atmospheric tsunami

简明释义

暴风海啸

英英释义

例句

1.After the earthquake, scientists monitored the sky for signs of an atmospheric tsunami 大气海啸 that could lead to severe weather changes.

地震后，科学家监测天空以寻找可能导致严重天气变化的大气海啸的迹象。

2.An atmospheric tsunami 大气海啸 can cause sudden shifts in temperature, impacting local ecosystems.

一场大气海啸可能导致温度的突然变化，从而影响当地生态系统。

3.The researchers discovered that the recent storm created an atmospheric tsunami 大气海啸 that affected weather patterns across the region.

研究人员发现，最近的风暴产生了一场大气海啸，大气海啸影响了该地区的天气模式。

4.During the conference, a scientist explained how an atmospheric tsunami 大气海啸 can travel thousands of miles from its origin.

在会议上，一位科学家解释了如何一场大气海啸可以从其起源地传播数千英里。

5.The phenomenon of an atmospheric tsunami 大气海啸 is still not fully understood by meteorologists.

气象学家对大气海啸这一现象仍未完全理解。

作文

The term atmospheric tsunami refers to a phenomenon that occurs when an abrupt change in atmospheric pressure creates a large wave of air that travels across the atmosphere. This concept might sound unusual at first, but it is essential to understand how such events can impact our weather systems and the environment. In essence, an atmospheric tsunami is similar to a water tsunami, but instead of water, it involves air and pressure changes. These waves can be triggered by various factors, including volcanic eruptions, meteorite impacts, or even large-scale weather events like hurricanes.To comprehend the significance of atmospheric tsunami, we must first look at how atmospheric pressure works. The Earth's atmosphere is composed of layers of air that have varying densities and temperatures. When a sudden shift occurs, such as a rapid rise or fall in temperature or pressure, it can create a disturbance that propagates through the air. Much like ripples in a pond, these disturbances can travel long distances, affecting the weather patterns along their path.One of the most notable examples of an atmospheric tsunami occurred during the eruption of Krakatoa in 1883. The eruption produced massive shockwaves that traveled through the atmosphere, leading to significant atmospheric pressure changes around the globe. This event resulted in dramatic shifts in weather patterns, with reports of unusual weather phenomena occurring as far away as Europe and North America. The aftermath of the eruption serves as a reminder of how interconnected our planet's systems are and how an event in one part of the world can have far-reaching consequences.Moreover, scientists study atmospheric tsunamis to better predict weather-related disasters. Understanding how these waves behave can help meteorologists forecast severe weather conditions, such as storms or high winds, which can lead to damage and loss of life. For instance, if a large storm system is approaching, recognizing the potential for an atmospheric tsunami can allow for timely warnings and preparations, ultimately saving lives and property.In addition to their role in weather prediction, atmospheric tsunamis also offer insights into climate change. As global temperatures rise, the dynamics of our atmosphere are changing, leading to more frequent and intense weather events. By studying how atmospheric tsunamis form and evolve, researchers can gain a deeper understanding of the implications of climate change on our planet's atmospheric systems.In conclusion, the phenomenon of atmospheric tsunami is a fascinating area of study that highlights the complexity of our atmosphere and its influence on weather patterns. By examining the causes and effects of these atmospheric waves, we can improve our ability to predict severe weather and understand the broader implications of climate change. As we continue to explore this field, it is crucial to recognize the interconnectedness of our planet's systems and the importance of being prepared for the unexpected.

“大气海啸”这一术语指的是当大气压力发生突变时，形成的一种空气波动现象，这种波动会在大气中传播。乍一听，这个概念可能显得不寻常，但理解此类事件如何影响我们的天气系统和环境是至关重要的。从本质上讲，大气海啸类似于水海啸，但其涉及的是空气和压力变化。这些波动可能由多种因素引发，包括火山喷发、陨石撞击，甚至大规模的天气事件，如飓风。为了理解大气海啸的重要性，我们首先需要了解大气压力的工作原理。地球的大气由不同密度和温度的空气层组成。当发生突发变化时，例如温度或压力的快速升高或降低，就会产生一种干扰，这种干扰会在空气中传播。就像池塘中的涟漪一样，这些干扰可以传播很长距离，影响沿途的天气模式。一个最著名的大气海啸的例子发生在1883年喀拉喀托火山的喷发。此次喷发产生了巨大的冲击波，这些波在大气中传播，导致全球范围内的大气压力变化。这一事件导致了剧烈的天气模式变化，报告显示，远至欧洲和北美的地方都出现了异常天气现象。喷发后的余波提醒我们，地球系统是多么相互关联，一个地方的事件可能会带来深远的后果。此外，科学家们研究大气海啸以更好地预测与天气相关的灾害。理解这些波动的行为可以帮助气象学家预测严重天气条件，如风暴或强风，这些条件可能导致损失和生命的丧失。例如，如果一个大型风暴系统正在逼近，认识到潜在的大气海啸可能使得及时发出警报和准备成为可能，从而最终拯救生命和财产。除了在天气预测中的作用外，大气海啸还为气候变化提供了见解。随着全球温度的上升，我们的大气动态正在发生变化，导致更频繁和更强烈的天气事件。通过研究大气海啸的形成和演变，研究人员可以更深入地理解气候变化对我们星球大气系统的影响。总之，大气海啸现象是一个令人着迷的研究领域，突显了我们大气的复杂性及其对天气模式的影响。通过考察这些大气波动的原因和影响，我们可以提高预测恶劣天气的能力，并理解气候变化的更广泛影响。随着我们继续探索这一领域，认识到我们星球系统的相互关联性以及为不可预见的情况做好准备的重要性是至关重要的。