geodynamic

简明释义

英[ˌdʒiːoʊdaɪˈnæmɪk]美[ˌdʒiːoʊdaɪˈnæmɪk]

adj. 地球动力学的

英英释义

单词用法

同义词

反义词

例句

1.The evolution features of the Jiaolai Basin are discussed in this paper on the basis of its regional structure, geodynamic background and sedimentary features of the Mesozoic and Cenozoic.

根据胶莱盆地区域地质特征，地球动力学背景及盆地中、新生代沉积特征分析，论述盆地的发育和演化阶段，并对胶莱盆地含油气前景进行探讨。

2.Moreover, your study here will encompass theoretical and experimental science as well as fieldwork to study geodynamic processes and the structure of the Earth and other planets.

另外，你的学习将会包含理论的和应用的科学例如野外的实习以学习地球动力过程和地球及其他行星的结构。

3.The geodynamic study of global tectonics has developed from a single dynamic driving mechanism to the geodynamic system consisting of many dynamic factors.

在全球构造驱动力源与驱动机制研究方面，开始由单一动力驱动机制研究转入多种动力因子所构成地球动力系统的综合研究。

4.The geodynamic setting of the ductile shear may be the later Magma Intrusion and the brittle fracture is related to the NS-trending stress field in this area.

韧性剪切作用的动力学背景可能是受后期岩浆侵入的影响，最后的脆性破裂应与区域上存在南北向的压应力有关。

5.The establishment of the paired high-pressure belts is of major significance for solving the problem of the geodynamic evolution of the boundary of the North China and Yangtze plates.

双高压变质带的确立对解决华北-扬子板块边界地球动力学演化问题具有重要意义。

6.The geodynamic regime of mantle-derived uranium metallogenesis and theory of hotspot uranium metallogenesis are briefly discussed.

文章扼要阐述了幔源铀成矿的地球动力学背景，评述了热点铀成矿理论。

7.As the direct product of magmatism during the process of tectonic evolution, volcanic rocks are the important clue in discussing the geological events and geodynamic evolution.

火山岩是大地构造演化过程中岩浆作用的直接产物，是探讨地质事件和地球动力学演化的重要线索。

8.The study of geodynamic 地球动力学 processes helps us understand plate tectonics.

对地球动力学过程的研究帮助我们理解板块构造。

9.Researchers are investigating the geodynamic 地球动力学 factors that lead to volcanic eruptions.

研究人员正在调查导致火山喷发的地球动力学因素。

10.The geodynamic 地球动力学 model predicts the movement of tectonic plates over millions of years.

该地球动力学模型预测了数百万年来构造板块的运动。

11.Understanding geodynamic 地球动力学 processes is crucial for earthquake risk assessment.

理解地球动力学过程对于地震风险评估至关重要。

12.The geodynamic 地球动力学 framework provides insight into mountain formation.

