anticyclonic eddies

简明释义

反气旋涡旋

英英释义

例句

1.The ocean currents are influenced by the formation of anticyclonic eddies (反气旋涡旋) that trap warm water.

海洋洋流受到形成的反气旋涡旋（anticyclonic eddies）的影响，这些涡旋会捕获温暖的水。

2.The climate model predicts an increase in anticyclonic eddies (反气旋涡旋) due to global warming.

气候模型预测，由于全球变暖，反气旋涡旋（anticyclonic eddies）将会增加。

3.The study focused on how anticyclonic eddies (反气旋涡旋) affect nutrient distribution in the ocean.

该研究集中于反气旋涡旋（anticyclonic eddies）如何影响海洋中的营养分布。

4.Researchers observed that anticyclonic eddies (反气旋涡旋) can enhance marine biodiversity in certain regions.

研究人员观察到，反气旋涡旋（anticyclonic eddies）可以增强某些地区的海洋生物多样性。

5.Satellite images reveal the presence of large anticyclonic eddies (反气旋涡旋) in the Atlantic Ocean.

卫星图像显示大西洋中存在大型的反气旋涡旋（anticyclonic eddies）。

作文

In the study of oceanography and meteorology, the term anticyclonic eddies refers to large-scale circular motions in the atmosphere or ocean that rotate in a clockwise direction in the Northern Hemisphere and counterclockwise in the Southern Hemisphere. These phenomena play a crucial role in regulating weather patterns and ocean currents, influencing climate conditions across various regions. Understanding anticyclonic eddies is essential for predicting weather changes and studying environmental impacts. Anticyclonic eddies are typically associated with high-pressure systems. When air descends in these areas, it creates a stable environment that suppresses cloud formation and precipitation. As a result, regions affected by anticyclonic eddies often experience clear skies and warmer temperatures. This stability can lead to prolonged dry spells, which can have significant implications for agriculture and water resources. For instance, during summer months, the presence of an anticyclonic eddy can lead to heatwaves, affecting crop yields and increasing the demand for irrigation.Moreover, anticyclonic eddies can influence ocean currents. In the ocean, these eddies can trap warm water and create localized areas of higher sea surface temperatures. This phenomenon can affect marine ecosystems, as many species rely on specific temperature ranges for spawning and feeding. The interaction between anticyclonic eddies and ocean currents can also impact global climate patterns, such as El Niño and La Niña events, which are characterized by variations in ocean temperatures and atmospheric conditions.The formation of anticyclonic eddies is often linked to larger atmospheric circulation patterns, such as the jet stream. Changes in the jet stream can lead to the development of these eddies, which can persist for days to weeks. Scientists use satellite imagery and numerical models to track these eddies, providing valuable data for weather forecasting and climate research. Understanding the dynamics of anticyclonic eddies allows meteorologists to improve their predictions regarding weather events, such as storms and droughts.Furthermore, the impact of anticyclonic eddies extends beyond immediate weather effects. Their influence on ocean currents can affect global heat distribution, contributing to long-term climate change. As the climate continues to evolve due to human activities, understanding how anticyclonic eddies respond to these changes becomes increasingly important. Research in this area can help scientists develop more accurate climate models, which are essential for planning and adaptation strategies.In conclusion, anticyclonic eddies are significant features in both atmospheric and oceanic sciences. Their role in shaping weather patterns, influencing marine ecosystems, and affecting global climate highlights the interconnectedness of Earth's systems. Continued research into anticyclonic eddies will enhance our understanding of climate dynamics and aid in the development of effective responses to environmental challenges.

在海洋学和气象学研究中，术语反气旋涡旋指的是大规模的循环运动，这种运动在北半球以顺时针方向旋转，而在南半球则以逆时针方向旋转。这些现象在调节天气模式和海洋洋流方面发挥着至关重要的作用，影响着各个地区的气候条件。理解反气旋涡旋对于预测天气变化和研究环境影响至关重要。反气旋涡旋通常与高压系统相关。当空气在这些区域下降时，会创造一个稳定的环境，抑制云形成和降水。因此，受到反气旋涡旋影响的地区通常会经历晴朗的天空和更高的温度。这种稳定性可能导致长期干旱，这对农业和水资源有重大影响。例如，在夏季，反气旋涡旋的存在可能导致热浪，影响作物产量并增加灌溉需求。此外，反气旋涡旋还可以影响海洋洋流。在海洋中，这些涡旋可以捕获温暖的水，形成局部高海面温度区域。这种现象可能会影响海洋生态系统，因为许多物种依赖特定的温度范围进行繁殖和觅食。反气旋涡旋与海洋洋流之间的相互作用也可能影响全球气候模式，如厄尔尼诺和拉尼娜事件，这些事件的特点是海洋温度和大气条件的变化。反气旋涡旋的形成通常与更大的大气环流模式有关，例如急流。急流的变化可能导致这些涡旋的发展，这些涡旋可以持续数天到数周。科学家使用卫星图像和数值模型来跟踪这些涡旋，为天气预报和气候研究提供宝贵的数据。理解反气旋涡旋的动态使气象学家能够改善他们对天气事件（如风暴和干旱）的预测。此外，反气旋涡旋的影响超出了即时天气效应。它们对海洋洋流的影响可能影响全球热分布，促进长期气候变化。随着气候因人类活动而不断演变，理解反气旋涡旋如何对这些变化做出反应变得越来越重要。该领域的研究可以帮助科学家开发更准确的气候模型，这对于规划和适应策略至关重要。总之，反气旋涡旋是大气和海洋科学中的重要特征。它们在塑造天气模式、影响海洋生态系统和影响全球气候方面的作用突显了地球系统之间的相互联系。对反气旋涡旋的持续研究将增强我们对气候动态的理解，并有助于制定有效应对环境挑战的策略。