turbulent motion

简明释义

湍动

英英释义

例句

1.Scientists study 湍流运动 in fluids to better understand weather patterns.

科学家研究湍流运动以更好地理解天气模式。

2.The river's 湍流运动 made it difficult for kayakers to navigate safely.

河流的湍流运动使得皮划艇运动员很难安全航行。

3.During the storm, the sea was filled with 湍流运动, making it perilous for sailors.

暴风雨期间，大海充满了湍流运动，使得水手们处于危险之中。

4.Engineers must account for 湍流运动 when designing bridges over rivers.

工程师在设计河流上的桥梁时必须考虑湍流运动。

5.The airplane experienced 湍流运动 during its descent, causing some passengers to feel uneasy.

飞机在降落过程中经历了湍流运动，导致一些乘客感到不安。

作文

Turbulence is a phenomenon that can be observed in various natural and artificial systems. When we think about the term turbulent motion, it often brings to mind chaotic and unpredictable movements. This type of motion is characterized by irregular fluctuations, swirling vortices, and rapid changes in pressure and flow velocity. In fluid dynamics, turbulent motion refers to the complex flow patterns that occur when a fluid moves at high speeds or when it encounters obstacles. Unlike laminar flow, where fluid particles move in smooth, parallel layers, turbulent motion creates a mix of different velocities and directions, leading to an intricate and dynamic flow. The study of turbulent motion is essential in various fields, including meteorology, oceanography, and engineering. For instance, in meteorology, understanding turbulent motion helps scientists predict weather patterns and phenomena like storms and hurricanes. The chaotic nature of air movement during these events can lead to severe weather conditions, making it crucial for meteorologists to analyze and model turbulent motion accurately.In oceanography, turbulent motion plays a significant role in the mixing of ocean waters, which affects marine life and climate. The interactions between wind, waves, and currents can create turbulence in the water, leading to nutrient distribution and temperature variations that are vital for the ecosystem.Engineering also relies heavily on the principles of turbulent motion. For example, in the design of aircraft, engineers must consider how turbulent airflow can impact lift and drag. Understanding the behavior of air around an aircraft during flight is critical for optimizing performance and ensuring safety. Similarly, in civil engineering, the design of bridges and buildings must account for the effects of turbulent winds, especially in hurricane-prone areas.Moreover, turbulent motion is not limited to fluids; it can also be observed in other contexts, such as economics and social sciences. For instance, market fluctuations can be seen as a form of turbulent motion, where prices and trends change rapidly due to various factors, including consumer behavior and global events. Understanding this turbulence can help economists and investors make informed decisions.In conclusion, turbulent motion is a fascinating and complex phenomenon that occurs in many aspects of our world. Whether in the atmosphere, oceans, or even financial markets, the principles of turbulence remind us of the inherent unpredictability of systems. By studying and understanding turbulent motion, we can better navigate and respond to the challenges posed by this chaos. As we continue to explore the intricacies of turbulence, we may uncover new insights that could lead to advancements in science, technology, and our understanding of the universe. In summary, turbulent motion (湍流运动) is not just a scientific concept; it is a reflection of the dynamic and ever-changing nature of our environment, urging us to embrace complexity and uncertainty in our pursuit of knowledge.

湍流是一种现象，可以在各种自然和人工系统中观察到。当我们想到术语turbulent motion（湍流运动）时，它常常让人联想到混乱和不可预测的运动。这种类型的运动的特点是不规则的波动、旋转的涡流以及压力和流速的快速变化。在流体动力学中，turbulent motion（湍流运动）指的是当流体以高速移动或遇到障碍物时发生的复杂流动模式。与层流不同，在层流中，流体颗粒以平滑、平行的层移动，而turbulent motion（湍流运动）则创造出不同速度和方向的混合，导致复杂而动态的流动。对turbulent motion（湍流运动）的研究在气象学、海洋学和工程学等多个领域至关重要。例如，在气象学中，了解turbulent motion（湍流运动）有助于科学家预测天气模式和风暴、飓风等现象。在这些事件中，空气运动的混乱特性可能导致严重的天气条件，因此气象学家必须准确分析和建模turbulent motion（湍流运动）。在海洋学中，turbulent motion（湍流运动）在海洋水体的混合中起着重要作用，这影响着海洋生物和气候。风、波和洋流之间的相互作用可以在水中产生湍流，导致营养物质分布和温度变化，这对生态系统至关重要。工程学也高度依赖于turbulent motion（湍流运动）的原理。例如，在飞机设计中，工程师必须考虑湍流气流如何影响升力和阻力。理解飞行过程中空气在飞机周围的行为对于优化性能和确保安全至关重要。类似地，在土木工程中，桥梁和建筑的设计必须考虑湍流风的影响，尤其是在飓风频发地区。此外，turbulent motion（湍流运动）不仅限于流体；它还可以在其他背景中观察到，例如经济学和社会科学。例如，市场波动可以被视为一种turbulent motion（湍流运动），其中价格和趋势由于各种因素，包括消费者行为和全球事件而迅速变化。理解这种湍流可以帮助经济学家和投资者做出明智的决策。总之，turbulent motion（湍流运动）是一个引人入胜且复杂的现象，发生在我们世界的许多方面。无论是在大气、海洋还是金融市场，湍流的原理提醒我们系统固有的不确定性。通过研究和理解turbulent motion（湍流运动），我们可以更好地应对这一混乱所带来的挑战。随着我们继续探索湍流的复杂性，我们可能会发现新的见解，从而推动科学、技术的发展，以及对宇宙的理解。总之，turbulent motion（湍流运动）不仅仅是一个科学概念；它反映了我们环境的动态和不断变化的本质，敦促我们在追求知识的过程中接受复杂性和不确定性。