antimonide
简明释义
英[ˈæntɪməˌnaɪd]美[ˈæntəməˌnaɪd]
n. 锑化物
英英释义
A compound formed by the combination of antimony with another element, typically a metal. | 由锑与另一种元素(通常是金属)结合形成的化合物。 |
单词用法
锑化物半导体 | |
锑化物化合物 | |
金属锑化物 | |
锑化物材料 |
同义词
| 锑矿 | Stibnite is a naturally occurring mineral that is a source of antimony. | 锑矿是一种天然矿物,是锑的来源。 | |
| 锑化合物 | Antimony compounds are used in flame retardants and lead-acid batteries. | 锑化合物用于阻燃剂和铅酸电池中。 |
反义词
| 催化剂 | 催化剂加速了化学反应。 | ||
| 氧化剂 | 氧化剂在燃烧过程中是必不可少的。 |
例句
1.The paper presented a new method for sample treatment in semiconductor indium antimonide single crystal dislocation display, and proveded of feasibility this method with large number experiments.
本文提出了半导体锑化铟单晶位错显示中对样品处理的一种新方法,并通过大量的实验证实了这种方法的可行性。
2.To meet the needs of high electron current density photocathodes, the processes for preparing cesium antimonide have been studied.
为满足大电流密度电子发射的需要,对锑铯光电阴极的制备工艺进行了研究。
3.The paper presented a new method for sample treatment in semiconductor indium antimonide single crystal dislocation display, and proveded of feasibility this method with large number experiments.
本文提出了半导体锑化铟单晶位错显示中对样品处理的一种新方法,并通过大量的实验证实了这种方法的可行性。
4.When the battery is being charged, magnesium antimonide in the middle layer breaks down into the pure elements and so the upper and lower layers deepen.
当电池正在充电,在中间层的组合物分解成纯元素,所以上下层变得更厚了。
5.In the field of thermoelectrics, antimonide alloys are known for their excellent performance.
在热电领域,锑化物合金以其优异的性能而闻名。
6.The semiconductor industry often uses materials like gallium antimonide to create high-performance devices.
半导体行业通常使用像镓锑化物这样的材料来制造高性能设备。
7.The fabrication of high-speed transistors often involves the use of antimonide semiconductors.
高速度晶体管的制造通常涉及使用锑化物半导体。
8.Researchers are studying the properties of antimonide compounds for potential applications in infrared detectors.
研究人员正在研究锑化物化合物的特性,以期在红外探测器中应用。
9.The efficiency of solar cells can be improved by incorporating antimonide materials.
通过加入锑化物材料,可以提高太阳能电池的效率。
作文
Antimonides are a fascinating class of compounds that have garnered significant attention in the fields of materials science and semiconductor technology. These compounds, which consist of antimony combined with other elements, exhibit unique properties that make them suitable for various applications. For instance, the most common type of antimonide (反铟化物) is formed when antimony is combined with metals such as gallium or indium. This combination results in materials that possess excellent electrical conductivity and can be used in high-performance electronic devices.One of the key characteristics of antimonides (反铟化物) is their ability to form a crystal structure that allows for efficient electron movement. This property is crucial in the development of semiconductors, where the flow of electrons is essential for the functioning of electronic components. Researchers are constantly exploring new ways to synthesize and manipulate antimonide (反铟化物) materials to enhance their performance and broaden their applications.In addition to their electrical properties, antimonides (反铟化物) also exhibit interesting thermal characteristics. Some antimonide (反铟化物) compounds are known for their thermoelectric properties, which allow them to convert temperature differences into electrical voltage. This makes them ideal candidates for applications in energy harvesting and refrigeration technologies. For example, devices made from antimonides (反铟化物) can be used to capture waste heat from industrial processes and convert it into usable energy, thereby improving overall energy efficiency.Furthermore, the use of antimonides (反铟化物) in optoelectronic devices has been a topic of great interest among scientists and engineers. These materials can be used to create lasers, photodetectors, and light-emitting diodes (LEDs) that operate at specific wavelengths. The tunability of antimonide (反铟化物) compounds allows for the development of devices that can be tailored to meet the demands of various applications, ranging from telecommunications to medical imaging.Despite the promising potential of antimonides (反铟化物), there are still challenges that researchers face in this field. One significant issue is the stability of these compounds under different environmental conditions. Understanding how antimonides (反铟化物) behave when exposed to moisture, temperature fluctuations, and other factors is crucial for their practical application. Ongoing research aims to address these challenges by developing more robust materials and exploring new synthesis techniques.In conclusion, antimonides (反铟化物) represent a vital area of study within materials science. Their unique properties and versatility make them valuable for a wide range of applications, from electronics to energy harvesting and optoelectronics. As research continues to advance, we can expect to see even more innovative uses for antimonides (反铟化物) in the future, paving the way for new technologies that can significantly impact our daily lives. The ongoing exploration of these compounds not only enhances our understanding of material properties but also contributes to the development of sustainable solutions for modern challenges.
