refracted

简明释义

英[rɪˈfræktɪd]美[rɪˈfræktɪd]

adj. [物]折射的；屈折的

v. 使折射（refract 的过去分词）

英英释义

单词用法

同义词

反义词

例句

1.Under the glass block, light is refracted on passing through the glass.

在玻璃棒下面，光穿过玻璃后发生折射。

2.The sun obscured by overcast, refracted from the jungle and heated the moist dark air.

云翳蔽空，日色朦胧，经丛林这么一反射，又阴又湿的空气就给烤得热烘烘的。

3.They think that a stick refracted in the water is a crooked stick.

他们认为在水中折射的棍子是弯曲的棍子。

4.The mirror glass carrier light refracted and affects the catoptric imaging light onthe reflection plane.

镜子的玻璃载体对光产生折射作用，它对光在镜子反射面的反射成像产生了影响。

5.How think about questions that produced by the net-worm's practice and refracted by their behaviors?

如何看待网虫这种实践行为所折射出的许多问题?。

6.The historic tragedy of China was refracted through the personalities of her ruling couple.

中国的历史性悲剧，在这对统治中国的夫妇的个性上反映了出来。

7.The light was refracted 折射 when it passed through the glass prism.

当光线通过玻璃棱镜时，它被折射。

8.When you look at a straw in a glass of water, it appears bent due to refracted 折射 light.

当你看着水杯中的吸管时，由于光的折射，它看起来是弯曲的。

9.The rainbow is formed when sunlight is refracted 折射 and reflected in raindrops.

彩虹是在阳光被雨滴折射和反射时形成的。

10.In physics class, we learned how lenses refracted 折射 light to focus images.

在物理课上，我们学习了透镜如何折射光线以聚焦图像。

11.The artist used a glass orb to create refracted 折射 effects in her paintings.

这位艺术家使用一个玻璃球在她的画作中创造了折射效果。

作文

Light is one of the most fascinating phenomena in our world. It travels in straight lines until it encounters a different medium, such as water or glass. When this happens, the light undergoes a process known as refraction, where its path is bent or changed. This bending of light is crucial for many natural and artificial processes. For example, when sunlight passes through raindrops, it gets refracted (折射) and creates a beautiful spectrum of colors that we see in rainbows. Similarly, when light enters a glass prism, it is also refracted (折射), splitting into various colors, which is a practical demonstration of how light behaves. In daily life, we encounter refraction in various scenarios. When you look at a straw placed in a glass of water, it appears to be broken or bent at the surface of the water. This illusion is caused by the light being refracted (折射) as it moves from air into water. The change in speed of light in different mediums results in this visual distortion. Understanding this principle helps us appreciate the beauty of nature and the science behind it. Refraction is not only limited to visible light; it also applies to other types of waves, including sound waves. For instance, when sound travels from air into water, it changes speed and direction, which can affect how we perceive sounds underwater compared to above it. This phenomenon is particularly important in fields like underwater acoustics and marine biology, where understanding sound propagation is essential. The concept of refraction has significant implications in various technologies as well. Lenses used in glasses, cameras, and microscopes rely on the principles of refraction to function effectively. By carefully designing lenses to control how light is refracted (折射), we can magnify images or correct vision. This application of refraction highlights the importance of understanding light behavior in both scientific and practical contexts. Moreover, the study of refraction extends beyond just physical applications. In a metaphorical sense, we can think about how our perceptions of reality can also be refracted (折射) through our experiences and beliefs. Just as light changes direction when it passes through different materials, our perspectives can shift based on new information or insights. This idea encourages us to remain open-minded and adaptable in our thinking, allowing us to see the world from various angles. In conclusion, the phenomenon of light being refracted (折射) is a fundamental concept that bridges science and everyday life. From creating rainbows to enabling the functionality of lenses, refraction plays a vital role in how we understand and interact with our environment. Furthermore, recognizing the metaphorical aspects of refraction can inspire us to embrace change and broaden our perspectives. By appreciating both the scientific and philosophical implications of refraction, we can deepen our understanding of the world around us.

光是我们世界上最迷人的现象之一。它沿直线传播，直到遇到不同的介质，例如水或玻璃。当这种情况发生时，光经历一个称为折射的过程，其路径被弯曲或改变。这种光的弯曲对许多自然和人工过程至关重要。例如，当阳光穿过雨滴时，它被refracted（折射）并创造出美丽的色彩谱，我们在彩虹中看到的就是这个。同样，当光进入玻璃棱镜时，它也被refracted（折射），分裂成各种颜色，这是光行为的实际演示。 在日常生活中，我们在各种场景中遇到折射。当你看着放在水杯中的吸管时，它似乎在水面处断裂或弯曲。这种错觉是由于光在从空气进入水时被refracted（折射）造成的。光在不同介质中的速度变化导致了这种视觉扭曲。理解这一原理帮助我们欣赏自然的美以及其背后的科学。 折射不仅限于可见光；它还适用于其他类型的波，包括声波。例如，当声音从空气传播到水中时，它会改变速度和方向，这可能会影响我们在水下与水上感知声音的方式。这一现象在水下声学和海洋生物学等领域尤为重要，在这些领域中，理解声音传播至关重要。 折射的概念在各种技术中也具有重要意义。眼镜、相机和显微镜中使用的镜头依赖于折射原理来有效工作。通过精心设计镜头以控制光的refracted（折射）方式，我们可以放大图像或矫正视力。这种对折射的应用突显了理解光行为在科学和实际背景中的重要性。 此外，折射的研究超越了物理应用。在隐喻的意义上，我们可以思考我们对现实的感知如何通过我们的经历和信念被refracted（折射）。就像光在通过不同材料时改变方向一样，我们的观点可以根据新信息或见解而转变。这个想法鼓励我们在思维上保持开放和适应，使我们能够从不同的角度看待世界。 总之，光被refracted（折射）的现象是一个基本概念，连接了科学和日常生活。从创造彩虹到使镜头功能正常，折射在我们理解和与环境互动的方式中发挥着至关重要的作用。此外，认识到折射的隐喻方面可以激励我们接受变化并拓宽我们的视角。通过欣赏折射的科学和哲学意义，我们可以加深对周围世界的理解。