calorescence

简明释义

英[ˌkæl.əˈrɛs.əns]美[ˌkæl.əˈrɛs.əns]

n. 发光热线；灼热

英英释义

单词用法

同义词

反义词

例句

1.By analyzed the effects of fiber's spring, cycle flex, calorescence and the heat expand, the strain sensitivity and temperature sensitivity of FBG are obtained.

通过对光纤的弹光效应、光纤周期的伸缩、热光效应、热膨胀效应的分析得出了光纤光栅的应变灵敏度和温度灵敏度。

2.By analyzed the effects of fiber's spring, cycle flex, calorescence and the heat expand, the strain sensitivity and temperature sensitivity of FBG are obtained.

通过对光纤的弹光效应、光纤周期的伸缩、热光效应、热膨胀效应的分析得出了光纤光栅的应变灵敏度和温度灵敏度。

3.At the same time, the characteristics of the LPG temperature sensing about different cladding calorescence coefficient or grating period are showed.

同时在LPG温度传感方面，讨论了不同包层材料热光系数或者不同光栅周期影响下的特性。

4.The phenomenon of calorescence is often observed in certain minerals when they absorb heat and emit light.

某些矿物在吸收热量并发出光时，常常观察到热致荧光现象。

5.During the experiment, the team noted that the calorescence effect increased with the temperature of the material.

在实验中，团队注意到材料的温度越高，热致荧光效应越明显。

6.Scientists are studying calorescence to develop new materials for energy-efficient lighting.

科学家们正在研究热致荧光，以开发新的节能照明材料。

7.The calorescence observed in some gemstones makes them particularly valuable.

某些宝石中观察到的热致荧光使它们特别有价值。

8.Understanding calorescence can lead to advancements in thermophotonic devices.

理解热致荧光可以推动热光子设备的进步。

作文

In the realm of physics and materials science, the term calorescence refers to the phenomenon where certain materials emit thermal energy or heat upon exposure to light. This intriguing process is not only a fascinating subject of study but also has practical applications in various fields, including energy conversion and lighting technologies. Understanding calorescence can lead to innovations that improve energy efficiency and sustainability in our daily lives. To delve deeper into the concept of calorescence, we must first explore its underlying principles. When a material absorbs photons from light, it can undergo a series of excitations at the atomic or molecular level. These excitations can result in the re-emission of energy in the form of heat rather than light. This behavior is particularly prominent in certain types of materials, such as phosphors and some organic compounds. The efficiency of calorescence depends on the specific properties of the material, including its bandgap and the nature of the absorbed light. One of the most notable applications of calorescence is in the field of solar energy. Solar panels, for instance, convert sunlight into electricity through photovoltaic processes. However, a significant portion of the solar energy is lost as heat due to inefficiencies in the conversion process. By integrating materials that exhibit calorescence, researchers aim to capture this waste heat and convert it back into usable energy, thereby enhancing the overall efficiency of solar energy systems. Moreover, calorescence plays a role in the development of innovative lighting solutions. Traditional incandescent bulbs generate light through the heating of a filament, resulting in considerable energy loss as heat. In contrast, light-emitting diodes (LEDs) are more efficient, but they still produce some heat. By utilizing materials that demonstrate calorescence, it may be possible to create lighting systems that not only provide illumination but also contribute to heating spaces during colder months, thus reducing energy consumption. The study of calorescence also extends to the realm of environmental science. For instance, understanding how certain materials interact with solar radiation can help in designing better building materials that reflect or absorb heat appropriately, contributing to energy-efficient architecture. This could lead to the development of smart buildings that adapt to changing weather conditions, ultimately reducing reliance on artificial heating and cooling systems. In conclusion, calorescence is a captivating phenomenon that bridges the gap between theoretical physics and practical applications. Its potential to enhance energy efficiency in renewable energy systems, improve lighting technologies, and contribute to sustainable architecture makes it a vital area of research. As we continue to explore the intricacies of calorescence, we edge closer to realizing a future where energy is utilized more effectively and sustainably. By investing in studies related to calorescence, we can pave the way for innovative solutions that address the pressing energy challenges of our time.

在物理学和材料科学领域，术语calorescence指的是某些材料在暴露于光照时发出热能或热量的现象。这一引人入胜的过程不仅是一个迷人的研究主题，还有许多实际应用，包括能源转换和照明技术。理解calorescence可以引领创新，从而提高我们日常生活中的能源效率和可持续性。 要深入了解calorescence的概念，我们首先必须探索其基本原理。当材料吸收来自光的光子时，它可以在原子或分子层面上经历一系列激发。这些激发可能导致能量以热而非光的形式重新发射。这种行为在某些类型的材料中尤为显著，例如磷光体和一些有机化合物。calorescence的效率取决于材料的特定性质，包括其带隙和吸收光的性质。 calorescence最显著的应用之一是在太阳能领域。例如，太阳能电池板通过光伏过程将阳光转化为电能。然而，太阳能的很大一部分由于转换过程中的低效率而以热量的形式损失。通过整合表现出calorescence的材料，研究人员旨在捕获这些废热并将其转化为可用能量，从而提高太阳能系统的整体效率。 此外，calorescence在创新照明解决方案的开发中也发挥着作用。传统的白炽灯泡通过加热灯丝产生光，从而导致相当大的能量损失作为热量。相比之下，发光二极管（LED）更高效，但它们仍然会产生一些热量。通过利用表现出calorescence的材料，可能会创造出不仅提供照明，还能在寒冷月份为空间供暖的照明系统，从而减少能耗。 对calorescence的研究还扩展到环境科学领域。例如，理解某些材料如何与太阳辐射相互作用可以帮助设计更好的建筑材料，以适当地反射或吸收热量，从而促进节能建筑的建设。这可能导致智能建筑的发展，能够适应不断变化的天气条件，最终减少对人工供暖和制冷系统的依赖。 总之，calorescence是一个引人入胜的现象，桥接了理论物理学和实际应用之间的差距。它在提高可再生能源系统的能源效率、改善照明技术和促进可持续建筑方面的潜力使其成为一个重要的研究领域。随着我们继续探索calorescence的复杂性，我们更接近实现一个能源利用更加有效和可持续的未来。通过投资与calorescence相关的研究，我们可以为解决我们时代紧迫的能源挑战铺平道路。