total surface resistance

简明释义

水面总阻力

英英释义

例句

1.To improve efficiency, we need to reduce the total surface resistance in our circuit design.

为了提高效率，我们需要降低电路设计中的总表面电阻。

2.The total surface resistance of this coating is critical for its performance in harsh environments.

该涂层的总表面电阻对其在恶劣环境中的性能至关重要。

3.During the tests, the total surface resistance was found to be higher than expected.

在测试中，发现总表面电阻比预期的要高。

4.The engineer measured the total surface resistance of the material to ensure it met industry standards.

工程师测量了材料的总表面电阻以确保其符合行业标准。

5.Reducing the total surface resistance can lead to better thermal conductivity in the material.

降低总表面电阻可以提高材料的热导率。

作文

Understanding the concept of total surface resistance is crucial in various fields, particularly in physics and engineering. This term refers to the overall resistance encountered by an electric current as it flows through a material's surface. It is an essential factor that influences how efficiently electricity can travel through different materials and is particularly significant in the design of electronic components and systems.The total surface resistance is determined by several factors, including the material properties, the surface condition, and the environmental factors surrounding the material. For instance, materials with high conductivity, such as metals, exhibit low total surface resistance, which allows for efficient current flow. Conversely, insulators like rubber or glass have high total surface resistance, making them poor conductors of electricity.In practical applications, engineers must consider the total surface resistance when designing circuits and selecting materials for specific tasks. For example, in electronic devices, minimizing the total surface resistance can lead to improved performance and energy efficiency. This is why many modern electronics utilize materials with low total surface resistance to enhance their functionality and longevity.Moreover, the total surface resistance can be influenced by external factors such as temperature, humidity, and contamination. For example, a clean metal surface may have lower total surface resistance than a corroded or oxidized one. This is why regular maintenance and cleaning of electrical contacts are necessary to ensure optimal performance.In addition to its applications in electronics, the concept of total surface resistance is also relevant in other fields such as materials science and nanotechnology. Researchers are continuously exploring new materials and coatings that can reduce total surface resistance while maintaining other desirable properties. For instance, advancements in nanomaterials have shown promise in creating surfaces with extremely low total surface resistance, which could revolutionize the way we design and manufacture electronic devices.Understanding total surface resistance is not only vital for professionals in these fields but also for students and enthusiasts who wish to delve deeper into the principles of electricity and material science. By grasping this concept, individuals can better appreciate the complexities of electrical systems and the importance of material selection in engineering.In summary, the term total surface resistance encapsulates a critical aspect of electrical conductivity that impacts a wide range of applications. Whether in the realm of electronics, materials science, or engineering, recognizing the significance of total surface resistance enables us to make informed decisions regarding material choices and system designs. As technology continues to advance, the study of total surface resistance will remain a key area of focus, driving innovation and efficiency in electrical systems across various industries.

理解总表面电阻的概念在物理和工程等多个领域中至关重要。该术语指的是电流通过材料表面时遇到的总体电阻。它是影响电力通过不同材料流动效率的重要因素，在电子元件和系统的设计中尤其显著。总表面电阻由多个因素决定，包括材料属性、表面状态以及材料周围的环境因素。例如，导电性高的材料（如金属）表现出低总表面电阻，这使得电流能够高效流动。相反，像橡胶或玻璃这样的绝缘体则具有高总表面电阻，使它们成为电的差导体。在实际应用中，工程师在设计电路和选择特定任务的材料时必须考虑总表面电阻。例如，在电子设备中，最小化总表面电阻可以提高性能和能源效率。这就是为什么许多现代电子产品采用低总表面电阻的材料，以增强其功能和使用寿命。此外，总表面电阻还会受到温度、湿度和污染等外部因素的影响。例如，干净的金属表面可能比腐蚀或氧化的表面具有更低的总表面电阻。这就是为什么定期维护和清洁电气接触点对于确保最佳性能是必要的。除了在电子学中的应用外，总表面电阻的概念在材料科学和纳米技术等其他领域也相关。研究人员不断探索新的材料和涂层，以减少总表面电阻，同时保持其他理想属性。例如，纳米材料的进展显示出创造极低总表面电阻的表面的前景，这可能会彻底改变我们设计和制造电子设备的方式。理解总表面电阻不仅对这些领域的专业人士至关重要，对希望深入电力和材料科学原理的学生和爱好者来说也是如此。通过掌握这一概念，个人可以更好地理解电气系统的复杂性以及材料选择在工程中的重要性。总之，术语总表面电阻概括了影响广泛应用的电导率的关键方面。无论是在电子学、材料科学还是工程领域，认识到总表面电阻的重要性使我们能够在材料选择和系统设计方面做出明智的决策。随着技术的不断进步，总表面电阻的研究将继续成为重点领域，推动各行业电气系统的创新和效率。