dynamical theory of tide

简明释义

潮汐动力论

英英释义

例句

1.The researchers applied the dynamical theory of tide to predict the tidal patterns for the upcoming year.

研究人员应用了潮汐动力学理论来预测即将到来的年度潮汐模式。

2.The dynamical theory of tide provides insights into how gravitational forces affect tidal movements.

在潮汐动力学理论中，提供了重力如何影响潮汐运动的见解。

3.Scientists use the dynamical theory of tide to model the impact of climate change on ocean tides.

科学家利用潮汐动力学理论来模拟气候变化对海洋潮汐的影响。

4.The dynamical theory of tide helps in explaining the variations in sea levels during different lunar phases.

潮汐动力学理论有助于解释不同月相期间海平面的变化。

5.Understanding the dynamical theory of tide is crucial for coastal engineering projects.

理解潮汐动力学理论对沿海工程项目至关重要。

作文

The study of ocean tides has fascinated scientists for centuries, and one of the most important frameworks for understanding this phenomenon is the dynamical theory of tide. This theory provides a comprehensive explanation of how gravitational forces exerted by celestial bodies, primarily the moon and the sun, influence the movement of water in the Earth's oceans. By analyzing the interactions between these forces and the Earth's rotation, the dynamical theory of tide helps us predict the timing and magnitude of tidal changes with remarkable accuracy.One of the key components of the dynamical theory of tide is the concept of equilibrium tide. This refers to the theoretical state of the ocean where the water level responds instantaneously to the gravitational pull of the moon and the sun. In reality, however, various factors such as the shape of coastlines, ocean floor topography, and local wind conditions complicate this ideal scenario. The dynamical theory of tide takes these factors into account, allowing for a more nuanced understanding of tidal behavior.Furthermore, the dynamical theory of tide incorporates the principles of fluid dynamics, which describe how fluids move and interact under various forces. This is essential for modeling the complex movements of water caused by tides. For instance, when the gravitational pull from the moon causes water to bulge on the side of the Earth facing the moon, it also creates a corresponding bulge on the opposite side due to the centrifugal force resulting from the Earth-moon system's rotation. The dynamical theory of tide explains these phenomena through mathematical equations that capture the intricate balance of forces at play.In addition to predicting tidal movements, the dynamical theory of tide has practical applications in various fields. For example, coastal engineering projects rely on accurate tidal predictions to design structures that can withstand the forces of waves and currents. Similarly, navigation systems for ships and boats depend on tidal data to ensure safe passage through coastal waters. The ability to forecast tides accurately is critical for fishermen, surfers, and recreational boaters who must consider tidal conditions in their activities.Moreover, the dynamical theory of tide has implications for understanding climate change and its effects on sea levels. As global temperatures rise, melting polar ice caps and glaciers contribute to rising sea levels, which can alter tidal patterns and coastal ecosystems. By applying the dynamical theory of tide, researchers can model potential future scenarios and assess the impacts of these changes on coastal communities.In conclusion, the dynamical theory of tide is a fundamental aspect of oceanography that enhances our understanding of tidal movements and their implications. Through its integration of gravitational forces, fluid dynamics, and real-world factors, it provides a robust framework for predicting tides and addressing the challenges posed by changing environmental conditions. As we continue to explore the complexities of our planet's oceans, the dynamical theory of tide will remain a vital tool for scientists and practitioners alike.

潮汐的研究吸引了科学家们几个世纪以来的关注，其中一个重要的框架是dynamical theory of tide（潮汐动力学理论）。该理论全面解释了月球和太阳等天体施加的引力如何影响地球海洋水体的运动。通过分析这些力量与地球自转之间的相互作用，dynamical theory of tide帮助我们以惊人的准确性预测潮汐变化的时机和幅度。dynamical theory of tide的一个关键组成部分是平衡潮的概念。这指的是海洋在引力作用下瞬时响应的理论状态，主要来自月球和太阳。然而，实际上，海岸线的形状、海底地形和局部风况等各种因素使这一理想情景变得复杂。dynamical theory of tide考虑到了这些因素，使我们对潮汐行为有了更细致的理解。此外，dynamical theory of tide还结合了流体动力学原理，描述了流体在各种力作用下的运动和相互作用。这对于建模潮汐引起的复杂水运动至关重要。例如，当月球的引力导致水在面向月球的一侧隆起时，由于地球-月球系统自转产生的离心力，也会在相对一侧形成相应的隆起。dynamical theory of tide通过数学方程解释了这些现象，捕捉到作用力之间的微妙平衡。除了预测潮汐运动外，dynamical theory of tide在多个领域也具有实际应用。例如，沿海工程项目依赖于准确的潮汐预测，以设计能够承受波浪和水流力量的结构。同样，船舶和小艇的导航系统也依赖于潮汐数据，以确保安全通过沿海水域。准确预测潮汐的能力对渔民、冲浪者和休闲划船者至关重要，他们在活动中必须考虑潮汐条件。此外，dynamical theory of tide对于理解气候变化及其对海平面的影响也具有重要意义。随着全球温度上升，极地冰盖和冰川的融化导致海平面上升，这可能改变潮汐模式和沿海生态系统。通过应用dynamical theory of tide，研究人员可以建模潜在的未来情景，并评估这些变化对沿海社区的影响。总之，dynamical theory of tide是海洋学的一个基本方面，增强了我们对潮汐运动及其影响的理解。通过将引力、流体动力学和现实世界因素结合起来，它提供了一个强大的框架，用于预测潮汐并应对气候变化带来的挑战。随着我们继续探索地球海洋的复杂性，dynamical theory of tide将继续成为科学家和从业者的重要工具。