radiation coupling

简明释义

辐射耦合

英英释义

例句

1.The effectiveness of the antenna design was evaluated based on its radiation coupling 辐射耦合 efficiency.

天线设计的有效性是基于其辐射耦合 辐射耦合 效率进行评估的。

2.In quantum optics, radiation coupling 辐射耦合 plays a crucial role in the interaction between light and matter.

在量子光学中，辐射耦合 辐射耦合 在光与物质之间的相互作用中起着关键作用。

3.They discovered that the radiation coupling 辐射耦合 efficiency increased with the angle of incidence.

他们发现，辐射耦合 辐射耦合 效率随着入射角的增加而提高。

4.The researchers focused on improving radiation coupling 辐射耦合 in their new photonic device.

研究人员专注于改善他们的新光子设备中的辐射耦合 辐射耦合 。

5.In medical imaging, radiation coupling 辐射耦合 is essential for accurate diagnosis.

在医学成像中，辐射耦合 辐射耦合 对于准确诊断至关重要。

作文

In the field of physics and engineering, understanding the principles of energy transfer is crucial. One important concept in this domain is radiation coupling, which refers to the interaction between electromagnetic radiation and matter. This phenomenon plays a significant role in various applications, from telecommunications to thermal management systems. By grasping the fundamentals of radiation coupling, we can enhance our ability to design and optimize technologies that rely on these principles.To begin with, radiation coupling occurs when energy is exchanged between two systems through electromagnetic waves. This process can be observed in numerous contexts, such as in antennas where radio waves are emitted and received. The efficiency of this energy transfer is influenced by factors like frequency, distance, and the properties of the materials involved. For instance, in wireless communication, the design of antennas must account for radiation coupling to ensure that signals are transmitted effectively over long distances.Moreover, radiation coupling is not limited to telecommunications; it is also vital in thermal systems. In applications such as solar panels, the ability to capture and convert solar radiation into usable energy depends on the principles of radiation coupling. The materials used in solar cells are specifically chosen to maximize their interaction with sunlight, thereby enhancing energy absorption. Understanding how radiation coupling works allows engineers to improve the efficiency of solar energy systems, making them more viable alternatives to fossil fuels.Furthermore, the concept of radiation coupling extends to the realm of astrophysics. Scientists study how stars emit radiation and how this energy interacts with surrounding matter in space. This research helps us understand the life cycles of stars and the formation of galaxies. By analyzing radiation coupling in these cosmic contexts, researchers can gain insights into the fundamental processes that govern the universe.In addition to its scientific significance, radiation coupling has practical implications in various industries. For example, in the medical field, radiation therapy employs the principles of radiation coupling to target cancer cells while minimizing damage to surrounding healthy tissue. By carefully controlling the dosage and type of radiation used, healthcare professionals can improve treatment outcomes for patients.In conclusion, the concept of radiation coupling is integral to our understanding of energy transfer in both natural and engineered systems. Whether in telecommunications, renewable energy, astrophysics, or medicine, the principles underlying radiation coupling have far-reaching implications. As we continue to explore and innovate in these fields, a deeper comprehension of radiation coupling will undoubtedly lead to advancements that enhance our quality of life and expand our knowledge of the universe.

在物理和工程领域，理解能量传递的原理至关重要。一个重要的概念是辐射耦合，它指的是电磁辐射与物质之间的相互作用。这一现象在从电信到热管理系统的各种应用中发挥着重要作用。通过掌握辐射耦合的基本原理，我们可以增强设计和优化依赖这些原理的技术的能力。首先，辐射耦合发生在两个系统通过电磁波进行能量交换时。这一过程可以在许多背景下观察到，例如在天线中，电波被发射和接收。能量传递的效率受到频率、距离和所涉及材料特性的影响。例如，在无线通信中，天线的设计必须考虑到辐射耦合，以确保信号能够有效地在长距离上传输。此外，辐射耦合不仅限于电信；它在热系统中也至关重要。在太阳能电池板等应用中，捕获和转换太阳辐射为可用能量的能力依赖于辐射耦合的原理。太阳能电池中使用的材料专门选择，以最大化其与阳光的相互作用，从而增强能量吸收。理解辐射耦合的工作原理使工程师能够提高太阳能系统的效率，使其成为化石燃料的更可行替代品。此外，辐射耦合的概念扩展到天体物理学领域。科学家研究恒星是如何发射辐射的，以及这种能量如何与太空中的周围物质相互作用。这项研究帮助我们理解恒星的生命周期和星系的形成。通过分析这些宇宙背景下的辐射耦合，研究人员可以深入了解支配宇宙的基本过程。除了科学意义外，辐射耦合在各个行业中还具有实际应用。例如，在医疗领域，放射治疗利用辐射耦合的原理来针对癌细胞，同时尽量减少对周围健康组织的损害。通过仔细控制使用的辐射剂量和类型，医疗专业人员可以改善患者的治疗效果。总之，辐射耦合的概念对于我们理解自然和工程系统中的能量传递至关重要。无论是在电信、可再生能源、天体物理学还是医学中，支撑辐射耦合的原理都具有深远的影响。随着我们继续在这些领域探索和创新，对辐射耦合的更深入理解无疑将带来提升我们生活质量和扩展我们对宇宙知识的进步。