photonic

简明释义

英[fəʊˈtɒnɪk]美[,foʊ'tɑnɪk]

adj. 光激性的

英英释义

单词用法

同义词

反义词

例句

1.The photonic chip, built by scientists from Bristol's Centre for Quantum Photonics, USES light rather than electricity to pass information.

由布里斯托尔大学量子光学中心的科学家制造的光子芯片可以利用光而不是用电来传递信息。

2.Then, it describes the technological advances of optical fiber transmission and photonic devices and integration which are needed by the all-optical network.

接着说明全光同所根据的光纤传输系统和光子器件与集成技术的进展。

3.Communication with the Tao however requires mastery of gold and silver or photonic thought-form to understand.

然而，要和道交流则需要掌握金银或者光子的思想形态以对其理解。

4.Then, it describes the technological advances of optical fiber transmission and photonic devices and integration which are needed by the all-optical network.

接着说明全光同所根据的光纤传输系统和光子器件与集成技术的进展。

5.The researchers have invented a novel "photonic molecule" system in which a semiconductor quantum dot emits a pair of entangled photons per excitation pulse.

研究人员发明了一种新型“光子分子”系统，其中半导体量子点在每个激励脉冲都会发出一对纠缠光子。

6.In a photonic crystal the elements are about the same size as the wavelength of light-a few hundred nanometres (billionths of a metre).

在光子晶体中，其成分与光的波长是同样的大小——几百纳米(一米的十亿分之一)。

7.Each level of increasing photonic energy allows for the biological changes inherent in ascension to grow at a more rapid pace for all species upon earth.

所增长光子能的每个水准，允许地球上全部物种在提升中所固有的生物变化以更快幅度成长。

8.The silicon photonic chips could replace the electronic connections between a computer's key components, such as its processors and memory.

这种硅晶光学集成电路能够代替计算机关键模块之间，比如处理器和内存之间，的电子连接器。

9.In the field of medicine, photonic 光子 imaging techniques are improving diagnostic accuracy.

在医学领域，光子成像技术提高了诊断的准确性。

10.The new photonic 光子 devices are more energy-efficient than their electronic counterparts.

新的光子设备比其电子对应物更节能。

11.Researchers are exploring photonic 光子 circuits for faster data processing.

研究人员正在探索光子电路以实现更快的数据处理。

12.The development of photonic 光子 technologies is revolutionizing communication systems.

光子技术的发展正在彻底改变通信系统。

13.The photonic 光子 sensors can detect minute changes in environmental conditions.

光子传感器可以检测环境条件的微小变化。

作文

In recent years, the field of technology has seen a significant shift towards the utilization of light-based systems. This transition is largely attributed to advancements in the field of photonic (光子学) technologies, which harness the properties of photons to improve various applications ranging from telecommunications to medical devices. The term photonic (光子学) refers to the science and technology of generating, manipulating, and detecting photons, particularly in the visible and near-infrared spectrum. This fascinating area of study has opened up new avenues for innovation and efficiency.One of the most notable applications of photonic (光子学) technology is in the realm of telecommunications. Fiber optic cables, which rely on photonic (光子学) principles, have revolutionized the way data is transmitted over long distances. By using light to carry information, these cables can transmit data at incredibly high speeds and with minimal loss. This advancement has made it possible for us to enjoy high-speed internet and seamless communication across the globe.Moreover, photonic (光子学) technologies are also making strides in the field of medicine. One exciting development is the use of photonic (光子学) sensors for early disease detection. These sensors can detect changes in light patterns caused by biological processes, allowing for non-invasive diagnostics that can identify diseases at their earliest stages. This capability not only enhances patient outcomes but also reduces the need for invasive procedures, making healthcare more efficient and accessible.The potential of photonic (光子学) technologies extends beyond telecommunications and medicine. In manufacturing, photonic (光子学) lasers are being used for precision cutting and welding, enabling the production of complex components with high accuracy. Additionally, photonic (光子学) devices are being integrated into consumer electronics, leading to lighter, faster, and more energy-efficient products.Despite the numerous advantages of photonic (光子学) technologies, there are still challenges to overcome. One major hurdle is the need for further research and development to enhance the efficiency and scalability of photonic (光子学) systems. As we continue to explore this promising field, it is essential to invest in education and training to cultivate a workforce skilled in photonic (光子学) applications.In conclusion, the rise of photonic (光子学) technologies marks a pivotal moment in our technological evolution. From improving communication to transforming healthcare and manufacturing, the impact of photonic (光子学) innovations is profound. As we move forward, embracing the potential of photonic (光子学) systems will be crucial in addressing the challenges of the future and unlocking new possibilities for society. It is an exciting time to be involved in this field, as the discoveries made today will shape the world of tomorrow.

近年来，科技领域经历了向光基系统利用的重大转变。这一转变主要归功于光子学技术的进步，这些技术利用光子的特性来改善从电信到医疗设备的各种应用。术语“photonic（光子学）”指的是生成、操控和检测光子的科学和技术，特别是在可见光和近红外光谱中。这一迷人的研究领域为创新和效率开辟了新的途径。光子学技术最显著的应用之一是在电信领域。光纤电缆依赖于光子学原理，彻底改变了数据在长距离上传输的方式。通过使用光来携带信息，这些电缆能够以极高的速度和最小的损失传输数据。这一进步使我们能够享受高速互联网和无缝的全球通信。此外，光子学技术在医学领域也取得了进展。一项令人兴奋的发展是使用光子学传感器进行早期疾病检测。这些传感器可以检测由生物过程引起的光模式变化，从而实现非侵入性诊断，可以在疾病的早期阶段识别疾病。这种能力不仅提高了患者的结果，还减少了对侵入性程序的需求，使医疗保健更加高效和可及。光子学技术的潜力超越了电信和医学。在制造业中，光子学激光被用于精密切割和焊接，使得复杂组件的生产具有高精度。此外，光子学设备正被集成到消费电子产品中，导致更轻、更快和更节能的产品。尽管光子学技术有许多优势，但仍然存在需要克服的挑战。其中一个主要障碍是需要进一步研究和开发，以提高光子学系统的效率和可扩展性。随着我们继续探索这一有前景的领域，投资教育和培训以培养熟练掌握光子学应用的劳动力至关重要。总之，光子学技术的崛起标志着我们技术演变的关键时刻。从改善通信到改变医疗和制造，光子学创新的影响深远。随着我们向前迈进，拥抱光子学系统的潜力对于应对未来的挑战和解锁社会的新可能性至关重要。现在是参与这一领域的激动人心的时刻，因为今天所做的发现将塑造明天的世界。