ultraviolet transparency

简明释义

紫外透迷

英英释义

例句

1.Manufacturers are developing coatings that enhance ultraviolet transparency 紫外线透过率 without compromising other properties.

制造商正在开发涂层，以增强ultraviolet transparency 紫外线透过率而不影响其他性能。

2.Research indicates that the ultraviolet transparency 紫外线透过率 of glass can affect indoor plant growth.

研究表明，玻璃的ultraviolet transparency 紫外线透过率会影响室内植物的生长。

3.The new window films provide excellent ultraviolet transparency 紫外线透过率, allowing natural light while blocking harmful rays.

新的窗膜提供了出色的ultraviolet transparency 紫外线透过率，允许自然光透入，同时阻挡有害射线。

4.Certain plastics have high ultraviolet transparency 紫外线透过率, making them suitable for lenses in sunglasses.

某些塑料具有高ultraviolet transparency 紫外线透过率，使其适合用于太阳镜的镜片。

5.When selecting materials for outdoor applications, consider their ultraviolet transparency 紫外线透过率 to ensure durability.

在选择户外应用材料时，考虑它们的ultraviolet transparency 紫外线透过率以确保耐用性。

作文

In recent years, the study of materials that exhibit ultraviolet transparency has gained significant attention in various scientific fields. Ultraviolet transparency refers to the ability of a material to allow ultraviolet (UV) light to pass through it without significant absorption or scattering. This property is crucial in applications such as optics, photonics, and even in the development of advanced materials for solar energy conversion. Understanding the mechanisms behind ultraviolet transparency can lead to innovations in technology and improvements in environmental sustainability.One of the primary areas where ultraviolet transparency is essential is in the manufacturing of optical components. Lenses and filters that are designed to transmit UV light are used in various applications, including photography, microscopy, and medical diagnostics. For instance, UV sterilization devices rely on materials that exhibit high ultraviolet transparency to effectively eliminate bacteria and viruses without harming the surrounding environment. The effectiveness of these devices is directly linked to the ultraviolet transparency of the materials used in their construction.Moreover, the field of solar energy has also benefited from advancements in ultraviolet transparency. Solar panels that can harness a broader spectrum of sunlight, including UV light, have the potential to increase energy conversion efficiency. Researchers are exploring new materials that not only maintain ultraviolet transparency but also enhance the overall performance of solar cells. By integrating such materials, we can develop more efficient solar panels that contribute to a greener planet.Additionally, the importance of ultraviolet transparency extends to the realm of environmental science. Many natural processes, such as photosynthesis, are influenced by UV radiation. Understanding how certain materials interact with UV light can aid in the development of better protective measures against harmful UV exposure. For example, sunscreen formulations often incorporate compounds that provide ultraviolet transparency while still offering protection against harmful rays. This balance is vital for ensuring skin safety without compromising the effectiveness of the product.The exploration of ultraviolet transparency is not limited to synthetic materials; natural substances also display this intriguing property. Certain types of glass, quartz, and even some plastics demonstrate varying degrees of ultraviolet transparency. This characteristic allows scientists to study natural phenomena under UV light, leading to discoveries in fields such as biology and geology. For instance, researchers can examine the behavior of organisms that thrive in UV-rich environments, providing insights into evolutionary adaptations.In conclusion, the concept of ultraviolet transparency plays a pivotal role in numerous scientific and technological advancements. From optical devices to solar energy solutions, understanding and harnessing this property can lead to significant improvements in various industries. As research continues to evolve, the potential applications of ultraviolet transparency will undoubtedly expand, paving the way for innovative solutions that benefit both humanity and the environment. Embracing the challenges and opportunities presented by ultraviolet transparency will be essential for future scientific endeavors and technological progress.

近年来，具有紫外透明性的材料研究在各个科学领域引起了广泛关注。紫外透明性是指材料能够让紫外线（UV）光通过而不被显著吸收或散射的能力。这一特性在光学、光子学，甚至在太阳能转换先进材料的开发中至关重要。理解紫外透明性背后的机制可以带来技术创新和环境可持续性的改善。紫外透明性至关重要的主要领域之一是光学元件的制造。设计用于传输紫外光的镜头和滤光片在摄影、显微镜和医学诊断等各种应用中都有使用。例如，紫外线消毒设备依赖于具有高紫外透明性的材料，以有效消除细菌和病毒，而不危害周围环境。这些设备的有效性直接与其构造材料的紫外透明性相关。此外，太阳能领域也从紫外透明性的进步中受益。能够利用更广泛阳光谱，包括紫外光的太阳能电池板，有潜力提高能量转换效率。研究人员正在探索新材料，这些材料不仅保持紫外透明性，而且增强太阳能电池的整体性能。通过整合这样的材料，我们可以开发出更高效的太阳能电池板，为保护地球做出贡献。此外，紫外透明性的重要性还扩展到环境科学领域。许多自然过程，如光合作用，受到紫外辐射的影响。了解某些材料如何与紫外光相互作用，可以帮助我们开发更好的防护措施，以应对有害的紫外线照射。例如，防晒霜配方通常包含提供紫外透明性的化合物，同时仍然能够抵御有害射线。这种平衡对于确保皮肤安全而不妨碍产品的有效性至关重要。对紫外透明性的探索不仅限于合成材料；天然物质也表现出这一引人注目的特性。某些类型的玻璃、石英，甚至一些塑料都显示出不同程度的紫外透明性。这一特性使科学家能够在紫外光下研究自然现象，导致生物学和地质学等领域的发现。例如，研究人员可以检查在紫外线丰富环境中繁荣的生物体的行为，从而提供对进化适应的见解。总之，紫外透明性的概念在众多科学和技术进步中发挥着关键作用。从光学设备到太阳能解决方案，理解和利用这一特性可以在各个行业带来显著改善。随着研究的不断发展，紫外透明性的潜在应用无疑将扩展，为创新解决方案铺平道路，造福人类和环境。迎接紫外透明性所带来的挑战和机遇，对于未来的科学探索和技术进步至关重要。