resistive material

简明释义

电阻材料

英英释义

例句

1.Conductive inks often contain a resistive material (电阻材料) to achieve specific electrical properties.

导电墨水通常含有resistive material（电阻材料），以实现特定的电气性能。

2.In electronic circuits, using a resistive material (电阻材料) helps control the flow of current.

在电子电路中，使用resistive material（电阻材料）有助于控制电流的流动。

3.When designing sensors, engineers often choose a resistive material (电阻材料) that can accurately measure changes in resistance.

在设计传感器时，工程师通常选择一种可以准确测量电阻变化的resistive material（电阻材料）。

4.The heating element in toasters is made from a resistive material (电阻材料) that generates heat when electricity passes through it.

烤面包机中的加热元件由一种resistive material（电阻材料）制成，当电流通过时会产生热量。

5.The resistive material (电阻材料) used in this application must withstand high temperatures without degrading.

在这个应用中使用的resistive material（电阻材料）必须能够承受高温而不降解。

作文

In the world of electronics and materials science, the term resistive material refers to substances that resist the flow of electric current. These materials are essential in various applications, including resistors, heating elements, and sensors. Understanding the properties and applications of resistive materials is crucial for engineers and scientists working in these fields. One of the most common examples of a resistive material is carbon. Carbon-based materials, such as graphite, have been used for decades in electronic components due to their ability to conduct electricity while also providing resistance. This unique combination allows them to be effective in regulating current flow in circuits. Additionally, materials like nickel-chromium alloys are often used in heating elements because they can withstand high temperatures while maintaining their resistive properties. The resistance of a resistive material is measured in ohms, and this value can vary depending on several factors, including temperature, length, and cross-sectional area of the material. For instance, as the temperature increases, the resistance of most metals will also increase, which is an important consideration in circuit design. Engineers must select appropriate resistive materials that can operate within the desired temperature range without failing or altering their resistance characteristics significantly. In addition to traditional applications, resistive materials are also being explored in the field of renewable energy. For example, materials with specific resistive properties can be utilized in solar cells to improve efficiency. By carefully selecting and engineering these materials, researchers aim to enhance the performance of photovoltaic devices, making solar energy more viable and accessible.Furthermore, the development of new resistive materials is a hot topic in nanotechnology. Researchers are investigating nanostructured materials that exhibit unique resistive properties at the nanoscale. These materials could lead to the creation of smaller, more efficient electronic devices and systems. For example, incorporating nanomaterials into the design of resistors could allow for more compact designs without compromising performance. In conclusion, the study of resistive materials is vital for advancing technology in various sectors, from consumer electronics to renewable energy solutions. As our understanding of these materials continues to grow, we can expect to see innovative applications that leverage their unique properties. Whether in everyday devices or cutting-edge technologies, resistive materials play a crucial role in shaping the future of electronics and energy systems.

在电子和材料科学的世界中，短语电阻材料指的是那些抵抗电流流动的物质。这些材料在各种应用中至关重要，包括电阻器、加热元件和传感器。理解电阻材料的性质和应用对从事这些领域的工程师和科学家至关重要。最常见的电阻材料之一是碳。基于碳的材料，如石墨，因其能够导电同时又能提供电阻而被使用了数十年。这种独特的组合使它们在电路中有效调节电流流动。此外，镍铬合金等材料常用于加热元件，因为它们能够承受高温，同时保持其电阻特性。电阻材料的电阻以欧姆为单位测量，这个值会根据多个因素而变化，包括温度、材料的长度和横截面积。例如，随着温度的升高，大多数金属的电阻也会增加，这是电路设计中的一个重要考虑因素。工程师必须选择适当的电阻材料，以便在所需的温度范围内运行，而不会发生故障或显著改变其电阻特性。除了传统应用外，电阻材料在可再生能源领域也受到关注。例如，具有特定电阻特性的材料可以用于太阳能电池，以提高效率。通过精心选择和工程化这些材料，研究人员旨在增强光伏设备的性能，使太阳能更加可行和可获取。此外，新型电阻材料的开发在纳米技术领域也是一个热门话题。研究人员正在研究在纳米尺度上表现出独特电阻特性的纳米结构材料。这些材料可能导致更小、更高效的电子设备和系统的创建。例如，将纳米材料纳入电阻器的设计中，可以在不妥协性能的情况下实现更紧凑的设计。总之，研究电阻材料对于推动各个行业技术的进步至关重要，从消费电子到可再生能源解决方案。随着我们对这些材料的理解不断加深，我们可以期待看到利用其独特特性的创新应用。无论是在日常设备中还是在尖端技术中，电阻材料在塑造电子和能源系统的未来中扮演着关键角色。