semiconducting

简明释义

英[ˌsemɪkənˈdʌktɪŋ]美[ˌsemɪkənˈdʌktɪŋ;ˌsemaɪkənˈdʌ

adj. 半导体的；有半导体特性的

英英释义

单词用法

同义词

反义词

例句

1.A transistor needs to be completely semiconducting to hold information, Tour says.

图尔表示，晶体管必须是纯粹的半导体才能传载信息。

2.Conducting tubes are used in wires and electrodes but semiconducting tubes are the active material for transistors or solar cells.

导电管用于电线和电极中，用于晶体管或太阳能电池中的半导体管采用了活性材料。

3.The electron conduction mechanism of semiconducting ceramic oxide with perovskite structure was also explained further.

对钙钛矿结构氧化物半导体陶瓷中的电子导电机制，也作了进一步的阐明。

4.And when the mixture is used for semiconducting, as in a transistor, the excess current from the conducting nanotubes will short the device.

当这种混合用在一个半导体晶体管中，来自半导体管过大的电流将损坏器件。

5.The base electrode (3) is a metal layer deposited on top of the semiconducting material forming the first electrode.

基极电极(3)是沉积在形成第一电极的半导体材料上面的金属层。

6.Their patented technology is based on inks containing tiny, semiconducting nanocrystals, which can be printed directly onto a variety of surfaces.

他们的这项专利技术基于印刷生产所使用的墨汁。这些墨汁含有微小的半导体纳米晶，可以直接印刷在各种物体的表面。

7.The semiconducting 半导体 properties of gallium arsenide make it ideal for high-frequency applications.

砷化镓的半导体特性使其非常适合高频应用。

8.Advancements in semiconducting 半导体 technology are crucial for the development of faster computers.

在半导体技术方面的进步对更快计算机的发展至关重要。

9.Researchers are exploring new semiconducting 半导体 materials for more efficient solar cells.

研究人员正在探索新的半导体材料，以制造更高效的太阳能电池。

10.The semiconducting 半导体 layer in transistors controls the flow of electrical current.

晶体管中的半导体层控制电流的流动。

11.Silicon is a widely used material in the production of semiconducting 半导体 devices.

硅是生产半导体设备中广泛使用的材料。

作文

In the modern world, technology plays a crucial role in our daily lives, and one of the key components that enable this technology to function is the concept of semiconducting. The term semiconducting refers to materials that have electrical conductivity between that of a conductor and an insulator. This unique property makes semiconducting materials essential for various electronic devices, including transistors, diodes, and solar cells. Understanding the principles behind semiconducting materials can help us appreciate the technological advancements we often take for granted.The most commonly used semiconducting material is silicon, which is abundant in nature and relatively inexpensive to produce. Silicon's semiconducting properties allow it to be manipulated in ways that can enhance its conductivity. By adding impurities to silicon through a process called doping, we can create n-type and p-type semiconductors. N-type semiconductors have extra electrons, while p-type semiconductors have holes or missing electrons. The interaction between these two types of semiconducting materials is what allows transistors to control electrical signals, thereby forming the basis of modern computing.In addition to silicon, other materials like gallium arsenide and germanium also exhibit semiconducting properties and are used in specialized applications. Gallium arsenide, for instance, is known for its high efficiency in converting electricity into light, making it ideal for use in laser diodes and high-frequency applications. This diversity in semiconducting materials highlights the importance of research and development in the field of electronics, as scientists continuously explore new compounds that could lead to even better performance and efficiency.The impact of semiconducting technology extends beyond consumer electronics. In the renewable energy sector, semiconducting materials are critical for the development of photovoltaic cells, which convert sunlight into electricity. As the world shifts towards more sustainable energy sources, the role of semiconducting materials in solar technology becomes increasingly significant. Innovations in semiconducting materials can lead to higher efficiency rates in solar panels, making renewable energy more accessible and cost-effective.Moreover, the future of semiconducting technology is promising with the rise of quantum computing. Researchers are investigating semiconducting materials that can operate at room temperature and maintain quantum states for longer periods, potentially leading to breakthroughs in processing power and speed. This could revolutionize industries ranging from healthcare to finance, allowing for faster data analysis and improved algorithms.In conclusion, the concept of semiconducting is fundamental to our understanding of modern electronics and technology. From the everyday devices we use to the advancements in renewable energy and quantum computing, semiconducting materials play a pivotal role in shaping our future. As we continue to explore the potential of these materials, it is clear that semiconducting technology will remain at the forefront of innovation, driving progress across various fields. Embracing and understanding the significance of semiconducting materials will not only enhance our appreciation for technology but also inspire future generations to push the boundaries of what is possible.

在现代世界中，技术在我们的日常生活中发挥着至关重要的作用，而使这些技术能够正常运行的关键组成部分之一就是“半导体”这一概念。术语“半导体”指的是电导率介于导体和绝缘体之间的材料。这种独特的特性使得半导体材料对各种电子设备至关重要，包括晶体管、二极管和太阳能电池。理解半导体材料背后的原理可以帮助我们欣赏我们常常视为理所当然的技术进步。最常用的半导体材料是硅，这种材料在自然界中丰富且相对便宜。硅的半导体特性使其能够以多种方式进行处理，从而增强其导电性。通过一种称为掺杂的过程向硅中添加杂质，我们可以制造出n型和p型半导体。n型半导体具有多余的电子，而p型半导体则具有空穴或缺失的电子。这两种类型的半导体材料之间的相互作用使得晶体管能够控制电信号，从而形成现代计算的基础。除了硅，其他材料如砷化镓和锗也表现出半导体特性，并用于专业应用。例如，砷化镓以其将电转化为光的高效率而闻名，使其非常适合用于激光二极管和高频应用。这种半导体材料的多样性突显了电子领域研究与开发的重要性，因为科学家们不断探索新的化合物，以期实现更好的性能和效率。半导体技术的影响超越了消费电子产品。在可再生能源领域，半导体材料对于光伏电池的发展至关重要，这些电池将阳光转化为电力。随着世界向更可持续的能源来源转变，半导体材料在太阳能技术中的作用变得越来越重要。半导体材料的创新可以提高太阳能电池板的效率，使可再生能源更加可及和经济。此外，随着量子计算的兴起，半导体技术的未来充满希望。研究人员正在调查能够在室温下操作并保持量子状态更长时间的半导体材料，这可能会在处理能力和速度上带来突破。这可能会彻底改变从医疗保健到金融等各个行业，允许更快的数据分析和改进的算法。总之，半导体的概念是我们理解现代电子和技术的基础。从我们使用的日常设备到可再生能源和量子计算的进步，半导体材料在塑造我们未来方面发挥着关键作用。随着我们继续探索这些材料的潜力，很明显，半导体技术将继续处于创新的前沿，推动各个领域的进步。拥抱和理解半导体材料的重要性不仅会增强我们对技术的欣赏，还会激励未来几代人突破可能的界限。