high conductivity

简明释义

离导电率

英英释义

例句

1.Graphene is known for its high conductivity (高导电性) and strength, which are valuable in electronics.

石墨烯以其高导电性（高导电性）和强度而闻名，这在电子产品中非常有价值。

2.Silver has the high conductivity (高导电性) among all metals, making it ideal for certain applications.

银是所有金属中具有高导电性（高导电性）的金属，使其在某些应用中理想。

3.The high conductivity (高导电性) of aluminum makes it a popular choice for overhead power lines.

铝的高导电性（高导电性）使其成为架空电力线路的热门选择。

4.Copper is widely used in electrical wiring due to its high conductivity (高导电性).

铜因其高导电性（高导电性）而广泛用于电线。

5.Materials with high conductivity (高导电性) are essential for efficient power transmission.

具有高导电性（高导电性）的材料对高效电力传输至关重要。

作文

In the world of materials science, understanding the properties of different substances is crucial for advancements in technology. One property that stands out is high conductivity, which refers to a material's ability to conduct electric current or heat efficiently. This characteristic is vital in various applications, ranging from electronics to energy transmission. The importance of high conductivity can be observed in everyday devices such as smartphones, laptops, and power lines. For instance, metals like copper and aluminum are renowned for their high conductivity, making them ideal choices for wiring and components in electronic devices. The reason behind the high conductivity of certain materials lies in their atomic structure. In metals, the presence of free electrons allows for the easy flow of electrical current. When a voltage is applied, these free electrons move rapidly, resulting in efficient energy transfer. This is why metals are often used in electrical applications where high conductivity is required. Moreover, the quest for materials with high conductivity does not stop at traditional metals. Researchers are continuously exploring new materials, such as graphene and carbon nanotubes, which exhibit even greater levels of high conductivity. These materials have the potential to revolutionize the electronics industry by enabling faster and more efficient devices. For example, graphene, a single layer of carbon atoms arranged in a two-dimensional lattice, has shown extraordinary high conductivity properties, making it a candidate for next-generation transistors and other electronic components. In addition to electronics, high conductivity plays a significant role in renewable energy technologies. Solar panels, for example, rely on materials that can efficiently convert sunlight into electricity. The high conductivity of certain semiconductors enhances the performance of solar cells, leading to better energy conversion rates. Similarly, in the field of energy storage, batteries benefit from materials with high conductivity to improve charge and discharge rates, ultimately enhancing the overall efficiency of the energy storage systems. Furthermore, the implications of high conductivity extend beyond just efficiency; they also impact sustainability. By utilizing materials with high conductivity, we can reduce energy losses during transmission, contributing to a decrease in greenhouse gas emissions. This is particularly important in the context of global efforts to combat climate change and transition to cleaner energy sources. In conclusion, high conductivity is a fundamental property that underpins many technological advancements in our modern world. Its significance spans across various industries, from electronics to renewable energy. As we continue to innovate and discover new materials, the pursuit of high conductivity will remain a key focus, driving progress and sustainability in our society. Understanding and harnessing this property will undoubtedly pave the way for future breakthroughs that can enhance our quality of life and protect our planet.

在材料科学的世界中，理解不同物质的特性对技术进步至关重要。其中一个突出的特性是高导电性，它指的是材料有效传导电流或热量的能力。这一特性在电子产品到能源传输等各种应用中都是至关重要的。我们可以在日常设备中观察到高导电性的重要性，例如智能手机、笔记本电脑和电力线路。例如，铜和铝等金属以其卓越的高导电性而闻名，因此它们是电子设备中布线和组件的理想选择。某些材料之所以具有高导电性，原因在于它们的原子结构。在金属中，自由电子的存在使得电流能够轻易流动。当施加电压时，这些自由电子迅速移动，从而实现高效的能量转移。这就是为什么金属通常用于需要高导电性的电气应用。此外，对具有高导电性的材料的探索并不仅限于传统金属。研究人员不断探索新材料，例如石墨烯和碳纳米管，这些材料表现出更高的高导电性。这些材料有潜力通过使设备更快、更高效来彻底改变电子行业。例如，石墨烯是一种单层碳原子以二维晶格排列的材料，显示出非凡的高导电性特性，使其成为下一代晶体管和其他电子组件的候选材料。除了电子产品，高导电性在可再生能源技术中也发挥着重要作用。例如，太阳能电池板依赖于能够高效将阳光转化为电能的材料。某些半导体的高导电性提高了太阳能电池的性能，从而导致更好的能量转换率。同样，在能源储存领域，电池受益于具有高导电性的材料，以改善充放电速率，最终提高能源储存系统的整体效率。此外，高导电性的影响不仅限于效率；它们也影响可持续性。通过利用具有高导电性的材料，我们可以减少传输过程中的能量损失，从而有助于减少温室气体排放。这在全球努力应对气候变化和过渡到更清洁能源的背景下尤为重要。总之，高导电性是支撑我们现代世界许多技术进步的基本特性。它的重要性跨越多个行业，从电子产品到可再生能源。随着我们继续创新和发现新材料，追求高导电性将始终是一个关键焦点，推动我们社会的进步和可持续发展。理解和利用这一特性无疑将为未来的突破铺平道路，从而提升我们的生活质量并保护我们的星球。