amphidromic system

简明释义

交汇潮

英英释义

例句

1.The study of the ocean currents revealed a complex amphidromic system that influences local tidal patterns.

对海洋洋流的研究揭示了一个复杂的双向潮汐系统，影响着当地的潮汐模式。

2.The amphidromic system plays a key role in the navigation of ships through tidal waters.

该双向潮汐系统在船只通过潮汐水域的导航中起着关键作用。

3.In coastal engineering, understanding the amphidromic system is crucial for predicting erosion.

在海岸工程中，理解双向潮汐系统对预测侵蚀至关重要。

4.Marine biologists study the effects of the amphidromic system on marine life distribution.

海洋生物学家研究双向潮汐系统对海洋生物分布的影响。

5.The amphidromic system can cause significant variations in water levels across different regions.

该双向潮汐系统会导致不同区域水位的显著变化。

作文

The term amphidromic system refers to a unique phenomenon in oceanography and tidal studies, describing a system where the tides rotate around a central point known as an amphidromic point. This concept is crucial for understanding how tidal waves propagate through oceans and seas, influencing coastal regions and marine life. In simple terms, an amphidromic system is characterized by the absence of a tidal range at the amphidromic point itself, while tidal ranges increase as one moves away from this point. To better grasp the significance of an amphidromic system, it's essential to explore its formation and implications. Tides are primarily caused by the gravitational pull of the moon and the sun on the Earth's waters. As the Earth rotates, different areas experience varying gravitational forces, leading to the rise and fall of sea levels. In an amphidromic system, the interplay between these gravitational forces and the Earth's rotation creates a complex pattern of tidal movement. One of the most fascinating aspects of an amphidromic system is its relationship with coastal geography. For instance, the presence of landmasses can significantly alter tidal patterns, creating areas where tides are amplified or diminished. Coastal cities often rely on accurate tidal predictions to manage shipping schedules, fishing activities, and even flood defenses. Understanding the dynamics of an amphidromic system helps scientists and policymakers make informed decisions about coastal management and environmental conservation. Moreover, the study of amphidromic systems extends beyond mere academic interest; it has practical applications in various fields. For example, renewable energy technologies, such as tidal energy converters, benefit from understanding tidal patterns associated with amphidromic systems. By harnessing the predictable nature of tides, engineers can develop efficient systems that generate clean energy, contributing to global sustainability efforts. In addition to energy production, the ecological implications of amphidromic systems are profound. Tides play a crucial role in nutrient cycling and the health of marine ecosystems. Areas influenced by amphidromic systems often support diverse habitats, including estuaries and wetlands, which are vital for numerous species. Protecting these ecosystems requires a comprehensive understanding of tidal dynamics, emphasizing the importance of studying amphidromic systems in the context of climate change and habitat preservation. In conclusion, the amphidromic system is a fundamental concept in the study of ocean tides, with far-reaching implications for coastal management, renewable energy, and ecological conservation. As we face the challenges posed by climate change and environmental degradation, understanding the intricacies of amphidromic systems will be essential for developing sustainable solutions that balance human needs with the health of our planet. Through continued research and collaboration, we can unlock the mysteries of these dynamic systems and harness their potential for a more sustainable future.

“amphidromic system”一词指的是海洋学和潮汐研究中的一种独特现象，描述了潮汐围绕一个称为“潮汐中心点”的中心点旋转的系统。这个概念对于理解潮汐波如何在海洋和海洋中传播、影响沿海地区和海洋生物至关重要。简单来说，amphidromic system的特点是在潮汐中心点本身没有潮汐幅度，而随着远离该点，潮汐幅度逐渐增加。 为了更好地理解amphidromic system的重要性，有必要探讨其形成及影响。潮汐主要是由于月球和太阳对地球水体的引力作用而产生的。随着地球的自转，不同区域经历不同的引力，从而导致海平面的升降。在amphidromic system中，这些引力与地球自转之间的相互作用创造了复杂的潮汐运动模式。 amphidromic system最迷人的一个方面是它与沿海地理的关系。例如，陆地的存在可以显著改变潮汐模式，造成一些地方潮汐被放大或减弱。沿海城市通常依赖准确的潮汐预测来管理航运时间表、渔业活动甚至洪水防御。理解amphidromic system的动态有助于科学家和政策制定者就沿海管理和环境保护做出明智的决策。 此外，amphidromic systems的研究超越了单纯的学术兴趣，具有广泛的实际应用。例如，潮汐能转换器等可再生能源技术受益于对amphidromic systems相关潮汐模式的理解。通过利用潮汐的可预测性，工程师可以开发高效的系统来生成清洁能源，为全球可持续发展努力做出贡献。 除了能源生产外，amphidromic systems的生态影响也深远。潮汐在营养循环和海洋生态系统健康中发挥着关键作用。受amphidromic systems影响的区域通常支持多样的栖息地，包括湿地和河口，这对众多物种至关重要。保护这些生态系统需要对潮汐动态有全面的理解，强调在气候变化和栖息地保护背景下研究amphidromic systems的重要性。 总之，amphidromic system是潮汐研究中的一个基本概念，对沿海管理、可再生能源和生态保护有着深远的影响。随着我们面临气候变化和环境退化带来的挑战，理解amphidromic systems的复杂性将对开发平衡人类需求与地球健康的可持续解决方案至关重要。通过持续的研究与合作，我们能够揭开这些动态系统的神秘面纱，利用其潜力为更加可持续的未来服务。