ovonics

简明释义

英[əʊˈvɒnɪks]美[oʊˈvɑnɪks]

n. [电子]交流控制半导体元件；[电子]双向开关半导体器件（ovonic 的复数）

英英释义

单词用法

同义词

反义词

例句

1.Eventually Stanford Ovshinsky, an American inventor, and his company, now known as ECD Ovonics, succeeded in creating metal-hydride alloys with a disordered structure that improved performance.

最终美国发明家Stanford Ovshinsky与他的公司ECD Ovonics成功地制备了随机结构的金属氢合金，实现了性能改良。

2.Eventually Stanford Ovshinsky, an American inventor, and his company, now known as ECD Ovonics, succeeded in creating metal-hydride alloys with a disordered structure that improved performance.

最终美国发明家Stanford Ovshinsky与他的公司ECD Ovonics成功地制备了随机结构的金属氢合金，实现了性能改良。

3.The research team is exploring new applications of ovonics in solar energy technology.

研究团队正在探索光电学在太阳能技术中的新应用。

4.Many universities have started courses focusing on ovonics to prepare students for careers in renewable energy.

许多大学开设了专注于光电学的课程，以为学生准备可再生能源领域的职业。

5.The latest advancements in ovonics could lead to more efficient battery technologies.

最新的光电学进展可能会导致更高效的电池技术。

6.Companies are investing heavily in ovonics research to stay competitive in the market.

公司在光电学研究上投入巨资，以保持市场竞争力。

7.The conference featured several presentations on the future of ovonics in electronics.

会议上有几场关于光电学在电子学中未来的演讲。

作文

Ovonics is a fascinating field that combines the principles of optics and electronics to create innovative materials and devices. The term itself is derived from the combination of 'optics' and 'electronics', and it primarily focuses on the development of materials that exhibit unique electrical and optical properties. One of the most significant contributions of ovonics (光电学) is in the area of thin-film technologies, which have revolutionized various industries, including solar energy, display technologies, and data storage. In recent years, the demand for renewable energy sources has surged due to growing concerns about climate change and the depletion of fossil fuels. Ovonics (光电学) plays a crucial role in this transition by enabling the creation of efficient photovoltaic cells that convert sunlight into electricity. These cells are made from materials that can absorb a wide spectrum of light, allowing them to generate more power than traditional solar panels. As a result, the adoption of ovonics (光电学) technologies in solar energy has the potential to significantly reduce our carbon footprint and promote sustainable living. Moreover, the impact of ovonics (光电学) extends beyond renewable energy. In the realm of display technologies, advancements in ovonics (光电学) have led to the development of organic light-emitting diodes (OLEDs). These displays are thinner, lighter, and more energy-efficient compared to conventional LCD screens. The vibrant colors and improved contrast ratios of OLEDs have made them the preferred choice for high-end televisions and smartphones. This shift towards ovonics (光电学) in display technology not only enhances user experience but also contributes to energy savings in consumer electronics. Another exciting application of ovonics (光电学) is in data storage. Researchers have been exploring the use of phase-change materials that change their state when subjected to heat or electricity. These materials can be used in rewritable optical discs, offering higher data storage capacities and faster read/write speeds. The integration of ovonics (光电学) principles in data storage solutions is paving the way for next-generation memory devices that can handle the ever-increasing need for data in our digital world. Despite its numerous benefits, the field of ovonics (光电学) is still evolving, and there are challenges to overcome. For instance, the scalability of manufacturing processes for ovonics (光电学) materials needs to be addressed to meet the growing market demands. Additionally, researchers are continuously working on improving the stability and longevity of these materials to ensure their practical applications in everyday life. In conclusion, ovonics (光电学) represents a promising intersection of optics and electronics that holds the key to many technological advancements. From renewable energy solutions to cutting-edge display technologies and innovative data storage methods, the influence of ovonics (光电学) is far-reaching. As we continue to explore and develop this field, we can expect to see even more groundbreaking innovations that will shape the future of technology and contribute to a sustainable world.

光电学是一个迷人的领域，它结合了光学和电子学的原理，以创造创新的材料和设备。这个术语本身来源于“光学”和“电子学”的结合，主要集中在开发具有独特电气和光学特性的材料上。光电学的一个重要贡献是在薄膜技术领域，这场技术革命改变了包括太阳能、显示技术和数据存储等多个行业。 近年来，由于对气候变化和化石燃料枯竭的日益关注，可再生能源的需求激增。光电学在这一转型中发挥着关键作用，使得高效光伏电池的创造成为可能，这些电池能够将阳光转化为电能。这些电池由能够吸收广泛光谱的材料制成，使其能够产生比传统太阳能电池板更多的电力。因此，采用光电学技术的太阳能有可能显著减少我们的碳足迹，促进可持续生活。 此外，光电学的影响不仅限于可再生能源。在显示技术领域，光电学的进步导致了有机发光二极管（OLED）的发展。这些显示器比传统的LCD屏幕更薄、更轻且更节能。OLED的鲜艳色彩和改进的对比度使其成为高端电视和智能手机的首选。这种向光电学的转变不仅增强了用户体验，还为消费电子产品的节能做出了贡献。 光电学的另一个令人兴奋的应用是在数据存储方面。研究人员一直在探索使用相变材料，这些材料在受到热或电的影响时会改变状态。这些材料可以用于可重写的光盘，提供更高的数据存储容量和更快的读写速度。在数据存储解决方案中整合光电学原理正在为下一代内存设备铺平道路，这些设备能够应对我们数字世界中日益增长的数据需求。 尽管有许多好处，光电学领域仍在不断发展，并面临挑战。例如，需要解决光电学材料制造过程的可扩展性问题，以满足日益增长的市场需求。此外，研究人员还在不断努力改善这些材料的稳定性和耐久性，以确保它们在日常生活中的实际应用。 总之，光电学代表了光学和电子学的有希望的交汇点，掌握着许多技术进步的关键。从可再生能源解决方案到尖端显示技术和创新的数据存储方法，光电学的影响远及各个领域。随着我们继续探索和发展这一领域，我们可以期待看到更多突破性的创新，这些创新将塑造未来的技术并为可持续世界做出贡献。