excitation anode

简明释义

激励阳极

英英释义

例句

1.To enhance the output power, we modified the design of the excitation anode (激发阳极).

为了增强输出功率，我们修改了excitation anode (激发阳极) 的设计。

2.The researchers found that the material of the excitation anode (激发阳极) significantly affects the performance of the device.

研究人员发现，excitation anode (激发阳极) 的材料显著影响设备的性能。

3.In our experiment, we measured the voltage across the excitation anode (激发阳极) to determine its efficiency.

在我们的实验中，我们测量了excitation anode (激发阳极) 上的电压，以确定其效率。

4.The excitation anode (激发阳极) plays a crucial role in the ionization process of the gas discharge tube.

excitation anode (激发阳极) 在气体放电管的电离过程中起着至关重要的作用。

5.The performance of the laser was greatly improved by optimizing the excitation anode (激发阳极) configuration.

通过优化excitation anode (激发阳极) 的配置，激光的性能得到了极大提升。

作文

In the field of electronics and physics, various components play crucial roles in the functioning of devices. One such component is the excitation anode, which is essential in many applications, particularly in gas discharge tubes and certain types of lasers. Understanding the function and significance of the excitation anode can provide deeper insights into how electronic systems operate. The term excitation anode refers to a specific type of electrode that facilitates the excitation of atoms or molecules within a medium. When an electrical current passes through the excitation anode, it generates a high voltage that ionizes the surrounding gas or plasma. This process creates excited states of atoms or molecules, which can then emit light or other forms of energy as they return to their ground state. This principle is applied in neon lights, fluorescent bulbs, and various display technologies.One of the most notable applications of the excitation anode is in gas discharge lamps. These lamps utilize the phenomenon of gas ionization to produce light. The excitation anode serves as a key element in initiating this ionization process. When the lamp is powered on, the excitation anode emits electrons into the gas-filled tube, leading to collisions with gas molecules. These collisions result in the excitation of the gas, producing a glow that illuminates the surroundings. Moreover, the excitation anode plays a vital role in laser technology. In gas lasers, for instance, the excitation anode helps to create a population inversion, a necessary condition for laser action. By exciting the gas atoms using the excitation anode, the system can achieve a state where more atoms are in an excited state than in the ground state. This leads to stimulated emission, where an incoming photon stimulates an excited atom to release another photon, resulting in a coherent beam of light. The efficiency and effectiveness of devices utilizing the excitation anode depend significantly on its design and material properties. Engineers must carefully select materials that can withstand high voltages and temperatures while maintaining conductivity. Additionally, the geometry of the excitation anode can influence the distribution of electric fields and, consequently, the efficiency of excitation processes. In conclusion, the excitation anode is a pivotal component in various electronic devices, playing a significant role in processes such as gas ionization and laser operation. A thorough understanding of its function and applications not only enhances our knowledge of electronic systems but also inspires innovation in technology. As we continue to explore new materials and designs for the excitation anode, we may unlock even more advanced applications in lighting, communication, and beyond.

在电子和物理学领域，各种组件在设备的运行中发挥着至关重要的作用。其中一个组件是激发阳极，它在许多应用中都是必不可少的，特别是在气体放电管和某些类型的激光器中。了解激发阳极的功能和重要性可以更深入地理解电子系统的工作原理。术语激发阳极指的是一种特定类型的电极，它促进介质中原子或分子的激发。当电流通过激发阳极时，会产生高电压，使周围的气体或等离子体电离。这个过程会产生原子或分子的激发态，当它们返回基态时，可以发出光或其他形式的能量。这一原理被应用于霓虹灯、荧光灯泡和各种显示技术中。激发阳极最显著的应用之一是在气体放电灯中。这些灯利用气体电离现象来产生光。激发阳极作为启动这一电离过程的关键元素。当灯通电时，激发阳极向充满气体的管道发射电子，导致与气体分子的碰撞。这些碰撞导致气体的激发，产生照亮周围环境的光芒。此外，激发阳极在激光技术中也发挥着重要作用。例如，在气体激光器中，激发阳极有助于创造人口反转，这是激光作用所需的条件。通过使用激发阳极激发气体原子，系统可以达到一种状态，即处于激发态的原子数量超过处于基态的原子数量。这导致了受激发射，其中一个入射光子刺激一个激发原子释放另一个光子，从而产生一束相干光。使用激发阳极的设备的效率和效果在很大程度上取决于其设计和材料特性。工程师必须仔细选择能够承受高电压和高温的材料，同时保持导电性。此外，激发阳极的几何形状可以影响电场的分布，从而影响激发过程的效率。总之，激发阳极是各种电子设备中的关键组件，在气体电离和激光操作等过程中发挥着重要作用。透彻理解其功能和应用不仅增强了我们对电子系统的知识，还激发了技术创新。随着我们继续探索激发阳极的新材料和设计，我们可能会在照明、通信等领域解锁更多先进应用。