laser radiation divergence

简明释义

激光射线发散

英英释义

例句

1.Understanding laser radiation divergence 激光辐射发散 is essential for designing effective laser rangefinders.

理解激光辐射发散对设计有效的激光测距仪至关重要。

2.The laser radiation divergence 激光辐射发散 can be minimized by using high-quality lenses in laser systems.

通过在激光系统中使用高质量的透镜，可以最小化激光辐射发散。

3.The laser radiation divergence 激光辐射发散 affects the precision of laser cutting in industrial applications.

激光辐射发散影响工业应用中激光切割的精度。

4.Researchers are studying the laser radiation divergence 激光辐射发散 to improve the efficiency of laser-based medical treatments.

研究人员正在研究激光辐射发散，以提高基于激光的医疗治疗的效率。

5.In optical communication systems, minimizing laser radiation divergence 激光辐射发散 is crucial for maintaining signal integrity over long distances.

在光通信系统中，最小化激光辐射发散对保持长距离信号完整性至关重要。

作文

Laser technology has revolutionized various fields, from medicine to telecommunications. One critical aspect of laser technology is its behavior in terms of light propagation, particularly the concept known as laser radiation divergence. Understanding this phenomenon is essential for optimizing laser applications and ensuring effective performance in various settings.Laser radiation divergence refers to the tendency of a laser beam to spread out or diverge as it travels away from the source. Unlike traditional light sources, which emit light in all directions, lasers produce highly collimated beams that maintain a narrow profile over significant distances. However, even the most perfectly collimated laser beams will exhibit some degree of divergence due to the fundamental properties of light and the design of the laser system.The divergence of a laser beam is influenced by several factors, including the wavelength of the light, the diameter of the beam at its point of emission, and the characteristics of the optical components used in the laser system. Generally, shorter wavelengths tend to produce less divergence, while larger beam diameters can also help minimize this effect. Understanding these parameters is crucial for engineers and scientists who are designing laser systems for specific applications.In practical terms, laser radiation divergence has significant implications for various applications. For instance, in medical procedures such as laser surgery, precise targeting is essential. A high degree of divergence can lead to imprecise cuts or treatments, potentially compromising patient safety. Therefore, medical professionals must consider the divergence characteristics of the lasers they use to ensure accurate and effective treatments.Similarly, in the field of telecommunications, where lasers are used for fiber optic transmission, understanding laser radiation divergence is vital for optimizing signal strength and clarity. When transmitting data over long distances, the divergence of the laser beam can affect how well the light couples into the optical fibers. Engineers must carefully calculate the divergence to ensure maximum efficiency and minimal signal loss.Moreover, in industrial applications, such as laser cutting or engraving, laser radiation divergence plays a critical role in determining the quality of the finished product. A beam with excessive divergence may result in wider cuts or less defined engravings, affecting the overall precision and quality of the work. Therefore, manufacturers often invest in high-quality optics and precise alignment systems to control divergence and achieve the desired results.In conclusion, laser radiation divergence is a fundamental concept in laser technology that influences a wide range of applications, from medical procedures to telecommunications and industrial processes. By understanding the factors that contribute to divergence and its implications, professionals can better harness the power of lasers to achieve their goals. As technology continues to advance, ongoing research and development will likely lead to even more precise and efficient laser systems, further enhancing the capabilities and applications of lasers in our daily lives. As we continue to explore the potential of laser technology, it is important to keep in mind the significance of laser radiation divergence and its impact on performance across various fields. With careful consideration and optimization, lasers can be utilized to their fullest potential, driving innovation and excellence in numerous industries.

激光技术已经彻底改变了医疗、通信等多个领域。激光技术的一个关键方面是其在光传播中的行为，特别是被称为激光辐射发散的概念。理解这一现象对于优化激光应用和确保在各种设置中的有效性能至关重要。激光辐射发散指的是激光束在离开源头时向外扩散或发散的倾向。与传统光源不同，后者以全方向发射光线，激光产生高度准直的光束，能够在较大距离内保持窄的轮廓。然而，即使是最完美准直的激光束也会由于光的基本特性和激光系统的设计而表现出一定程度的发散。激光束的发散受到多个因素的影响，包括光的波长、发射点的光束直径以及激光系统中使用的光学组件的特性。通常，较短的波长往往会产生较小的发散，而较大的光束直径也可以帮助最小化这种效应。理解这些参数对于设计特定应用的激光系统的工程师和科学家至关重要。在实际应用中，激光辐射发散对各种应用具有重要意义。例如，在激光手术等医疗程序中，精确定位至关重要。高程度的发散可能导致切割或治疗不精确，从而可能危害患者安全。因此，医疗专业人员必须考虑所使用激光的发散特性，以确保治疗的准确性和有效性。同样，在通信领域，激光用于光纤传输时，理解激光辐射发散对于优化信号强度和清晰度至关重要。在长距离传输数据时，激光束的发散可能会影响光如何耦合到光纤中。工程师必须仔细计算发散，以确保最大效率和最小信号损失。此外，在工业应用中，如激光切割或雕刻，激光辐射发散在决定成品质量方面起着关键作用。过度发散的光束可能导致切割宽度或雕刻不清晰，从而影响工作的整体精度和质量。因此，制造商通常会投资于高质量的光学元件和精确的对准系统，以控制发散并实现所需的结果。总之，激光辐射发散是激光技术中的一个基本概念，影响着从医疗程序到通信和工业过程的广泛应用。通过理解影响发散的因素及其影响，专业人士可以更好地利用激光的力量来实现他们的目标。随着技术的不断进步，持续的研究和开发可能会导致更加精确和高效的激光系统，进一步增强激光在我们日常生活中的能力和应用。随着我们继续探索激光技术的潜力，重要的是要牢记激光辐射发散的重要性及其对各个领域性能的影响。通过仔细考虑和优化，激光可以充分发挥其潜力，推动众多行业的创新和卓越。