anomalous skin effect

简明释义

反常囚效应

英英释义

例句

1.In their experiments, they measured the anomalous skin effect 异常表皮效应 in superconductors to better understand their properties.

在他们的实验中，他们测量了超导体中的异常表皮效应 anomalous skin effect 以更好地理解其特性。

2.Engineers must account for the anomalous skin effect 异常表皮效应 when designing RF circuits to ensure optimal performance.

工程师在设计射频电路时必须考虑异常表皮效应 anomalous skin effect 以确保最佳性能。

3.Researchers are investigating the anomalous skin effect 异常表皮效应 in nanostructured materials for potential applications in electronics.

研究人员正在调查纳米结构材料中的异常表皮效应 anomalous skin effect 以寻找在电子学中的潜在应用。

4.The research team discovered that the anomalous skin effect 异常表皮效应 significantly impacts the conductivity of certain metals at high frequencies.

研究小组发现，异常表皮效应 anomalous skin effect 在高频率下显著影响某些金属的导电性。

5.The anomalous skin effect 异常表皮效应 can lead to unexpected losses in power transmission systems.

在电力传输系统中，异常表皮效应 anomalous skin effect 可能导致意外的损耗。

作文

The study of electromagnetic waves has led to various intriguing phenomena in physics, one of which is the anomalous skin effect. This phenomenon occurs when alternating current (AC) flows through a conductor, leading to a situation where the current density is not uniform across the cross-section of the conductor. Typically, in conventional conductors, the current tends to flow near the surface, a behavior known as the skin effect. However, under certain conditions, particularly at high frequencies, the anomalous skin effect can cause the current to penetrate deeper into the material than would be expected. This deviation from the norm raises important questions about the behavior of materials in high-frequency applications.Understanding the anomalous skin effect is essential for engineers and physicists, especially in fields such as telecommunications and power transmission. For instance, in radio frequency applications, components like antennas and transmission lines must account for this effect to ensure efficiency and performance. The anomalous skin effect can lead to increased resistive losses, which can significantly impact the overall efficiency of these systems. As a result, designers must carefully select materials and geometries that mitigate these losses while maximizing signal integrity.Moreover, the anomalous skin effect is not limited to just metals; it can also occur in superconductors under specific conditions. Superconductors exhibit unique properties that allow them to conduct electricity without resistance, but when subjected to high-frequency AC, the anomalous skin effect can disrupt this ideal behavior. Understanding how this effect influences superconducting materials is crucial for developing advanced technologies, such as magnetic resonance imaging (MRI) machines and particle accelerators.In addition to practical applications, the anomalous skin effect also presents interesting theoretical challenges. Researchers are continually exploring the underlying physics that governs this phenomenon, seeking to develop models that accurately predict its behavior across different materials and frequencies. This research not only enhances our understanding of electromagnetism but also paves the way for innovative solutions in various technological domains.In conclusion, the anomalous skin effect is a fascinating topic that bridges theoretical physics and practical engineering. As technology continues to advance, the implications of this effect become increasingly significant. By deepening our understanding of the anomalous skin effect, we can improve the efficiency of electrical systems and unlock new possibilities in the realm of high-frequency electronics. The exploration of this phenomenon is a testament to the ever-evolving nature of science and its ability to challenge our perceptions of material behavior in the presence of electromagnetic fields.

电磁波的研究引发了许多物理学中的有趣现象，其中之一就是异常表皮效应。这一现象发生在交流电（AC）流经导体时，导致电流密度在导体的横截面上不均匀。通常情况下，在常规导体中，电流倾向于流向表面，这种行为被称为表皮效应。然而，在某些条件下，特别是在高频率下，异常表皮效应会导致电流比预期更深地渗透到材料中。这种偏离常规的现象引发了有关材料在高频应用中行为的重要问题。理解异常表皮效应对于工程师和物理学家至关重要，特别是在电信和电力传输等领域。例如，在射频应用中，像天线和传输线这样的组件必须考虑到这一效应，以确保效率和性能。异常表皮效应可能导致增加的电阻损耗，这会显著影响这些系统的整体效率。因此，设计者必须仔细选择材料和几何形状，以减轻这些损失，同时最大限度地提高信号完整性。此外，异常表皮效应不仅限于金属；在特定条件下，它也可以发生在超导体中。超导体具有独特的特性，使其能够无阻力地导电，但当受到高频交流电的影响时，异常表皮效应可能会干扰这种理想行为。理解这一效应如何影响超导材料对于开发先进技术至关重要，例如磁共振成像（MRI）机器和粒子加速器。除了实际应用外，异常表皮效应还提出了有趣的理论挑战。研究人员不断探索支配这一现象的基本物理，寻求开发能够准确预测其在不同材料和频率下行为的模型。这项研究不仅增强了我们对电磁学的理解，还为各个技术领域中的创新解决方案铺平了道路。总之，异常表皮效应是一个迷人的主题，连接了理论物理和实践工程。随着技术的不断进步，这一效应的影响变得越来越重要。通过加深对异常表皮效应的理解，我们可以提高电气系统的效率，并在高频电子学领域解锁新的可能性。对这一现象的探索证明了科学不断发展的本质及其挑战我们对电磁场中材料行为的看法的能力。