non-conducting state
简明释义
不导通状态
英英释义
例句
1.The researchers were excited to discover that the compound could enter a non-conducting state 非导电状态 when exposed to certain chemicals.
研究人员很高兴地发现,该化合物在接触某些化学物质时可以进入非导电状态。
2.In electronics, insulating materials are often required to maintain a non-conducting state 非导电状态 to prevent short circuits.
在电子产品中,绝缘材料通常需要保持非导电状态以防止短路。
3.When the voltage is removed, the circuit returns to a non-conducting state 非导电状态, ensuring safety.
当电压被移除时,电路会恢复到非导电状态,确保安全。
4.The material was tested to confirm its ability to remain in a non-conducting state 非导电状态 under high temperatures.
该材料经过测试以确认其在高温下保持非导电状态的能力。
5.A good insulator should effectively maintain a non-conducting state 非导电状态 even at high frequencies.
一个好的绝缘体应该能够在高频率下有效地保持非导电状态。
作文
In the realm of physics, materials can be classified based on their electrical properties. One such classification is the distinction between conducting and non-conducting states. A material in a non-conducting state (非导电状态) does not allow the flow of electric current through it. This property is crucial in various applications, especially in electronics and electrical engineering. Understanding the non-conducting state (非导电状态) helps us appreciate how different materials interact with electricity and how they can be utilized in technology.To elaborate, when a material is in a non-conducting state (非导电状态), it means that its electrons are tightly bound to their respective atoms and cannot move freely. This lack of free-moving electrons is what defines the inability of the material to conduct electricity. Common examples of materials that exhibit this behavior include rubber, glass, and certain types of plastics. These materials serve as insulators, preventing unwanted flow of electricity and protecting both users and sensitive electronic components from damage.The importance of non-conducting states (非导电状态) cannot be overstated in the context of safety. For instance, when working with high-voltage systems, engineers often use insulating materials to cover wires and components. This ensures that the electric current remains confined to the intended pathways and does not pose a risk to individuals who may come into contact with the equipment. By maintaining a non-conducting state (非导电状态), these materials play a vital role in preventing electrical shocks and short circuits.Moreover, the non-conducting state (非导电状态) is not just a passive characteristic; it can be influenced by external factors such as temperature and pressure. For instance, some materials can transition from a non-conducting state (非导电状态) to a conducting state when subjected to heat or other stimuli. This phenomenon is observed in semiconductors, which are essential in modern electronics. By manipulating the conditions, engineers can create devices that switch between conducting and non-conducting states (非导电状态), allowing for the development of transistors and diodes that are fundamental to computer technology.In conclusion, the concept of a non-conducting state (非导电状态) is pivotal in understanding how materials interact with electricity. It highlights the differences between insulators and conductors and underscores the importance of safety in electrical applications. As technology continues to advance, the study of non-conducting states (非导电状态) will remain a key area of research, providing insights that could lead to innovative solutions in electronics and energy management. The ability to control and utilize these states effectively will undoubtedly shape the future of our technological landscape.
在物理学领域,材料可以根据其电气特性进行分类。其中一种分类是导电状态与非导电状态之间的区别。处于非导电状态(non-conducting state)的材料不允许电流通过。这一特性在各种应用中至关重要,特别是在电子和电气工程中。理解非导电状态(non-conducting state)帮助我们欣赏不同材料如何与电力相互作用,以及它们如何在技术中被利用。进一步说,当材料处于非导电状态(non-conducting state)时,意味着其电子紧密地绑定在各自的原子上,无法自由移动。这种缺乏自由移动电子的特性定义了材料无法导电的原因。常见的表现出这种行为的材料包括橡胶、玻璃和某些类型的塑料。这些材料作为绝缘体,防止电流的不必要流动,保护用户和敏感的电子元件免受损害。在安全方面,非导电状态(non-conducting state)的重要性不容小觑。例如,在处理高压系统时,工程师通常会使用绝缘材料覆盖电线和组件。这确保电流保持在预定路径内,不会对可能接触设备的个人构成风险。通过维持非导电状态(non-conducting state),这些材料在防止电击和短路方面发挥着至关重要的作用。此外,非导电状态(non-conducting state)不仅仅是一种被动特性;它可以受到温度和压力等外部因素的影响。例如,一些材料在受到热量或其他刺激时可以从非导电状态(non-conducting state)转变为导电状态。这种现象在半导体中观察到,半导体在现代电子学中至关重要。通过操控条件,工程师可以制造出在导电和非导电状态(non-conducting state)之间切换的设备,从而推动了晶体管和二极管的发展,这些都是计算机技术的基础。总之,非导电状态(non-conducting state)的概念在理解材料如何与电力相互作用方面至关重要。它突出了绝缘体与导体之间的差异,并强调了电气应用中的安全性。随着技术的不断进步,对非导电状态(non-conducting state)的研究将仍然是一个关键领域,提供可能导致电子和能源管理创新解决方案的洞察力。有效地控制和利用这些状态无疑将塑造我们技术景观的未来。
