refractile

简明释义

英[rɪˈfræktaɪl]美[rɪˈfræktaɪl]

adj. 折射的；有折射力的；能折射的

英英释义

单词用法

同义词

反义词

例句

1.When a rod is about to sporulate a tiny refractile granule appears in the cell.

当一个杆菌即将形成芽孢时，细胞内便出现一粒带折射性的微小颗粒。

2.Elastic fibers usually occur as individual, refractile, branching, and anastomosing fibers.

弹性纤维通常是单独的，折光的，分枝的及吻合的纤维。

3.Elastic fibers usually occur as individual, refractile, branching, and anastomosing fibers.

弹性纤维通常是单独的，折光的，分枝的及吻合的纤维。

4.The refractile nature of diamonds makes them sparkle beautifully when cut properly.

钻石的折射性特性使其在切割得当时闪耀美丽的光芒。

5.The scientist noted that the sample was highly refractile, indicating its ability to bend light significantly.

科学家注意到样本具有很高的折射性，这表明它能够显著弯曲光线。

6.Certain minerals are refractile, which is why they are often used in jewelry.

某些矿物具有折射性，这就是它们常用于珠宝的原因。

7.The refractile properties of the lens help to focus the light onto the sensor.

透镜的折射性特性有助于将光聚焦到传感器上。

8.In optical microscopy, refractile materials can provide clearer images due to their interaction with light.

在光学显微镜中，折射性材料由于与光的相互作用可以提供更清晰的图像。

作文

In the realm of science and optics, the term refractile refers to the ability of a material to bend light as it passes through it. This property is crucial in various applications, from the design of lenses in eyeglasses to the intricate workings of cameras and microscopes. Understanding how refractile materials interact with light can significantly enhance our perception of the world around us. For instance, when light travels from air into water, it slows down and bends at the interface. This phenomenon not only explains why objects appear distorted when viewed underwater but also highlights the fascinating ways in which light behaves in different mediums.The study of refractile materials extends beyond mere curiosity; it has practical implications in fields such as photography, where the quality of images can be dramatically improved by selecting the right lenses. Photographers often seek lenses made from high-quality glass that possesses excellent refractile properties, ensuring that their images are sharp and vibrant. Similarly, in the medical field, refractile properties are utilized in devices like endoscopes, which allow doctors to visualize the interior of the body without invasive surgery.Moreover, the concept of refractile materials can be observed in nature. For example, diamonds are known for their exceptional refractile qualities, which contribute to their brilliance and sparkle. When light enters a diamond, it is bent multiple times before exiting, creating a dazzling display of colors. This natural property is what makes diamonds so coveted in jewelry, symbolizing luxury and elegance.In addition to natural occurrences, scientists are continually experimenting with synthetic refractile materials to create innovative technologies. One such advancement is the development of fiber optics, which relies on the principle of total internal reflection—a result of refractile properties. Fiber optic cables are capable of transmitting data at incredible speeds over long distances, revolutionizing communication and internet technology.As we delve deeper into the study of refractile materials, it becomes evident that they play an integral role in both our daily lives and advanced technological applications. From enhancing our vision to facilitating rapid data transmission, the implications of refractile materials are vast and profound. Thus, the exploration of these materials not only enriches our understanding of physics but also propels innovation across various sectors.In conclusion, the term refractile encapsulates a fundamental aspect of how light interacts with different materials. Its significance stretches across numerous fields, underscoring the importance of understanding this phenomenon. Whether in the context of natural wonders like diamonds or groundbreaking technologies like fiber optics, refractile materials continue to shape our world in remarkable ways. The ongoing study of these materials promises to unveil even more exciting possibilities, making it a captivating area of exploration for scientists and enthusiasts alike.

在科学和光学领域，术语refractile指的是材料在光线通过时弯曲光线的能力。这一特性在各种应用中至关重要，从眼镜镜头的设计到相机和显微镜的复杂工作原理。理解refractile材料与光的相互作用，可以显著增强我们对周围世界的感知。例如，当光从空气进入水中时，它会减速并在界面处弯曲。这一现象不仅解释了为什么物体在水下看起来扭曲，还突显了光在不同介质中行为的迷人方式。对refractile材料的研究超越了单纯的好奇心，它在摄影等领域具有实际意义，选择合适的镜头可以显著提高图像质量。摄影师通常寻找由高质量玻璃制成的镜头，这些镜头具有出色的refractile特性，确保他们的图像清晰而生动。同样，在医疗领域，refractile特性被用于内窥镜等设备，使医生能够在不进行侵入性手术的情况下可视化身体内部。此外，refractile材料的概念可以在自然界中观察到。例如，钻石以其卓越的refractile特性而闻名，这使其闪耀和璀璨。当光线进入钻石时，它在多次折射后才会射出，创造出令人眼花缭乱的色彩展示。这一自然特性使得钻石在珠宝中备受追捧，象征着奢华和优雅。除了自然现象，科学家们还在不断实验合成的refractile材料，以创造创新技术。其中一种进展是光纤的发展，依赖于全内反射原理——这是refractile特性的结果。光纤电缆能够以惊人的速度在长距离内传输数据，彻底改变了通信和互联网技术。随着我们深入研究refractile材料，显然它们在我们的日常生活和先进技术应用中发挥着不可或缺的作用。从增强我们的视力到促进快速数据传输，refractile材料的影响广泛而深远。因此，对这些材料的探索不仅丰富了我们对物理学的理解，也推动了各个领域的创新。总之，术语refractile概括了光与不同材料相互作用的基本方面。其重要性遍及众多领域，强调了理解这一现象的重要性。无论是在自然奇观如钻石的背景下，还是在光纤等突破性技术中，refractile材料继续以惊人的方式塑造我们的世界。对这些材料的持续研究承诺将揭示更多令人兴奋的可能性，使其成为科学家和爱好者都感兴趣的迷人探索领域。