single mode laser oscillation

简明释义

单模激光振荡

英英释义

例句

1.The research team focused on achieving single mode laser oscillation to improve the precision of their measurements.

研究团队专注于实现单模激光振荡以提高测量的精确度。

2.We utilized single mode laser oscillation to achieve a narrow linewidth in our laser system.

我们利用单模激光振荡在我们的激光系统中实现了窄线宽。

3.In telecommunications, single mode laser oscillation is essential for long-distance fiber optic communication.

在电信中，单模激光振荡对于长距离光纤通信至关重要。

4.The performance of the sensor improved significantly with single mode laser oscillation technology.

传感器的性能随着单模激光振荡技术的应用显著提高。

5.The stability of single mode laser oscillation makes it ideal for applications in quantum optics.

由于单模激光振荡的稳定性，使其成为量子光学应用的理想选择。

作文

In the realm of photonics and laser technology, the concept of single mode laser oscillation is fundamental to understanding how lasers operate with precision and efficiency. A laser, which stands for Light Amplification by Stimulated Emission of Radiation, can be designed to emit light in various modes. However, when we refer to single mode laser oscillation (单模激光振荡), we are specifically talking about a laser that operates using a single transverse mode. This means that the laser emits light in a very specific manner, characterized by a single frequency and a well-defined spatial distribution. The significance of single mode laser oscillation lies in its applications across various fields, including telecommunications, medicine, and manufacturing. In telecommunications, for example, single-mode fibers are used to transmit data over long distances with minimal loss. The use of lasers that exhibit single mode laser oscillation ensures that the light travels efficiently through these fibers, maintaining the integrity of the data being transmitted. In medical applications, lasers that utilize single mode laser oscillation are employed in procedures such as laser surgery and phototherapy. The precision of a single-mode laser allows for targeted treatments, minimizing damage to surrounding tissues and improving patient outcomes. For instance, in ophthalmology, lasers that operate in single mode can be used for corrective eye surgeries, where accuracy is crucial. Moreover, in the field of manufacturing, single mode laser oscillation plays a vital role in processes such as laser cutting and engraving. The focused beam produced by a single-mode laser allows for intricate designs and high-quality finishes, making it an essential tool in industries ranging from automotive to jewelry making. Understanding the principles behind single mode laser oscillation also involves delving into the physics of laser operation. A laser cavity typically consists of two mirrors facing each other, creating a resonant optical cavity. When the gain medium within the cavity is pumped with energy, it stimulates the emission of photons. In a single-mode configuration, the cavity is designed such that only one specific mode of light can resonate, leading to the dominance of that particular frequency in the output. This results in a highly coherent and monochromatic beam of light, which is a hallmark of laser technology. In conclusion, the concept of single mode laser oscillation (单模激光振荡) is crucial in various scientific and industrial applications. Its ability to produce a coherent beam of light with minimal divergence makes it invaluable in fields such as telecommunications, medicine, and manufacturing. As technology continues to evolve, the importance of understanding and harnessing the properties of single mode laser oscillation will undoubtedly grow, paving the way for innovations that enhance our daily lives and push the boundaries of what is possible with laser technology.

在光子学和激光技术领域，单模激光振荡的概念对于理解激光如何精确高效地工作是基础。激光，即通过受激辐射的光放大，可以设计成以各种模式发射光。然而，当我们提到单模激光振荡时，我们特别指的是一种以单一横向模式操作的激光。这意味着激光以非常特定的方式发射光，具有单一频率和明确的空间分布。 单模激光振荡的重要性体现在其在电信、医学和制造等多个领域的应用中。例如，在电信中，单模光纤用于长距离传输数据，损耗最小。使用表现出单模激光振荡的激光确保光在这些光纤中高效传播，保持所传输数据的完整性。 在医学应用中，利用单模激光振荡的激光被用于激光手术和光疗等程序。单模激光的精确性允许针对性治疗，最小化对周围组织的损伤，提高患者的治疗效果。例如，在眼科中，操作于单模的激光可用于矫正眼睛的手术，其中准确性至关重要。 此外，在制造领域，单模激光振荡在激光切割和雕刻等工艺中扮演着重要角色。单模激光产生的聚焦光束允许复杂的设计和高质量的表面处理，使其成为从汽车到珠宝制作等行业的重要工具。 理解单模激光振荡背后的原理还涉及激光操作的物理学。激光腔通常由两个相对的镜子组成，形成一个共振光学腔。当腔内的增益介质被能量泵送时，它刺激光子的发射。在单模配置中，腔被设计为只有一个特定的光模式能够共振，从而导致该特定频率在输出中的主导地位。这导致了高度相干和单色光束的产生，这是激光技术的标志。 总之，单模激光振荡的概念在各种科学和工业应用中至关重要。其以最小的发散产生相干光束的能力使其在电信、医学和制造等领域中不可或缺。随着技术的不断发展，理解和利用单模激光振荡特性的能力无疑将会增长，为增强我们的日常生活和推动激光技术可能性的边界铺平道路。