fault holding

简明释义

障碍保持

英英释义

例句

1.During the troubleshooting process, the technician discovered that fault holding 故障保持 was causing the machine to malfunction.

在故障排除过程中，技术人员发现fault holding 故障保持导致机器出现故障。

2.The engineer identified a problem in the system and determined that the issue was due to fault holding 故障保持 in the circuit.

工程师在系统中发现了一个问题，并确定该问题是由于电路中的fault holding 故障保持导致的。

3.The software update fixed the fault holding 故障保持 issue that had been affecting performance for weeks.

软件更新修复了影响性能数周的fault holding 故障保持问题。

4.The team conducted an analysis and found that fault holding 故障保持 was the root cause of the system failure.

团队进行了分析，发现fault holding 故障保持是系统故障的根本原因。

5.To prevent fault holding 故障保持, regular maintenance checks are essential.

为了防止fault holding 故障保持，定期维护检查是必不可少的。

作文

In the realm of geology and tectonics, the term fault holding refers to the ability of a fault line to maintain its position and resist movement over time. This concept is crucial in understanding how earthquakes occur and why certain areas remain stable while others are prone to seismic activity. A fault is essentially a crack in the Earth's crust where two blocks of land have moved past each other. When stress builds up along these fault lines due to tectonic forces, the potential for movement increases. However, some faults exhibit fault holding characteristics, meaning they can withstand this stress without slipping. The study of fault holding is significant for several reasons. Firstly, it helps geologists predict the likelihood of future earthquakes. By analyzing the historical behavior of faults, scientists can identify which faults are currently holding stress and which may be ready to slip. This predictive capability is vital for earthquake preparedness and risk mitigation in populated areas. For instance, regions like California, which are known for their active fault lines, benefit from understanding which faults are experiencing fault holding and which ones might be overdue for an earthquake. Secondly, the concept of fault holding plays a role in the field of engineering, particularly in the design of buildings and infrastructure. Engineers must consider the geological stability of the area when constructing new structures. If a building is located near a fault that exhibits fault holding, engineers might implement additional safety measures to ensure the structure can withstand potential seismic events. This proactive approach can save lives and reduce property damage during an earthquake. Moreover, the phenomenon of fault holding is not uniform across all fault lines. Some faults may hold for decades or even centuries before releasing their accumulated stress in a sudden slip, while others may show signs of creeping movement. Understanding the differences between these behaviors is essential for both geologists and engineers. Research into fault holding mechanisms has led to various models that attempt to explain why some faults behave differently from others. Factors such as rock type, moisture content, and the history of past seismic activity all play a role in determining a fault's behavior. In conclusion, the concept of fault holding is a critical aspect of geology that influences our understanding of earthquakes and their risks. By studying how faults hold stress and the conditions under which they may eventually slip, scientists and engineers can better prepare for seismic events. This knowledge not only aids in predicting earthquakes but also informs safe construction practices. As we continue to advance our understanding of these geological processes, the implications of fault holding will remain a focal point in both research and practical applications. Ultimately, recognizing the importance of fault holding in the context of earth sciences can lead to improved safety measures and a greater awareness of the natural world around us. It emphasizes the need for ongoing research and education in geology, ensuring that communities are equipped with the knowledge necessary to navigate the complexities of living in seismically active regions.

在地质学和构造学的领域中，术语fault holding指的是一个断层线能够维持其位置并在时间上抵抗运动的能力。这个概念对于理解地震是如何发生的，以及为什么某些地区保持稳定而其他地区容易发生地震活动至关重要。断层本质上是地壳中的一条裂缝，其中两块土地相互滑动。当由于构造力沿着这些断层线积累应力时，移动的潜力就会增加。然而，一些断层表现出fault holding特征，这意味着它们能够承受这种应力而不滑动。研究fault holding的重要性体现在几个方面。首先，它帮助地质学家预测未来地震的可能性。通过分析断层的历史行为，科学家可以识别出哪些断层当前正在承受应力，哪些可能准备滑动。这种预测能力对于地震准备和在人口稠密地区的风险减轻至关重要。例如，加利福尼亚州因其活跃的断层线而闻名，了解哪些断层正在经历fault holding，以及哪些可能逾期发生地震，对于该地区的安全至关重要。其次，fault holding的概念在工程领域也发挥着作用，特别是在建筑和基础设施设计中。工程师在建造新结构时必须考虑该地区的地质稳定性。如果建筑位于一个表现出fault holding的断层附近，工程师可能会实施额外的安全措施，以确保结构能够承受潜在的地震事件。这种主动的方法可以在地震期间拯救生命并减少财产损失。此外，fault holding现象在所有断层线中并不均匀。有些断层可能会持续数十年甚至数个世纪而不释放其积累的应力，而其他断层可能会表现出缓慢的运动。了解这些行为之间的差异对于地质学家和工程师都是至关重要的。对fault holding机制的研究导致各种模型试图解释为什么一些断层的行为与其他断层不同。岩石类型、湿度含量和过去地震活动的历史等因素都在决定断层行为中扮演着角色。总之，fault holding的概念是地质学的一个关键方面，影响着我们对地震及其风险的理解。通过研究断层如何承受应力以及在何种条件下最终可能滑动，科学家和工程师可以更好地为地震事件做好准备。这种知识不仅有助于预测地震，还为安全的建筑实践提供了依据。随着我们对这些地质过程理解的不断深入，fault holding的意义将继续成为研究和实际应用的重点。最终，认识到fault holding在地球科学背景下的重要性，可以导致更好的安全措施，并增强我们对周围自然世界的认识。这强调了持续进行地质研究和教育的必要性，确保社区具备应对生活在地震活跃区域复杂性的知识。