shallow junction

简明释义

浅结

英英释义

例句

1.In the electrical circuit, a shallow junction 浅接头 can cause signal interference.

在电路中，浅接头 shallow junction 可能会导致信号干扰。

2.The engineer noted that the shallow junction 浅接头 could lead to water accumulation during heavy rains.

工程师指出，浅接头 shallow junction 在暴雨期间可能导致积水。

3.The shallow junction 浅接头 in the pipeline system requires frequent inspections to prevent leaks.

管道系统中的浅接头 shallow junction 需要定期检查以防止泄漏。

4.During the construction, they discovered a shallow junction 浅接头 that was not on the original plans.

在施工过程中，他们发现了一个不在原始计划中的浅接头 shallow junction。

5.They decided to reinforce the shallow junction 浅接头 to improve its durability under pressure.

他们决定加固浅接头 shallow junction 以提高其在压力下的耐久性。

作文

In the field of electrical engineering, various terms are used to describe different components and junctions within circuits. One such term that often comes up is shallow junction, which refers to a type of semiconductor junction that has a limited depth. This concept is crucial in understanding modern electronic devices, especially as technology continues to advance. A shallow junction is characterized by its ability to minimize the capacitance and improve the speed of operation, making it ideal for high-speed applications. The significance of a shallow junction can be observed in the development of integrated circuits (ICs). As ICs become smaller and more complex, the need for efficient junctions becomes paramount. A shallow junction allows for better control over the electrical properties of the device, leading to enhanced performance. For instance, in CMOS technology, which is widely used in microprocessors and memory chips, the incorporation of shallow junction designs helps reduce power consumption while maintaining high switching speeds. Moreover, the fabrication process of a shallow junction involves techniques such as ion implantation or diffusion, which allows for precise control over the doping concentration and profile. This precision is essential for ensuring that the junction operates effectively under various conditions. As devices are pushed towards miniaturization, the challenges associated with creating shallow junction structures also increase, necessitating continuous research and innovation in material science and engineering practices. In addition to their application in ICs, shallow junction technologies have implications in other areas such as solar cells and sensors. For example, in photovoltaic devices, a shallow junction can enhance the efficiency of light absorption and conversion, leading to more effective energy harvesting solutions. Similarly, in sensor applications, the sensitivity and response time can be significantly improved through the use of shallow junction designs. However, it is important to note that while shallow junction structures offer many advantages, they also come with certain limitations. The shallow depth can make them more susceptible to external factors such as thermal fluctuations and radiation, which may impact their reliability over time. Therefore, engineers must carefully consider the trade-offs when designing devices that utilize shallow junction technologies.In conclusion, the concept of shallow junction plays a vital role in the ongoing evolution of electronic devices. Its ability to enhance performance while reducing size and power consumption makes it a key focus area in research and development. As we move forward into an era of even more advanced technology, the importance of understanding and mastering the principles behind shallow junction will only continue to grow, shaping the future of electronics in profound ways.

在电气工程领域，各种术语用于描述电路中的不同组件和连接点。其中一个经常出现的术语是浅接合，它指的是一种深度有限的半导体接合。这一概念对于理解现代电子设备至关重要，尤其是在技术不断进步的背景下。浅接合的特点是能够最小化电容并提高操作速度，使其非常适合高速应用。浅接合的重要性可以在集成电路（IC）的发展中观察到。随着IC变得越来越小且复杂，对高效接合的需求变得至关重要。浅接合允许更好地控制器件的电气特性，从而提高性能。例如，在广泛用于微处理器和存储芯片的CMOS技术中，采用浅接合设计有助于在保持高切换速度的同时减少功耗。此外，浅接合的制造过程涉及离子注入或扩散等技术，这使得对掺杂浓度和分布的精确控制成为可能。这种精确性在确保接合在各种条件下有效运行方面至关重要。随着设备向微型化推进，与创建浅接合结构相关的挑战也在增加，这需要材料科学和工程实践领域的持续研究和创新。除了在IC中的应用外，浅接合技术在太阳能电池和传感器等其他领域也有影响。例如，在光伏设备中，浅接合可以提高光吸收和转换的效率，从而导致更有效的能源收集解决方案。同样，在传感器应用中，通过使用浅接合设计，可以显著提高灵敏度和响应时间。然而，需要注意的是，尽管浅接合结构提供了许多优点，但它们也存在某些局限性。浅层深度可能使其对外部因素（如热波动和辐射）更加敏感，这可能会影响其长期可靠性。因此，工程师在设计利用浅接合技术的设备时必须仔细考虑权衡。总之，浅接合的概念在电子设备的持续演变中发挥着至关重要的作用。它增强性能并减少尺寸和功耗的能力使其成为研究和开发的关键焦点。随着我们进入一个更加先进的技术时代，理解和掌握浅接合背后的原理的重要性只会继续增长，从而以深远的方式塑造电子产品的未来。