entrainment phenomena

简明释义

卷吸现象

英英释义

例句

1.In engineering, entrainment phenomena must be accounted for when designing efficient mixing systems.

在工程中，设计高效混合系统时必须考虑到夹带现象。

2.The study of entrainment phenomena in fluid dynamics helps us understand how particles are carried by a flowing fluid.

流体动力学中对夹带现象的研究帮助我们理解颗粒是如何被流动的流体携带的。

3.The entrainment phenomena in ocean currents can significantly affect marine life and ecosystems.

海洋洋流中的夹带现象会显著影响海洋生物和生态系统。

4.Researchers observed entrainment phenomena during the mixing of two different gases in a controlled environment.

研究人员在受控环境中观察到两种不同气体混合时的夹带现象。

5.Understanding entrainment phenomena is crucial for predicting weather patterns and atmospheric behavior.

理解夹带现象对于预测天气模式和大气行为至关重要。

作文

The concept of entrainment phenomena is a fascinating area of study that spans multiple disciplines, including physics, biology, and environmental science. Essentially, entrainment phenomena refer to the process by which one medium influences or incorporates another, often resulting in significant changes in both entities. This phenomenon can be observed in various contexts, such as fluid dynamics, where particles are carried along by a flowing fluid, or in ecological systems, where different species interact and affect each other's populations.In fluid dynamics, entrainment phenomena play a crucial role in understanding how pollutants disperse in rivers and oceans. For example, when a river flows rapidly, it can pick up sediment and other materials from its banks and bed. This process not only alters the river's physical characteristics but also impacts the aquatic ecosystem. The entrainment of sediments can provide nutrients for aquatic life, while at the same time, excessive pollution can lead to detrimental effects on fish populations and overall water quality.Similarly, in the field of atmospheric science, entrainment phenomena are vital for understanding cloud formation and weather patterns. When warm air rises, it can draw in cooler air from its surroundings, leading to the mixing of different air masses. This mixing is essential for the development of clouds and precipitation. The study of these interactions helps meteorologists predict weather changes and understand climate dynamics.On a biological level, entrainment phenomena can be observed in the synchronization of circadian rhythms among living organisms. Many species, including humans, have internal biological clocks that regulate their sleep-wake cycles. However, these rhythms can be influenced by external factors such as light exposure and social interactions. For instance, when a group of people spends time together, their individual circadian rhythms may become synchronized, demonstrating a form of biological entrainment.The implications of entrainment phenomena extend beyond scientific curiosity; they also have practical applications in various fields. In environmental management, understanding how pollutants are entrained in water bodies can inform strategies for pollution control and habitat restoration. In agriculture, knowledge of how different species interact can guide sustainable farming practices that promote biodiversity and ecosystem health.Moreover, the study of entrainment phenomena is crucial for addressing global challenges such as climate change. As ecosystems are interconnected, changes in one part of the world can have ripple effects on others. By analyzing these phenomena, scientists can better predict how environmental changes will impact biodiversity and ecosystem services.In conclusion, entrainment phenomena are integral to our understanding of the natural world. They illustrate the interconnectedness of various systems and highlight the importance of considering multiple factors when studying complex interactions. Whether in the context of fluid dynamics, atmospheric science, or biological rhythms, the influence of entrainment phenomena is profound and far-reaching. As we continue to explore these phenomena, we gain valuable insights that can help us navigate the challenges of our rapidly changing environment.

“引入现象”这个概念是一个迷人的研究领域，涵盖多个学科，包括物理学、生物学和环境科学。基本上，“引入现象”指的是一种介质影响或吸收另一种介质的过程，通常导致两个实体都发生显著变化。这种现象可以在各种背景下观察到，例如流体动力学，其中颗粒被流动的流体携带，或者在生态系统中，不同物种之间相互作用并影响彼此的种群。在流体动力学中，“引入现象”在理解污染物如何在河流和海洋中扩散方面起着至关重要的作用。例如，当一条河流快速流动时，它可以从岸边和河床上拾取沉积物和其他材料。这个过程不仅改变了河流的物理特性，还影响了水生生态系统。沉积物的引入可以为水生生物提供养分，而过量的污染则可能对鱼类种群和整体水质产生不利影响。同样，在大气科学领域，“引入现象”对于理解云的形成和天气模式至关重要。当暖空气上升时，它可以从周围环境中吸入较冷的空气，导致不同气团的混合。这种混合对于云和降水的发展是必不可少的。这些相互作用的研究帮助气象学家预测天气变化并理解气候动态。在生物层面，“引入现象”可以在生物体之间的昼夜节律同步中观察到。许多物种，包括人类，都有调节其睡眠-觉醒周期的内部生物钟。然而，这些节律可以受到光照和社会互动等外部因素的影响。例如，当一群人一起度过时间时，他们的个体昼夜节律可能会变得同步，展示了一种生物引入的形式。“引入现象”的影响超越了科学好奇心；它们在各个领域也有实际应用。在环境管理中，理解污染物如何在水体中被引入可以为污染控制和栖息地恢复策略提供信息。在农业中，了解不同物种如何相互作用可以指导可持续的农业实践，以促进生物多样性和生态系统健康。此外，“引入现象”的研究对于应对全球挑战（如气候变化）至关重要。由于生态系统是相互关联的，世界某一部分的变化可能对其他部分产生连锁反应。通过分析这些现象，科学家可以更好地预测环境变化将如何影响生物多样性和生态系统服务。总之，“引入现象”是我们理解自然世界的核心。它们说明了各种系统之间的相互联系，并强调了在研究复杂相互作用时考虑多个因素的重要性。无论是在流体动力学、大气科学还是生物节律的背景下，“引入现象”的影响都是深远而广泛的。随着我们继续探索这些现象，我们获得了宝贵的见解，这些见解可以帮助我们应对快速变化的环境所带来的挑战。