microelectronic

简明释义

英[ˌmaɪkrəʊɪˌlekˈtrɒnɪk]美[ˌmaɪkroʊɪˌlekˈtrɑːnɪk]

adj. [电子] 微电子的

英英释义

单词用法

同义词

反义词

例句

1.This paper describes a fabrication technology of metal tip field emission arrays (FEA) for the vacuum microelectronic devices.

本文介绍了真空微电子器件场发射金属尖阵列阴极的制备工艺技术。

2.The ultra high pure hydrogen peroxide is one of the critical chemical materials for wet chemical process in the microelectronic industry.

超高纯过氧化氢试剂是微电子材料加工必需的关键电子化学品。

3.Semiconductor silicon is the most fundamental material for the microelectronic industry.

半导体硅材料是微电子产业的基础材料。

4.Microchannel heat sink is a promising technique to dissipate high heat flux microelectronic chips in the near future.

微通道热沉是解决高热流密度微电子芯片散热的一种有效途径。

5.It is an urgent demand of new generation packaging materials with excellent properties in the microelectronic industry.

微电子行业迫切需要新一代优异性能的封装材料。

6.The application prospect of the transparent and conducting polyaniline films in optoelectronic and microelectronic devices is forecasted.

展望了透明导电聚苯胺薄膜在光电器件和微电子器件领域的应用前景。

7.A process for the fabrication of Si cone cathode for the build up of vacuum microelectronic devices is proposed and its experimental results are given.

本文介绍了利用半导体硅材料制作的真空微电子器件的核心部件，场致发射硅锥阴极，的工艺研究及实验结果。

8.Information society is on the base of microelectronic industry that is built on the semiconductor silicon material.

微电子是信息社会的基础，而半导体硅材料则是微电子的支柱。

9.In the microelectronic packaging, the reliability of the solder joint has been being a forward position and a hot topic.

电子封装中的的焊点可靠性问题一直是电子封装中学科的前沿和热点问题。

10.The development of 微电子 devices has revolutionized the technology industry.

微电子设备的发展彻底改变了技术行业。

11.Many modern gadgets rely on 微电子 components to function effectively.

许多现代小工具依赖于微电子组件才能有效运作。

12.Engineers are constantly innovating in the field of 微电子 engineering.

工程师们在微电子工程领域不断创新。

13.The 微电子 industry is crucial for advancements in telecommunications.

微电子产业对电信领域的进步至关重要。

14.A career in 微电子 design can be very rewarding.

从事微电子设计的职业可以非常有回报。

作文

In today's rapidly advancing technological landscape, the field of microelectronic (微电子学) engineering plays a crucial role in shaping our daily lives. From smartphones to sophisticated medical devices, microelectronic (微电子学) components are at the heart of modern electronics, enabling functionalities that were once thought impossible. The development of microelectronic (微电子学) circuits has revolutionized industries by allowing for smaller, faster, and more efficient devices. This essay will explore the significance of microelectronic (微电子学), its applications, and its impact on society. To begin with, microelectronic (微电子学) technology is essential for miniaturizing electronic components. The ability to fabricate tiny transistors on silicon wafers has led to the creation of integrated circuits (ICs), which are fundamental to virtually all electronic devices. These ICs consist of millions, or even billions, of transistors packed into a single chip, allowing for complex functionalities in a compact form factor. As a result, products like smartphones, laptops, and wearable technology have become more powerful while maintaining portability. Moreover, the influence of microelectronic (微电子学) engineering extends beyond consumer electronics. In the medical field, microelectronic (微电子学) devices such as pacemakers and diagnostic equipment play a vital role in improving patient care. For instance, implantable devices can monitor vital signs and deliver medication, significantly enhancing the quality of life for patients with chronic conditions. Additionally, advancements in microelectronic (微电子学) technology have facilitated the development of telemedicine, allowing healthcare providers to remotely monitor and treat patients. The automotive industry has also benefited tremendously from microelectronic (微电子学) innovations. Modern vehicles are equipped with numerous microelectronic (微电子学) systems that enhance safety, efficiency, and comfort. Features such as anti-lock braking systems (ABS), adaptive cruise control, and infotainment systems rely on microelectronic (微电子学) circuits to function effectively. As we move toward an era of autonomous driving, the demand for advanced microelectronic (微电子学) components will only continue to grow. Furthermore, microelectronic (微电子学) technology is integral to the advancement of artificial intelligence (AI). AI algorithms require significant computational power, which is made possible through microelectronic (微电子学) hardware such as graphics processing units (GPUs) and specialized chips designed for machine learning. These technologies enable faster data processing and analysis, paving the way for smarter applications across various sectors, including finance, healthcare, and entertainment. Despite its many benefits, the field of microelectronic (微电子学) also faces challenges. The ongoing miniaturization of components raises concerns about heat dissipation and energy efficiency. As devices become smaller, managing power consumption becomes increasingly critical. Engineers and researchers are continuously exploring new materials and designs to overcome these obstacles and ensure the sustainability of microelectronic (微电子学) technology. In conclusion, the field of microelectronic (微电子学) engineering is pivotal in driving technological innovation and enhancing our quality of life. Its applications span across various industries, from consumer electronics to healthcare and automotive. As we continue to push the boundaries of what is possible with microelectronic (微电子学) technology, it is essential to address the challenges that arise and strive for sustainable solutions. The future of microelectronic (微电子学) holds immense potential, and its impact on society will undoubtedly be profound as we move forward into an increasingly interconnected world.

