optical transparency

简明释义

光透萌

英英释义

例句

1.The optical transparency of the atmosphere affects how we perceive distant objects.

大气的光学透明度影响我们对远处物体的感知。

2.The new glass material exhibits high optical transparency, allowing more light to pass through.

这种新型玻璃材料表现出高光学透明度，允许更多的光线通过。

3.The artist chose a medium with excellent optical transparency to enhance the colors of her painting.

这位艺术家选择了一种具有优良光学透明度的媒介，以增强她画作的颜色。

4.Researchers are studying materials with improved optical transparency for use in contact lenses.

研究人员正在研究用于隐形眼镜的改进光学透明度材料。

5.In solar panels, optical transparency is crucial for maximizing energy absorption.

在太阳能电池板中，光学透明度对最大化能量吸收至关重要。

作文

Optical transparency is a fundamental concept in the field of optics and materials science. It refers to the property of a material that allows light to pass through it without being absorbed or scattered. This characteristic is crucial for various applications, including lenses, windows, and optical fibers. Understanding optical transparency (光学透明度) helps us comprehend how different materials interact with light and how we can manipulate these interactions for technological advancements.In everyday life, we encounter numerous examples of optical transparency (光学透明度). For instance, glass windows are designed to be highly transparent so that they allow natural light to enter buildings while providing a clear view of the outside world. The optical transparency (光学透明度) of glass is achieved by its atomic structure, which does not absorb visible light wavelengths. Instead, it permits light to pass through, making it an ideal material for construction and design.Another significant application of optical transparency (光学透明度) is in the field of telecommunications. Optical fibers, which are used for high-speed internet connections, rely on the optical transparency (光学透明度) of certain materials, such as silica. These fibers transmit light signals over long distances with minimal loss, thanks to their ability to maintain high levels of optical transparency (光学透明度). This technology has revolutionized communication, enabling faster data transfer rates and more reliable connections.The study of optical transparency (光学透明度) also extends to innovative materials, such as metamaterials. These engineered substances can manipulate electromagnetic waves in ways that natural materials cannot. Researchers are exploring how to create materials with tailored optical transparency (光学透明度) properties, which could lead to advancements in cloaking devices, superlenses, and other cutting-edge technologies.Moreover, the concept of optical transparency (光学透明度) is essential in the medical field. Techniques like endoscopy rely on the optical transparency (光学透明度) of certain tissues to allow doctors to visualize internal organs without invasive procedures. By utilizing light and understanding how it interacts with biological tissues, medical professionals can diagnose and treat conditions more effectively.In conclusion, optical transparency (光学透明度) is a vital aspect of both natural and synthetic materials. Its implications span various fields, from architecture to telecommunications and medicine. As we continue to explore and understand the principles behind optical transparency (光学透明度), we open the door to new technologies and innovations that can significantly impact our daily lives. The importance of this property cannot be overstated, as it underlies many of the advancements we see in modern science and engineering.

光学透明度是光学和材料科学领域的一个基本概念。它指的是一种材料的特性，使光能够通过而不被吸收或散射。这一特性对于各种应用至关重要，包括透镜、窗户和光纤。理解光学透明度有助于我们理解不同材料如何与光相互作用，以及我们如何操控这些相互作用以推动技术进步。在日常生活中，我们会遇到许多光学透明度的例子。例如，玻璃窗户被设计得高度透明，以便让自然光进入建筑物，同时提供清晰的外部视野。玻璃的光学透明度是通过其原子结构实现的，该结构不会吸收可见光波长。相反，它允许光通过，使其成为建筑和设计的理想材料。光学透明度的另一个重要应用是在电信领域。用于高速互联网连接的光纤依赖于某些材料（如二氧化硅）的光学透明度。这些光纤能够在长距离内传输光信号，损失最小，这要归功于它们能够保持高水平的光学透明度。这项技术革新了通信，使数据传输速率更快，连接更可靠。光学透明度的研究还扩展到创新材料，如超材料。这些工程材料可以以自然材料无法做到的方式操控电磁波。研究人员正在探索如何创造具有定制光学透明度特性的材料，这可能导致隐形设备、超透镜和其他尖端技术的进步。此外，光学透明度的概念在医学领域也至关重要。内窥镜等技术依赖于某些组织的光学透明度，以使医生能够在不进行侵入性手术的情况下可视化内部器官。通过利用光并理解其如何与生物组织相互作用，医疗专业人员可以更有效地诊断和治疗疾病。总之，光学透明度是自然和合成材料的重要方面。它的影响跨越多个领域，从建筑到电信再到医学。随着我们不断探索和理解光学透明度背后的原理，我们为新的技术和创新打开了大门，这些创新可以显著影响我们的日常生活。这一特性的意义不容小觑，因为它是现代科学和工程中许多进步的基础。