。基于船载温盐深综合剖面测量系统获取的万米级剖面数据,分析全海深的温盐性质,并依据Thorpe尺度方法和细尺度参数化方法,进一步估算不同深度层的湍动能耗散率。结果表明:"挑战者深渊"的深层海水十分稳定, 3 000—5 000 dbar的温盐特征与下层绕极水相同;受弱层结背景下的内潮影响, 5 000—8 000 m的耗散率显著提升。本次调查获取的万米级水文剖面为马里亚纳海沟的深渊探索提供了数据方面的支撑。 相似文献
975.
使用胶东及邻区地震数据,对于发生在基岩出露区的18次地震的30条可靠等震线,利用最小二乘法,拟合胶东地区地震烈度衰减关系公式。与华北地区地震烈度衰减关系进行比较,发现胶东地区地震烈度衰减较慢。胶东地区地震烈度衰减关系的建立,可以辅助制定相关应急预案和震后快速评估。 相似文献
976.
阐述张家口市尚义M_S 4.0地震构造背景、地震活动特征,总结地震应急调查成果,介绍极震区震感现象和分布范围。通过对地震现场调查点和电话调查点的烈度评定,确定极震区的影响烈度为Ⅴ度,圈定地震等烈度分布区域,同时修正观测仪器震中位置。结合本次地震的宏观烈度分布、震源机制和震区卫星影像的线性构造解释等资料,讨论本次地震的孕震构造和发震断层。 相似文献
977.
Ricardo N. Szupiany Cecilia Lopez Weibel Massimo Guerrero Francisco Latosinski Molly Wood Lucas Dominguez Ruben Kevin Oberg 《地球表面变化过程与地形》2019,44(6):1295-1308
Quantifying sediment flux within rivers is a challenge for many disciplines due, mainly, to difficulties inherent to traditional sediment sampling methods. These methods are operationally complex, high cost, and high risk. Additionally, the resulting data provide a low spatial and temporal resolution estimate of the total sediment flux, which has impeded advances in the understanding of the hydro-geomorphic characteristics of rivers. Acoustic technologies have been recognized as a leading tool for increasing the resolution of sediment data by relating their echo intensity level measurements to suspended sediment. Further effort is required to robustly test and develop these techniques across a wide range of conditions found in natural river systems. This article aims to evaluate the application of acoustic inversion techniques using commercially available, down-looking acoustic Doppler current profilers (ADCPs) in quantifying suspended sediment in a large sand bed river with varying bi-modal particle size distributions, wash load and suspended-sand ratios, and water stages. To achieve this objective, suspended sediment was physically sampled along the Paraná River, Argentina, under various hydro-sedimentological regimes. Two ADCPs emitting different sound frequencies were used to simultaneously profile echo intensity level within the water column. Using the sonar equation, calibrations were determined between suspended-sand concentrations and acoustic backscatter to solve the inverse problem. The study also analyzed the roles played by each term of the sonar equation, such as ADCP frequency, power supply, instrument constants, and particle size distributions typically found in sand bed rivers, on sediment attenuation and backscatter. Calibrations were successfully developed between corrected backscatter and suspended-sand concentrations for all sites and ADCP frequencies, resulting in mean suspended-sand concentration estimates within about 40% of the mean sampled concentrations. Noise values, calculated using the sonar equation and sediment sample characteristics, were fairly constant across evaluations, suggesting that they could be applied to other sand bed rivers. © 2018 John Wiley & Sons, Ltd. 相似文献
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979.
980.
Hao-Jie Huang 《地球表面变化过程与地形》2020,45(15):3943-3954
Particle–turbulence interaction has been a research focus in the field of pneumatic transport, especially in aeolian environments. However, knowledge regarding the effect of saltating particles on the turbulence characteristics is very limited. In this article, a process of sand-laden flow from forming sand streamers to stability is investigated via a coupled mathematical model of wind-blown sand that includes the spatiotemporal development. The variations in the turbulence characteristics, such as the mean velocity and turbulence intensity in clean air or sand-laden flow field, are analyzed. The results show that the splash process of sand grains near the wall decrease the wind speed in the saltation layer and destroy the low-speed streaks. Moreover, the profiles of streamwise turbulence intensity exhibit a transition from ‘decreasing’ to ‘increasing’ and approximately intersect at an ‘intensity focus’, which is presented for the first time. Furthermore, it was found that saltating particles could enhance the Reynolds stress. Meanwhile, it was also noticed that the shear stress at the wall surface is greater than the impact threshold and that there is a tendency towards the impact threshold. Therefore, saltation makes the particle Reynolds number of sand-laden flow higher than that under non-saltation conditions, thus changing the particles’ effect on the turbulence intensity. Gravity-dominated saltation is probably the most essential difference between wind-blown sand and other traditional two-phase flows. © 2020 John Wiley & Sons, Ltd. 相似文献