cryotron

简明释义

英[ˈkraɪəˌtrɒn]美[ˈkraɪətrɑːn]

n. [电子] 冷子管；[电子] 低温管

英英释义

单词用法

同义词

反义词

例句

1.A laser pulse slicer with a cryotron high voltage pulse generator is reported.

本文报导由冷阴极闸流管产生高压脉冲的激光脉冲削波器。

2.A laser pulse slicer with a cryotron high voltage pulse generator is reported.

本文报导由冷阴极闸流管产生高压脉冲的激光脉冲削波器。

3.The research team developed a new type of quantum computer using a cryotron 低温电子开关 to enhance processing speed.

研究团队开发了一种新型量子计算机，使用了cryotron 低温电子开关 来提高处理速度。

4.In the lab, the scientists explained how the cryotron 低温电子开关 functions at extremely low temperatures.

在实验室里，科学家们解释了cryotron 低温电子开关 在极低温度下的工作原理。

5.The use of a cryotron 低温电子开关 can significantly reduce energy consumption in electronic devices.

使用cryotron 低温电子开关 可以显著减少电子设备的能耗。

6.Engineers are exploring the potential of cryotron 低温电子开关 technology for faster computing applications.

工程师们正在探索cryotron 低温电子开关 技术在更快计算应用中的潜力。

7.A cryotron 低温电子开关 operates by changing its state when cooled to superconducting temperatures.

cryotron 低温电子开关 通过在冷却到超导温度时改变其状态来工作。

作文

The world of technology is constantly evolving, and among the many innovations that have shaped modern computing, the cryotron stands out as a remarkable invention. A cryotron is a type of superconducting switch that operates at very low temperatures, typically below the critical temperature of superconductors. This unique characteristic allows it to conduct electricity without resistance, making it an efficient alternative to traditional electronic components. The history of the cryotron dates back to the 1960s when researchers were exploring the properties of superconductivity. The invention of the cryotron can be attributed to physicist Robert L. Smith, who demonstrated its potential in the realm of digital circuits. Unlike conventional transistors, which can generate heat and consume power, the cryotron operates with minimal energy loss, leading to faster processing speeds and improved performance. One of the most significant advantages of using a cryotron is its ability to function in extreme environments. For instance, space applications often require components that can withstand harsh conditions, including extreme temperatures and radiation. The cryotron excels in these situations, making it a valuable asset for aerospace engineering and satellite technology. Furthermore, the cryotron has implications beyond just computing. In the field of quantum computing, where researchers are striving to create faster and more powerful processors, the cryotron could play a crucial role. Its superconducting properties align well with the principles of quantum mechanics, potentially leading to breakthroughs in how we understand and manipulate information at the quantum level. Despite its advantages, the cryotron is not without challenges. The requirement for extremely low temperatures necessitates complex cooling systems, which can be costly and cumbersome. Additionally, the manufacturing process for cryotrons can be intricate, limiting their widespread adoption in consumer electronics. However, ongoing research aims to address these issues, paving the way for broader use of cryotrons in various industries. In conclusion, the cryotron is a fascinating example of how advancements in science and technology can lead to innovative solutions in computing and beyond. As researchers continue to explore its potential, we may witness a new era of high-performance electronics that harness the power of superconductivity. The future of the cryotron holds promise, and its impact on technology could be profound, changing the way we think about electronic devices and their capabilities.

科技的世界不断发展，在塑造现代计算机的众多创新中，cryotron作为一项卓越的发明脱颖而出。cryotron是一种超导开关，工作于非常低的温度，通常低于超导体的临界温度。这一独特特性使其能够无阻力地导电，成为传统电子元件的高效替代品。 cryotron的历史可以追溯到20世纪60年代，当时研究人员正在探索超导性的特性。cryotron的发明归功于物理学家罗伯特·L·史密斯，他展示了其在数字电路领域的潜力。与常规晶体管不同，后者会产生热量并消耗电能，cryotron以最小的能量损失运行，从而提高处理速度和性能。 使用cryotron的一个显著优势是其在极端环境中工作的能力。例如，太空应用通常需要能够承受恶劣条件的组件，包括极端温度和辐射。cryotron在这些情况下表现出色，使其成为航空工程和卫星技术中的宝贵资产。 此外，cryotron在量子计算领域也具有重要意义，研究人员正在努力创建更快、更强大的处理器，cryotron可能在其中发挥关键作用。其超导特性与量子力学的原理高度一致，可能导致我们对量子级别的信息理解和操控的突破。 尽管有诸多优势，cryotron也面临挑战。对极低温度的要求需要复杂的冷却系统，这可能既昂贵又笨重。此外，cryotron的制造过程可能复杂，限制了其在消费电子产品中的广泛应用。然而，持续的研究旨在解决这些问题，为cryotron在各个行业的更广泛使用铺平道路。 总之，cryotron是科学和技术进步如何在计算和其他领域提供创新解决方案的迷人例子。随着研究人员继续探索其潜力，我们可能会见证一个利用超导性力量的高性能电子设备的新纪元。cryotron的未来充满希望，其对技术的影响可能深远，改变我们对电子设备及其能力的思考。