crystalline semiconductor

简明释义

晶体半导体

英英释义

例句

1.The manufacturing process of crystalline semiconductors 晶体半导体 requires precise control of temperature and pressure.

制造晶体半导体 crystalline semiconductors的过程需要精确控制温度和压力。

2.In high-performance computing, crystalline semiconductors 晶体半导体 are essential for creating faster processors.

在高性能计算中，晶体半导体 crystalline semiconductors对于创建更快的处理器至关重要。

3.The performance of the solar cells improved significantly when using crystalline semiconductor 晶体半导体 materials.

当使用晶体半导体 crystalline semiconductor材料时，太阳能电池的性能显著提高。

4.The crystalline semiconductor 晶体半导体 used in LED lights offers better light quality compared to amorphous types.

用于LED灯的晶体半导体 crystalline semiconductor相比非晶类型提供更好的光质量。

5.Researchers are exploring new ways to enhance the efficiency of crystalline semiconductors 晶体半导体 in electronic devices.

研究人员正在探索提高电子设备中晶体半导体 crystalline semiconductors效率的新方法。

作文

In the world of electronics, the term crystalline semiconductor refers to a type of material that has a well-defined and ordered atomic structure. This characteristic is crucial for the efficient functioning of electronic devices. Semiconductors are materials that have electrical conductivity between that of a conductor and an insulator. The crystalline semiconductor structure allows for better control of electrical properties, which is essential in the manufacturing of various electronic components such as diodes, transistors, and integrated circuits.The significance of crystalline semiconductors can be observed in everyday technology. For instance, silicon, one of the most commonly used crystalline semiconductors, is the backbone of modern electronics. Its ability to form a crystalline structure allows it to effectively conduct electricity when doped with certain impurities, thus creating p-type or n-type semiconductors. This property is exploited in the production of computer chips, solar cells, and many other electronic devices.One of the primary advantages of using crystalline semiconductors is their superior performance compared to amorphous semiconductors. In crystalline semiconductors, the ordered arrangement of atoms leads to fewer defects and a higher mobility of charge carriers, which enhances the efficiency of electronic devices. This is particularly important in applications where speed and reliability are critical, such as in high-frequency communication systems.Moreover, the research and development of new crystalline semiconductor materials are ongoing, with scientists exploring alternatives to silicon. Materials like gallium nitride (GaN) and indium phosphide (InP) are being investigated for their potential in high-power and high-frequency applications. These materials offer advantages such as wider band gaps, which allow them to operate at higher voltages and temperatures, making them suitable for advanced electronic applications.The impact of crystalline semiconductors on the global economy cannot be overstated. The semiconductor industry is a multi-billion dollar sector that drives innovation and technological advancement. The demand for faster, smaller, and more energy-efficient electronic devices continues to grow, pushing researchers and manufacturers to explore new crystalline semiconductor technologies. This has led to significant investments in semiconductor research and development, fostering collaboration between academia and industry.In conclusion, the role of crystalline semiconductors in modern electronics is pivotal. Their unique properties enable the creation of efficient and reliable electronic devices that are integral to our daily lives. As technology continues to evolve, the exploration of new crystalline semiconductor materials will play a crucial role in shaping the future of electronics, paving the way for innovations that we have yet to imagine. Understanding the importance of crystalline semiconductors is essential for anyone interested in the field of electronics and technology, as they are at the heart of the devices that power our world.

在电子学的世界里，术语晶体半导体指的是一种具有明确且有序原子结构的材料。这一特性对于电子设备的高效运行至关重要。半导体是电导率介于导体和绝缘体之间的材料。晶体半导体的结构允许更好地控制电气特性，这在制造二极管、晶体管和集成电路等各种电子元件中是必不可少的。晶体半导体的重要性可以在日常技术中观察到。例如，硅是最常用的晶体半导体之一，是现代电子产品的支柱。它形成晶体结构的能力使其在掺入某些杂质后能够有效导电，从而创造出p型或n型半导体。这一特性被用于计算机芯片、太阳能电池和许多其他电子设备的生产。使用晶体半导体的主要优势之一是其性能优于非晶半导体。在晶体半导体中，原子的有序排列导致缺陷更少，载流子的迁移率更高，从而增强了电子设备的效率。这在速度和可靠性至关重要的应用中尤为重要，例如在高频通信系统中。此外，新的晶体半导体材料的研究与开发正在进行中，科学家们正在探索替代硅的材料。氮化镓（GaN）和磷化铟（InP）等材料因其在高功率和高频应用中的潜力而受到关注。这些材料提供了更宽的带隙，使其能够在更高的电压和温度下工作，适合于先进的电子应用。晶体半导体对全球经济的影响不可低估。半导体产业是一个数十亿美元的行业，推动着创新和技术进步。对更快、更小和更节能电子设备的需求持续增长，促使研究人员和制造商探索新的晶体半导体技术。这导致了对半导体研发的重大投资，促进了学术界与工业界之间的合作。总之，晶体半导体在现代电子学中的作用至关重要。它们独特的特性使得创建高效且可靠的电子设备成为可能，这些设备是我们日常生活中不可或缺的一部分。随着技术的不断发展，新晶体半导体材料的探索将对塑造电子学的未来发挥关键作用，为我们尚未想象的创新铺平道路。理解晶体半导体的重要性对于任何对电子学和技术感兴趣的人来说都是至关重要的，因为它们是驱动我们世界的设备的核心。