seismography

简明释义

英[saɪzˈmɒɡrəfi]美[saɪzˈmɒɡrəfi]

n. 地震定测法；地震学（等于 seismology）

英英释义

单词用法

同义词

反义词

例句

1.The new design of digital geophone used in the occasion of high resolution seismic prospecting will pay an important roll in a new kind of seismography.

新型数字式地震检波器的设计，完全可以适应高分辨率地震勘探的要求，为基于可控震源的新型地震仪的实现起到了决定性作用。

2.The new design of digital geophone used in the occasion of high resolution seismic prospecting will pay an important roll in a new kind of seismography.

新型数字式地震检波器的设计，完全可以适应高分辨率地震勘探的要求，为基于可控震源的新型地震仪的实现起到了决定性作用。

3.The seismic modeling is the foundation of the seismic prospecting and the seismography.

地震数值模拟是地震勘探和地震学的基础。

4.The study of earthquakes relies heavily on seismography 地震测量法 to record seismic waves.

地震研究在很大程度上依赖于seismography 地震测量法来记录地震波。

5.Scientists use seismography 地震测量法 to monitor tectonic plate movements.

科学家们使用seismography 地震测量法来监测构造板块的运动。

6.Advancements in seismography 地震测量法 technology have improved our ability to predict earthquakes.

在seismography 地震测量法技术上的进步提高了我们预测地震的能力。

7.The data collected from seismography 地震测量法 can help engineers design safer buildings.

从seismography 地震测量法收集的数据可以帮助工程师设计更安全的建筑。

8.After the earthquake, the seismography 地震测量法 results were analyzed to understand its impact.

在地震发生后，分析了seismography 地震测量法的结果以了解其影响。

作文

Seismography is a fascinating field that plays a crucial role in understanding the dynamics of our planet. It refers to the scientific study and measurement of seismic waves generated by earthquakes, volcanic activity, and other geological processes. The primary instrument used in this field is known as a seismograph, which detects and records these waves. By analyzing the data collected through seismography (地震测量), scientists can gain insights into the Earth's interior structure and the behavior of tectonic plates. The importance of seismography (地震测量) cannot be overstated, especially in regions prone to earthquakes. For instance, in countries like Japan and California, where seismic activity is prevalent, seismography (地震测量) provides essential information that helps in predicting potential earthquakes and mitigating their impact. This predictive capability is vital for saving lives and minimizing property damage. Moreover, seismography (地震测量) is not limited to earthquake detection. It also plays a significant role in studying other natural phenomena such as tsunamis and landslides. By monitoring seismic waves, researchers can determine the origin and intensity of these events, allowing for timely warnings and preparedness measures. This aspect of seismography (地震测量) highlights its interdisciplinary nature, bridging geology, engineering, and emergency management. In addition to its practical applications, seismography (地震测量) also contributes to our understanding of the Earth's history. By examining ancient seismic records, scientists can reconstruct past geological events, providing valuable context for current seismic activity. This historical perspective is essential for understanding long-term trends and patterns in the Earth's geological processes. The technology behind seismography (地震测量) has advanced significantly over the years. Modern seismographs are highly sensitive instruments capable of detecting even the faintest seismic waves. They utilize various techniques, including digital recording and real-time data transmission, to enhance the accuracy and efficiency of seismic monitoring. As technology continues to evolve, so does the field of seismography (地震测量), leading to improved methodologies and insights. Education and research in seismography (地震测量) are also growing fields. Universities and research institutions around the world are increasingly focusing on seismology programs, training the next generation of scientists to tackle the challenges posed by seismic hazards. These programs often emphasize the importance of interdisciplinary collaboration, encouraging students to engage with experts from various fields to address complex geological issues. In conclusion, seismography (地震测量) is an essential scientific discipline that enhances our understanding of the Earth and its processes. Its applications in earthquake prediction, natural disaster management, and historical geological research underscore its significance in today's world. As we continue to face the challenges posed by natural disasters, the role of seismography (地震测量) will undoubtedly become even more critical, highlighting the need for ongoing research, education, and technological advancement in this vital field.

地震测量是一个迷人的领域，在理解我们星球的动态方面发挥着至关重要的作用。它指的是对由地震、火山活动和其他地质过程产生的地震波进行科学研究和测量。该领域使用的主要仪器被称为地震仪，它可以检测和记录这些波。通过分析通过seismography（地震测量）收集的数据，科学家可以深入了解地球内部结构和构造板块的行为。 seismography（地震测量）的重要性不容小觑，尤其是在易发生地震的地区。例如，在日本和加利福尼亚等地，地震活动频繁，seismography（地震测量）提供了重要的信息，有助于预测潜在的地震并减轻其影响。这种预测能力对于拯救生命和减少财产损失至关重要。 此外，seismography（地震测量）不仅限于地震检测。它在研究其他自然现象如海啸和滑坡方面也发挥着重要作用。通过监测地震波，研究人员可以确定这些事件的起源和强度，从而及时发出警报和采取应对措施。seismography（地震测量）的这一方面突显了其跨学科的性质，桥接了地质学、工程学和应急管理。 除了实用应用，seismography（地震测量）还促进了我们对地球历史的理解。通过检查古代地震记录，科学家可以重建过去的地质事件，为当前的地震活动提供有价值的背景。这种历史视角对于理解地球地质过程中的长期趋势和模式至关重要。 随着时间的推移，seismography（地震测量）背后的技术也取得了显著进步。现代地震仪是高度敏感的仪器，能够检测到即使是最微弱的地震波。它们利用各种技术，包括数字记录和实时数据传输，以提高地震监测的准确性和效率。随着技术的不断发展，seismography（地震测量）领域也在不断发展，导致方法和见解的改善。 教育和研究方面，seismography（地震测量）也是一个不断增长的领域。全球各地的大学和研究机构越来越关注地震学课程，培养下一代科学家来应对地震灾害带来的挑战。这些课程通常强调跨学科合作的重要性，鼓励学生与各个领域的专家合作，以解决复杂的地质问题。 总之，seismography（地震测量）是一个重要的科学学科，增强了我们对地球及其过程的理解。它在地震预测、自然灾害管理和历史地质研究中的应用凸显了它在当今世界的重要性。随着我们继续面临自然灾害带来的挑战，seismography（地震测量）的角色无疑将变得更加关键，强调了在这一重要领域中持续研究、教育和技术进步的必要性。