该地球动力学框架提供了山脉形成的洞察。

作文

The Earth is a dynamic planet, constantly undergoing changes that shape its surface and interior. These changes are driven by various processes that can be collectively referred to as geodynamic (地球动力学). Understanding these processes is crucial for comprehending the evolution of our planet, as well as for predicting natural disasters such as earthquakes and volcanic eruptions. Geodynamics is the study of the forces and movements within the Earth. It encompasses a range of phenomena, from the tectonic shifts that lead to the formation of mountains and ocean basins to the thermal dynamics of the Earth's interior. The theory of plate tectonics, which explains how the Earth's lithosphere is divided into several plates that float on the semi-fluid asthenosphere below, is a fundamental aspect of geodynamic (地球动力学) research. This theory not only helps us understand the physical structure of the Earth but also provides insights into the historical geological events that have shaped our planet over millions of years. One of the most significant aspects of geodynamic (地球动力学) studies is the investigation of seismic activity. Earthquakes occur when stress builds up along fault lines, and understanding the geodynamic (地球动力学) processes that lead to this stress is essential for earthquake preparedness and risk mitigation. Scientists use various tools, including satellite measurements and seismographs, to monitor the movements of tectonic plates and predict potential seismic events. This research is vital for communities living in earthquake-prone regions, as it can save lives and reduce property damage through better building practices and emergency response planning. Volcanic activity is another area where geodynamic (地球动力学) processes play a crucial role. Volcanoes are formed when magma from the Earth's interior escapes to the surface, often due to the movement of tectonic plates. Understanding the geodynamic (地球动力学) mechanisms behind volcanic eruptions can help scientists predict when a volcano might erupt and assess the potential hazards associated with such events. For instance, the eruption of Mount St. Helens in 1980 provided valuable data on the geodynamic (地球动力学) processes that precede an eruption, leading to improved monitoring techniques that are still in use today. Moreover, geodynamic (地球动力学) studies are not limited to Earth alone. Researchers are also investigating the geodynamic (地球动力学) processes of other celestial bodies, such as Mars and Venus, to gain insights into their geological histories and potential for hosting life. By comparing the geodynamic (地球动力学) activities of different planets, scientists can better understand the conditions that lead to planetary evolution and the development of habitable environments. In conclusion, geodynamic (地球动力学) processes are fundamental to our understanding of the Earth and its behavior. They provide critical insights into the mechanisms behind earthquakes, volcanic eruptions, and the overall evolution of our planet. As technology advances, the field of geodynamic (地球动力学) research continues to grow, offering new tools and methods to explore the complexities of our dynamic Earth. With ongoing research and increased collaboration among scientists worldwide, we can hope to unravel the mysteries of our planet’s geodynamic (地球动力学) processes and use that knowledge to create a safer and more resilient future for all.

地球是一个动态的星球，不断经历着塑造其表面和内部的变化。这些变化是由各种过程驱动的，这些过程可以统称为地球动力学。理解这些过程对于理解我们星球的演变以及预测自然灾害（如地震和火山喷发）至关重要。 地球动力学是研究地球内部的力量和运动的学科。它涵盖了一系列现象，从导致山脉和海洋盆地形成的构造移动，到地球内部的热动力学。板块构造理论解释了地球的岩石圈是如何分为几个漂浮在下面半流体的软流圈上的板块，这是地球动力学研究的基本方面。这一理论不仅帮助我们理解地球的物理结构，还提供了对数百万年来塑造我们星球的历史地质事件的见解。 地球动力学研究中最重要的方面之一是对地震活动的调查。地震发生在沿着断层线的应力积累时，理解导致这种应力的地球动力学过程对地震准备和风险缓解至关重要。科学家使用包括卫星测量和地震仪在内的各种工具来监测构造板块的运动，并预测潜在的地震事件。这项研究对生活在地震多发地区的社区至关重要，因为它可以通过更好的建筑实践和应急响应规划来拯救生命并减少财产损失。 火山活动是另一个地球动力学过程发挥关键作用的领域。当来自地球内部的岩浆逃逸到表面时，火山就会形成，通常是由于构造板块的运动。理解火山喷发背后的地球动力学机制可以帮助科学家预测火山何时可能喷发，并评估与此类事件相关的潜在危险。例如，1980年圣海伦斯山的喷发提供了有关喷发前地球动力学过程的宝贵数据，导致了改进的监测技术，这些技术至今仍在使用。 此外，地球动力学研究并不限于地球本身。研究人员还在调查其他天体（如火星和金星）的地球动力学过程，以获得对其地质历史和潜在宿主生命的见解。通过比较不同星球的地球动力学活动，科学家可以更好地理解导致行星演化和适宜居住环境发展的条件。 总之，地球动力学过程是我们理解地球及其行为的基础。它们为地震、火山喷发以及我们星球的整体演变背后的机制提供了关键见解。随着技术的进步，地球动力学研究领域不断发展，提供了探索我们动态地球复杂性的新的工具和方法。通过持续的研究和全球科学家的合作，我们希望揭开我们星球地球动力学过程的神秘面纱，并利用这些知识为所有人创造一个更安全、更具韧性的未来。