abnormal glow discharge
简明释义
异常辉光放电
英英释义
例句
1.The technician noticed an abnormal glow discharge 异常辉光放电 during the equipment test.
技术人员在设备测试中注意到有一个异常辉光放电。
2.The presence of abnormal glow discharge 异常辉光放电 could lead to safety hazards in the laboratory.
实验室中存在异常辉光放电可能会导致安全隐患。
3.Engineers are studying the effects of abnormal glow discharge 异常辉光放电 on material degradation.
工程师正在研究异常辉光放电对材料退化的影响。
4.We need to investigate the cause of the abnormal glow discharge 异常辉光放电 observed in the reactor.
我们需要调查反应器中观察到的异常辉光放电的原因。
5.An abnormal glow discharge 异常辉光放电 can indicate a malfunction in the plasma chamber.
一个异常辉光放电可能表示等离子体腔室故障。
作文
The study of plasma physics often leads to fascinating phenomena, one of which is the abnormal glow discharge. This term refers to a type of electrical discharge that occurs in gases under certain conditions. Unlike normal glow discharges, which are well-defined and predictable, abnormal glow discharge presents unique characteristics that can be both intriguing and complex. Understanding this phenomenon requires a deep dive into the principles of gas ionization and the behavior of charged particles in electric fields.To begin with, it is essential to grasp what a glow discharge is. In a typical glow discharge, when a gas is subjected to a strong electric field, it becomes ionized, allowing current to flow through it. This ionization creates a luminous glow, which is visible to the naked eye. However, when the conditions change—such as varying pressure, voltage, or gas composition—the discharge may enter an abnormal glow discharge state. This transition can lead to unexpected behaviors, such as fluctuations in brightness and changes in color, making it a subject of intense study.The abnormal glow discharge can be observed in various applications, including neon lights, plasma displays, and even in some types of lasers. Researchers have found that the properties of this discharge can be manipulated for practical uses. For instance, by altering the gas mixture or the pressure within a tube, one can achieve different visual effects or enhance the efficiency of light emission. This adaptability is one reason why understanding abnormal glow discharge is crucial for advancements in lighting technology.Moreover, the abnormal glow discharge has implications beyond just lighting. In the field of material science, it plays a significant role in processes like sputtering and surface modification. When materials are exposed to this type of discharge, the energetic particles can alter their surfaces at a microscopic level, leading to improved adhesion properties or enhanced durability. Thus, the practical applications of abnormal glow discharge extend into industries such as electronics and manufacturing, where surface characteristics are paramount.In conclusion, the abnormal glow discharge is a captivating topic within plasma physics that combines both theoretical and practical aspects. Its unpredictable nature and potential for manipulation make it a valuable subject for ongoing research. As scientists continue to explore the intricacies of this phenomenon, we can expect to see further innovations in technology that leverage the unique properties of abnormal glow discharge. By understanding this concept more thoroughly, we can unlock new possibilities in fields ranging from lighting design to advanced materials engineering.
等离子体物理的研究常常会导致一些迷人的现象,其中之一就是异常辉光放电。这个术语指的是在某些条件下发生在气体中的一种电气放电类型。与正常的辉光放电不同,正常的辉光放电是明确且可预测的,而异常辉光放电则呈现出独特的特征,这些特征既引人入胜又复杂。理解这一现象需要深入探讨气体电离的原理以及带电粒子在电场中的行为。首先,必须理解什么是辉光放电。在典型的辉光放电中,当气体受到强电场的作用时,它会被电离,从而允许电流通过。这种电离产生了可肉眼可见的发光。但是,当条件发生变化,例如压力、电压或气体成分的变化,放电可能进入异常辉光放电状态。这种转变可能导致意想不到的行为,例如亮度波动和颜色变化,使其成为一个引人关注的研究对象。异常辉光放电可以在多种应用中观察到,包括霓虹灯、等离子显示器,甚至某些类型的激光器。研究人员发现,可以操控这种放电的特性以实现实际用途。例如,通过改变气体混合物或管道内的压力,可以实现不同的视觉效果或提高光发射的效率。这种适应性是理解异常辉光放电对照明技术进步至关重要的原因之一。此外,异常辉光放电在材料科学领域也具有重要意义,它在溅射和表面改性等过程中发挥着重要作用。当材料暴露在这种类型的放电中时,能量粒子可以在微观层面上改变其表面,导致粘附性能的改善或耐用性的增强。因此,异常辉光放电的实际应用扩展到电子和制造等行业,在这些行业中,表面特性至关重要。总之,异常辉光放电是等离子体物理学中的一个迷人主题,结合了理论和实践的各个方面。其不可预测的特性和操控潜力使其成为持续研究的宝贵主题。随着科学家们继续探索这一现象的复杂性,我们可以期待在利用异常辉光放电独特特性的技术创新方面取得进一步进展。通过更全面地理解这一概念,我们可以在从照明设计到先进材料工程等领域解锁新的可能性。
