upper-atmosphere phenomena

简明释义

高层大气现象

英英释义

例句

1.Meteorologists rely on satellite data to observe upper-atmosphere phenomena 高层大气现象 like jet streams.

气象学家依赖卫星数据观察如急流等高层大气现象。

2.Research on upper-atmosphere phenomena 高层大气现象 helps in predicting space weather events.

对高层大气现象的研究有助于预测空间天气事件。

3.Understanding upper-atmosphere phenomena 高层大气现象 is crucial for improving weather forecasting models.

理解高层大气现象对于改善天气预报模型至关重要。

4.The auroras are stunning examples of upper-atmosphere phenomena 高层大气现象 that occur near the poles.

极光是发生在极地区域的令人惊叹的高层大气现象的例子。

5.Scientists study upper-atmosphere phenomena 高层大气现象 to understand climate change better.

科学家研究高层大气现象以更好地理解气候变化。

作文

The Earth’s atmosphere is a complex and dynamic system that plays a crucial role in supporting life on our planet. Among the various layers of the atmosphere, the upper atmosphere is particularly fascinating due to its unique characteristics and phenomena. upper-atmosphere phenomena (上层大气现象) encompass a wide range of events and processes that occur at high altitudes, often beyond the reach of everyday human experience. These phenomena include auroras, jet streams, and even cosmic rays, each contributing to our understanding of atmospheric science and climate. One of the most visually stunning upper-atmosphere phenomena (上层大气现象) is the aurora borealis, or northern lights, which occur when charged particles from the sun collide with the Earth's magnetic field. This interaction excites the gases in the atmosphere, causing them to emit light in brilliant colors. The result is a breathtaking display of greens, pinks, and purples dancing across the night sky. Similarly, the aurora australis, or southern lights, provides a mirror image of this phenomenon in the Southern Hemisphere. Both types of auroras are not only beautiful but also serve as indicators of solar activity, offering insights into the dynamics of space weather. Another significant aspect of the upper-atmosphere phenomena (上层大气现象) is the jet stream, a fast-flowing ribbon of air located high in the atmosphere. These powerful winds can influence weather patterns, affecting everything from storm development to temperature fluctuations. Meteorologists closely monitor jet streams to predict weather changes and understand how they interact with other atmospheric systems. As climate change continues to alter the behavior of the atmosphere, studying jet streams becomes increasingly important for forecasting and mitigating the impacts of extreme weather events. In addition to these well-known occurrences, the upper atmosphere is also home to less visible but equally intriguing phenomena such as cosmic rays. These high-energy particles originate from outside our solar system and can have significant effects on both technology and biology. For instance, cosmic rays can interfere with satellite operations and pose risks to astronauts in space. Understanding these particles and their interactions with the Earth's atmosphere is crucial for advancing our knowledge of both atmospheric science and space exploration. The study of upper-atmosphere phenomena (上层大气现象) is not only essential for scientific inquiry but also has practical implications for society. As we face challenges related to climate change, weather extremes, and environmental degradation, a deeper understanding of these atmospheric processes can inform policy decisions and technological innovations. For example, advancements in remote sensing and satellite technology allow scientists to monitor and analyze upper-atmosphere phenomena in real time, leading to improved predictions and responses to natural disasters. In conclusion, upper-atmosphere phenomena (上层大气现象) represent a vital area of study within atmospheric science. From the mesmerizing displays of auroras to the powerful jet streams and the enigmatic cosmic rays, these phenomena shape our planet's climate and environment. As we continue to explore the complexities of the upper atmosphere, we enhance our ability to navigate the challenges posed by a changing world. The more we learn about these phenomena, the better equipped we will be to protect our planet and ensure a sustainable future for generations to come.

地球的气氛是一个复杂而动态的系统，在支持我们星球上的生命方面发挥着至关重要的作用。在大气的各个层次中，上层大气因其独特的特征和现象而特别引人注目。upper-atmosphere phenomena（上层大气现象）包括一系列发生在高海拔地区的事件和过程，这些现象通常超出了日常人类经验的范围。这些现象包括极光、喷射流，甚至宇宙射线，每一种现象都为我们理解大气科学和气候提供了贡献。其中最令人惊叹的upper-atmosphere phenomena（上层大气现象）之一是极光或北极光，它发生在来自太阳的带电粒子与地球磁场碰撞时。这种相互作用激发了大气中的气体，使其发出绚丽的光芒。结果是在夜空中舞动的绿色、粉色和紫色的壮观表演。同样，南极光则在南半球提供了这种现象的镜像。两种极光不仅美丽，而且也是太阳活动的指示器，为我们提供了关于空间天气动态的见解。upper-atmosphere phenomena（上层大气现象）的另一个重要方面是喷射流，它是一种位于大气高层的快速流动空气带。这些强大的风可以影响天气模式，影响从风暴发展到温度波动的一切。气象学家密切监测喷射流，以预测天气变化并了解它们如何与其他大气系统相互作用。随着气候变化继续改变大气的行为，研究喷射流对于预测和减轻极端天气事件的影响变得愈加重要。除了这些著名的现象，上层大气还是一些不那么明显但同样引人入胜的现象的家园，比如宇宙射线。这些高能粒子源自我们太阳系之外，并可能对技术和生物产生重大影响。例如，宇宙射线可以干扰卫星操作，并对太空中的宇航员构成风险。理解这些粒子及其与地球大气的相互作用对于推进我们对大气科学和太空探索的知识至关重要。对upper-atmosphere phenomena（上层大气现象）的研究不仅对科学探索至关重要，而且对社会也有实际意义。随着我们面临与气候变化、极端天气和环境退化相关的挑战，更深入地理解这些大气过程可以为政策决策和技术创新提供信息。例如，遥感和卫星技术的进步使科学家能够实时监测和分析上层大气现象，从而改善自然灾害的预测和响应。总之，upper-atmosphere phenomena（上层大气现象）代表了大气科学研究中的一个重要领域。从迷人的极光展示到强大的喷射流以及神秘的宇宙射线，这些现象塑造着我们星球的气候和环境。随着我们继续探索上层大气的复杂性，我们增强了应对气候变化的挑战的能力。我们对这些现象了解得越多，就越能保护我们的星球，并确保为后代创造可持续的未来。