indium oxide

简明释义

氧化铟

英英释义

例句

1.Scientists are exploring the use of indium oxide (铟氧化物) in gas sensors for better sensitivity.

科学家们正在探索在气体传感器中使用indium oxide (铟氧化物)以提高灵敏度。

2.In solar cells, indium oxide (铟氧化物) is often used as a transparent conductive layer.

在太阳能电池中，indium oxide (铟氧化物)通常用作透明导电层。

3.The researchers discovered that adding indium oxide (铟氧化物) improved the conductivity of the material.

研究人员发现，添加indium oxide (铟氧化物)可以提高材料的导电性。

4.The coating on the display screen contains indium oxide (铟氧化物) to enhance its performance.

显示屏上的涂层包含indium oxide (铟氧化物)，以增强其性能。

5.The electronic device's efficiency was boosted by integrating indium oxide (铟氧化物) into its circuitry.

通过将indium oxide (铟氧化物)集成到电路中，电子设备的效率得到了提升。

作文

Indium oxide, represented by the chemical formula In2O3, is a compound that has garnered significant attention in various fields of research and technology. This compound is primarily known for its unique properties, including its high transparency to visible light and excellent electrical conductivity. These characteristics make indium oxide (铟氧化物) an essential material in the production of transparent conductive films, which are crucial for applications in touch screens, solar cells, and flat-panel displays. The importance of indium oxide (铟氧化物) can be traced back to its role in the electronics industry. As the demand for thinner and more efficient electronic devices increases, manufacturers are constantly seeking materials that can provide both conductivity and transparency. Indium oxide (铟氧化物) fits this need perfectly, allowing for the development of advanced technologies such as organic light-emitting diodes (OLEDs) and liquid crystal displays (LCDs). In addition to its optical and electrical properties, indium oxide (铟氧化物) also exhibits interesting thermal and chemical stability. This stability makes it suitable for high-temperature applications, where other materials might fail. Researchers have been exploring the use of indium oxide (铟氧化物) in gas sensors, where its ability to detect various gases can lead to improved safety and environmental monitoring systems. Furthermore, the synthesis of indium oxide (铟氧化物) can be achieved through various methods, including chemical vapor deposition (CVD) and sol-gel processes. These methods allow for the control of the material's properties, such as grain size and morphology, which can significantly impact its performance in applications. The versatility of indium oxide (铟氧化物) in terms of fabrication techniques makes it a popular choice among researchers and engineers alike. Despite its many advantages, there are challenges associated with the use of indium oxide (铟氧化物). One of the primary concerns is related to the availability of indium, a rare metal that is primarily obtained as a byproduct of zinc mining. As the demand for indium oxide (铟氧化物) continues to grow, there are increasing calls for sustainable practices in the sourcing and recycling of indium. Researchers are actively investigating alternative materials and methods to reduce reliance on indium, which could lead to more sustainable technologies in the future. In conclusion, indium oxide (铟氧化物) is a remarkable compound that plays a critical role in modern technology. Its unique combination of optical, electrical, and thermal properties makes it an invaluable material in various applications, from electronics to environmental monitoring. As research continues to advance, the potential for indium oxide (铟氧化物) to contribute to innovative solutions is vast, although addressing sustainability challenges will be essential for its continued use in the future.