在当今快速发展的技术领域，微电子学工程在塑造我们的日常生活中发挥着至关重要的作用。从智能手机到复杂的医疗设备，微电子学组件是现代电子产品的核心，使曾经被认为不可能实现的功能成为可能。微电子学电路的发展彻底改变了各行各业，使得设备更小、更快、更高效。本文将探讨微电子学的重要性、应用及其对社会的影响。 首先，微电子学技术对于电子元件的小型化至关重要。在硅片上制造微小晶体管的能力促成了集成电路（IC）的创造，而这些电路是几乎所有电子设备的基础。这些IC由数百万甚至数十亿个晶体管组成，紧密集成在一个芯片中，使得复杂的功能可以在紧凑的形态中实现。因此，像智能手机、笔记本电脑和可穿戴技术这样的产品变得更强大，同时保持了便携性。 此外，微电子学工程的影响超越了消费电子领域。在医疗领域，微电子学设备如心脏起搏器和诊断设备在改善患者护理方面发挥着重要作用。例如，植入式设备可以监测生命体征并投放药物，大大提高了慢性病患者的生活质量。此外，微电子学技术的进步促进了远程医疗的发展，使医疗提供者能够远程监测和治疗患者。 汽车行业也因微电子学创新而受益匪浅。现代车辆配备了许多依赖于微电子学系统的安全、效率和舒适性特性。诸如防抱死刹车系统（ABS）、自适应巡航控制和信息娱乐系统等功能都依赖于微电子学电路的有效运作。随着我们迈向自动驾驶时代，对先进微电子学组件的需求只会继续增长。 此外，微电子学技术对于人工智能（AI）的发展至关重要。AI算法需要大量的计算能力，而这通过微电子学硬件如图形处理单元（GPU）和专为机器学习设计的专用芯片得以实现。这些技术使得数据处理和分析速度更快，为金融、医疗和娱乐等多个领域的更智能应用铺平了道路。 尽管有许多好处，微电子学领域也面临挑战。组件的持续小型化引发了热散失和能效问题。随着设备变得越来越小，管理功耗变得越来越关键。工程师和研究人员正在不断探索新材料和设计，以克服这些障碍，并确保微电子学技术的可持续性。 总之，微电子学工程领域在推动技术创新和提升我们的生活质量方面至关重要。它的应用遍及各个行业，从消费电子到医疗和汽车。随着我们继续推动微电子学技术的可能性边界，有必要解决出现的挑战并努力寻求可持续的解决方案。微电子学的未来蕴藏着巨大的潜力，其对社会的影响无疑将在我们走向一个日益互联的世界时变得深远。