refrangibility

简明释义

英[rɪˌfrændʒɪˈbɪlɪti]美[rɪˌfrændʒəˈbɪləti]

n. 折射性；折射度

英英释义

单词用法

同义词

反义词

例句

1.This article begins with introducing the conception of refrangibility, and then the relation between refractive index and density of the gas is established.

本文从介绍折射度的概念和性质出发，建立了气体密度与折射率之间的关系。

2.This article begins with introducing the conception of refrangibility, and then the relation between refractive index and density of the gas is established.

本文从介绍折射度的概念和性质出发，建立了气体密度与折射率之间的关系。

3.The transparent adhesive must be homogeneous and low in absorption of light, and its refrangibility must be same as that of the material to be bonded.

作为光透性胶粘剂，必须均匀，对光具有低的吸收，和被粘接材料的折射率相当。

4.The study of light involves understanding the concept of refrangibility, which refers to the ability of light to change direction when it passes through different mediums.

光的研究涉及理解折射能力的概念，即光在通过不同介质时改变方向的能力。

5.In optics, the refrangibility of a material determines how much it can bend light, affecting the design of lenses.

在光学中，材料的折射能力决定了它可以弯曲光线的程度，这影响了透镜的设计。

6.The refrangibility of certain wavelengths of light is crucial in developing fiber optic technology.

某些波长光的折射能力在光纤技术的发展中至关重要。

7.Scientists measure the refrangibility of various substances to understand their optical properties.

科学家测量各种物质的折射能力以了解它们的光学特性。

8.The refrangibility of water compared to air explains why objects appear distorted when viewed underwater.

水与空气的折射能力解释了为什么在水下观察物体时它们看起来扭曲。

作文

In the realm of physics, the concept of refrangibility holds significant importance, particularly in the study of light and its behavior as it travels through different mediums. Refrangibility refers to the ability of a substance or medium to refract light, which means to bend or alter the path of light waves as they pass from one material to another. This phenomenon is crucial in understanding various optical devices such as lenses, prisms, and even the natural occurrences of rainbows. The study of refrangibility not only enhances our comprehension of light but also has practical applications in technology and science. To illustrate the importance of refrangibility, consider how lenses are designed. Lenses are crafted from materials with specific refrangibility properties to achieve desired optical effects. For instance, a convex lens is designed to converge light rays, while a concave lens diverges them. The refrangibility of the material determines how effectively it can manipulate light, making it essential for creating glasses that correct vision, cameras that capture images, and microscopes that allow us to see tiny details. Moreover, the phenomenon of refrangibility is not limited to artificial constructs; it is also observed in nature. When light passes through raindrops, it is refracted, and this bending of light creates the beautiful spectrum of colors we see in a rainbow. Each color corresponds to a different wavelength of light, and the degree of refrangibility varies for each wavelength, leading to the separation of colors. This natural display serves as a reminder of the intricate relationships between light, water, and the atmosphere. Understanding refrangibility also has implications in the field of telecommunications. Fiber optic technology relies on the principles of light refraction to transmit data over long distances. The core of a fiber optic cable is designed to have a higher refrangibility than the surrounding cladding, allowing light to be guided through the core by total internal reflection. This technology has revolutionized communication, enabling high-speed internet and clearer phone calls. In addition to its practical applications, the study of refrangibility encourages scientific inquiry and innovation. Researchers continue to explore new materials with unique refrangibility characteristics that could lead to advancements in optics and photonics. For example, metamaterials—engineered materials with properties not found in nature—are being investigated for their potential to manipulate light in unprecedented ways. Such innovations may pave the way for new technologies, including invisibility cloaks and superlenses that surpass the limits of conventional optics. In conclusion, refrangibility is a fundamental concept in the study of light and optics, influencing both natural phenomena and technological advancements. Its applications range from everyday items like glasses to cutting-edge innovations in communications and materials science. By deepening our understanding of refrangibility, we not only enhance our knowledge of the physical world but also unlock new possibilities for the future. As we continue to explore the intricacies of light and its interactions with different mediums, the significance of refrangibility will undoubtedly remain at the forefront of scientific discovery and technological progress.

在物理学领域，refrangibility（折射性）这一概念具有重要意义，尤其是在研究光及其在不同介质中传播的行为时。Refrangibility指的是一种物质或介质折射光的能力，这意味着当光波从一种材料传递到另一种材料时，会弯曲或改变其路径。这一现象对于理解各种光学设备，如透镜、棱镜，甚至自然现象如彩虹至关重要。对refrangibility的研究不仅增强了我们对光的理解，还有助于科技和科学的实际应用。 为了说明refrangibility的重要性，可以考虑透镜的设计。透镜是由具有特定refrangibility特性的材料制成，以实现所需的光学效果。例如，凸透镜旨在聚焦光线，而凹透镜则使光线发散。材料的refrangibility决定了它能多有效地操控光线，因此对于制造矫正视力的眼镜、捕捉图像的相机和允许我们观察微小细节的显微镜至关重要。 此外，refrangibility现象并不仅限于人工构造；它也在自然界中得到观察。当光通过雨滴时，它会被折射，这种光的弯曲创造了我们在彩虹中看到的美丽色谱。每种颜色对应于不同的光波长，而每种波长的refrangibility程度各不相同，从而导致颜色的分离。这一自然展示提醒我们光、水和大气之间的复杂关系。 理解refrangibility在电信领域也有重要意义。光纤技术依赖于光的折射原理来远距离传输数据。光纤电缆的核心设计为具有比周围包层更高的refrangibility，使光能够通过全内反射在核心中导引。这项技术彻底改变了通信，使高速互联网和更清晰的电话通话成为可能。 除了实际应用，refrangibility的研究还激励着科学探索和创新。研究人员继续探索具有独特refrangibility特性的材料，这可能导致光学和光子学的进步。例如，超材料——具有自然界中不存在的特性的工程材料——正在被研究以其潜力操控光的前所未有的方式。这些创新可能为新技术铺平道路，包括隐形斗篷和超透镜，超越传统光学的极限。 总之，refrangibility是光和光学研究中的一个基本概念，影响着自然现象和技术进步。其应用范围从日常物品如眼镜到通信和材料科学的尖端创新。通过加深对refrangibility的理解，我们不仅增强了对物理世界的知识，还开启了未来的新可能性。随着我们继续探索光的复杂性及其与不同介质的相互作用，refrangibility的重要性无疑将始终处于科学发现和技术进步的前沿。