coseismic

简明释义

英[ˌkəʊˈsiːzmɪk]美[ˌkoʊˈsaɪzmɪk]

adj. 同震的；等震波圈的

n. 同震线

英英释义

单词用法

同义词

反义词

例句

1.Earthquake liquefaction, caused by coseismic shakes, is controlled by soil conditions which are the results of geomorphic processes.

地震液化是同震震动引起的，同时也受地貌活动创造的土壤条件控制。

2.Following the idea of coseismic stress-triggering, coseismic strain steps recorded by borehole strainmeters are used to study coseismic stress-triggered fault slips.

沿着同震应力触发的思路，提出了利用钻孔应变观测记录的同震应变阶反演同震应力触发断层活动的方法。

3.Strain steps recorded by borehole strainmeters are of special values in studies of coseismic stress triggered fault activities.

钻孔应变观测记录的同震应变阶对于研究同震应力触发断层活动具有特殊的价值。

4.Following the idea of coseismic stress-triggering, coseismic strain steps recorded by borehole strainmeters are used to study coseismic stress-triggered fault slips.

沿着同震应力触发的思路，提出了利用钻孔应变观测记录的同震应变阶反演同震应力触发断层活动的方法。

5.Researchers are analyzing coseismic 同震的 data to improve earthquake prediction models.

研究人员正在分析同震的数据，以改善地震预测模型。

6.Understanding coseismic 同震的 phenomena is crucial for assessing earthquake hazards.

理解同震的现象对于评估地震危险至关重要。

7.The study focused on the coseismic 同震的 changes in groundwater levels after the quake.

该研究集中在地震后地下水位的同震的变化上。

8.The geologists studied the coseismic 同震的 effects of the recent earthquake on the surrounding landscape.

地质学家研究了最近地震对周围景观的同震的影响。

9.The coseismic 同震的 displacement was measured using advanced GPS technology.

使用先进的GPS技术测量了同震的位移。

作文

The study of earthquakes has always been a fascinating field of research, especially when considering the various phenomena that occur as a result of seismic activity. One term that often arises in this context is coseismic, which refers to events or changes that occur simultaneously with an earthquake. Understanding the implications of coseismic activities can provide valuable insights into the behavior of the Earth's crust and the mechanisms behind seismic events.When an earthquake strikes, it does not only cause immediate shaking and destruction; it also triggers a series of coseismic effects that can be both intriguing and alarming. For instance, landslides, ground ruptures, and tsunamis can all be classified as coseismic phenomena. These events can significantly amplify the damage caused by the initial quake, leading to further loss of life and property. Therefore, studying coseismic occurrences is crucial for disaster preparedness and risk mitigation.One of the most notable examples of coseismic effects is the phenomenon of ground shaking. When seismic waves travel through the Earth, they cause the ground to vibrate. This vibration can lead to structural failures in buildings and bridges, resulting in catastrophic consequences. Engineers and architects must take these coseismic factors into account when designing structures in earthquake-prone areas. By incorporating materials and designs that can withstand such forces, they can help ensure the safety of occupants during seismic events.Another interesting aspect of coseismic activity is the impact it has on groundwater systems. Research has shown that large earthquakes can alter the flow of underground water, leading to changes in water levels in wells and springs. These alterations can affect local ecosystems and agriculture, making it essential for scientists to monitor coseismic changes in hydrology following major quakes. Understanding these shifts can aid in managing water resources and preparing for potential droughts or floods.Moreover, coseismic phenomena can also influence the behavior of other geological processes. For example, after a significant earthquake, the stress distribution in the Earth's crust changes, potentially triggering additional seismic events in nearby fault lines. This interconnectedness highlights the importance of studying coseismic effects to predict future earthquakes and understand their patterns.In conclusion, the term coseismic encompasses a range of phenomena that occur concurrently with earthquakes, each with its own implications for the environment and human society. From structural engineering to hydrology and geology, the understanding of coseismic activities is vital for enhancing our preparedness for natural disasters. As research continues to evolve, it is imperative that we remain vigilant in studying these occurrences to mitigate risks and protect lives. Through collaboration among scientists, engineers, and policymakers, we can build a more resilient future in the face of seismic challenges.

地震的研究一直是一个引人入胜的研究领域，特别是在考虑到由于地震活动而发生的各种现象时。一个常常出现在此背景下的术语是coseismic，它指的是与地震同时发生的事件或变化。理解coseismic活动的影响可以为了解地壳的行为和地震事件背后的机制提供宝贵的见解。当地震发生时，它不仅会造成立即的震动和破坏；它还会触发一系列的coseismic效应，这些效应既令人感兴趣又令人担忧。例如，山体滑坡、地面破裂和海啸都可以被归类为coseismic现象。这些事件可以显著加剧初始地震造成的损害，导致进一步的生命和财产损失。因此，研究coseismic事件对于灾害准备和风险缓解至关重要。coseismic效应中最显著的例子之一是地面震动现象。当地震波穿过地球时，它们会导致地面振动。这种振动可能导致建筑物和桥梁的结构失效，从而造成灾难性的后果。工程师和建筑师在设计位于地震频发地区的结构时，必须考虑这些coseismic因素。通过采用能够承受这种力量的材料和设计，他们可以帮助确保在地震事件期间居住者的安全。coseismic活动的另一个有趣方面是它对地下水系统的影响。研究表明，大型地震可以改变地下水的流动，导致井和泉水的水位变化。这些变化可能会影响当地生态系统和农业，因此科学家必须在重大地震后监测coseismic水文变化。了解这些变化可以帮助管理水资源，并为潜在的干旱或洪水做好准备。此外，coseismic现象还可以影响其他地质过程的行为。例如，在一次重大的地震之后，地壳中的应力分布发生变化，可能会在附近的断层线上引发额外的地震事件。这种相互联系凸显了研究coseismic效应以预测未来地震和理解其模式的重要性。总之，术语coseismic涵盖了一系列与地震同时发生的现象，每一种现象对环境和人类社会都有其特定的影响。从结构工程到水文学和地质学，对coseismic活动的理解对于增强我们对自然灾害的准备至关重要。随着研究的不断发展，我们必须保持警惕，研究这些事件，以减轻风险并保护生命。通过科学家、工程师和政策制定者之间的合作，我们可以在面对地震挑战时建立一个更具韧性的未来。