photonics

简明释义

英[fəʊˈtɒnɪks]美[foʊˈtɑːnɪks]

n. 光电；光子学

英英释义

单词用法

同义词

反义词

例句

1.The research appears in the journal Nature Photonics.

这项研究发现刊登在《自然光学》杂志上。

2.The design and synthesis of photonics polymers with given properties to satisfy the special requirements are the key task of this area.

设计和合成具有特定性质以满足特定要求的聚合物结构是其中最受关注的课题之一。

3.Defect structures of solid state materials and their photonics applications.

光电材料的缺陷结构及其光子学应用。

4.Design and fabrication of Photonics devices.

光子学器件设计与制备。

5.In the 20th century, traditional optics was striding forward to the modern optics, and photonics and its technology forced open its doorway.

20世纪，传统光学迈向现代光学，光子学和光子技术破门而出。

6.Photon-tissue interactions and photo-biomedical detection are the hotspots of current biomedical photonics research.

光子与生物组织的相互作用和光生物医学检测是当前生物医学光子学的研究热点。

7.Xi'an OE Photonics Co. , Ltd. , located at the export processing zone of Xi'an northern suburbs, is one hi-tech enterprise engaging in optical technology.

西安欧益光电科技有限公司坐落于西安北郊的出口加工区，是立足于光学技术的高新技术企业。

8.The field of photonics is revolutionizing communication technology.

光子学photonics领域正在彻底改变通信技术。

9.Researchers are exploring new materials to enhance photonics applications.

研究人员正在探索新材料以增强photonics应用。

10.Companies are investing heavily in photonics research to stay competitive.

公司正在大力投资于photonics研究以保持竞争力。

11.In medicine, photonics is used for advanced imaging techniques.

在医学中，photonics用于先进的成像技术。

12.The development of photonics devices has led to faster internet speeds.

光子设备的开发导致了更快的互联网速度。

作文

In the modern world, technology plays a crucial role in our daily lives, and one of the most fascinating fields that has emerged is photonics. 光子学 is the science and technology of generating, manipulating, and detecting photons, which are particles of light. This field encompasses a wide range of applications, from telecommunications to medical devices, and even environmental monitoring. Understanding photonics is essential for appreciating how it impacts various sectors and improves our quality of life.One of the most significant contributions of photonics is in the realm of communication technology. Optical fibers, which rely on the principles of photonics, have revolutionized how we transmit data over long distances. Unlike traditional copper wires, optical fibers use light to carry information, resulting in faster speeds and higher bandwidth. This advancement has made the internet more accessible and efficient, enabling seamless communication across the globe. As we continue to rely on digital connectivity, the importance of photonics cannot be overstated.Moreover, photonics plays a vital role in the medical field. Techniques such as laser surgery, endoscopy, and optical imaging have transformed patient care and diagnosis. For instance, lasers can precisely target tissues without damaging surrounding areas, leading to quicker recovery times and better outcomes. Additionally, optical imaging technologies allow for non-invasive examinations, improving early detection of diseases like cancer. The integration of photonics in healthcare demonstrates its potential to save lives and enhance medical practices.Environmental monitoring is another area where photonics shows great promise. Sensors based on photonics can detect pollutants in the air and water with high sensitivity and accuracy. This capability is crucial for maintaining public health and ensuring environmental sustainability. By utilizing light for detection, these sensors can provide real-time data, allowing for immediate responses to hazardous situations. As global awareness of environmental issues grows, the role of photonics in monitoring and addressing these challenges becomes increasingly important.Furthermore, the field of photonics is continuously evolving, with research and innovation driving new discoveries. Emerging technologies, such as quantum photonics, aim to harness the unique properties of light for advanced computing and secure communication. Quantum photonics could lead to breakthroughs in information processing, making systems faster and more secure than ever before. This ongoing research highlights the dynamic nature of photonics and its potential to shape the future.In conclusion, photonics is a pivotal field that influences numerous aspects of our lives. From enhancing communication systems to advancing medical technologies and supporting environmental initiatives, photonics has proven its significance in modern society. As we continue to explore the capabilities of light and its applications, it is essential to recognize and support the growth of this remarkable discipline. Embracing the advancements in photonics will undoubtedly lead us towards a brighter and more innovative future.

在现代世界中，技术在我们的日常生活中扮演着至关重要的角色，而出现的最迷人的领域之一就是光子学。光子学是生成、操纵和检测光子（光的粒子）的科学和技术。这个领域涵盖了广泛的应用，从电信到医疗设备，甚至环境监测。理解光子学对于欣赏它如何影响各个行业以及改善我们的生活质量至关重要。光子学的一个重要贡献是在通信技术领域。光纤依赖于光子学的原理，彻底改变了我们如何远距离传输数据。与传统的铜线不同，光纤使用光来传递信息，从而实现更快的速度和更高的带宽。这一进步使互联网变得更加可及和高效，能够实现全球无缝通信。随着我们继续依赖数字连接，光子学的重要性不容小觑。此外，光子学在医疗领域也发挥着至关重要的作用。激光手术、内窥镜检查和光学成像等技术已经改变了患者护理和诊断。例如，激光可以精确地靶向组织，而不会损害周围区域，从而导致更快的恢复时间和更好的结果。此外，光学成像技术允许进行非侵入性检查，提高了癌症等疾病的早期发现率。光子学在医疗中的整合展示了其拯救生命和增强医疗实践的潜力。环境监测是光子学展现巨大前景的另一个领域。基于光子学的传感器可以以高灵敏度和准确性检测空气和水中的污染物。这种能力对于维护公共健康和确保环境可持续性至关重要。通过利用光进行检测，这些传感器可以提供实时数据，使得对危险情况的及时响应成为可能。随着全球对环境问题的关注加剧，光子学在监测和应对这些挑战中的作用变得越来越重要。此外，光子学领域正在不断发展，研究和创新推动着新的发现。量子光子学等新兴技术旨在利用光的独特性质进行先进的计算和安全通信。量子光子学可能会导致信息处理方面的突破，使系统比以往任何时候都更快、更安全。这项持续的研究突显了光子学的动态特性及其塑造未来的潜力。总之，光子学是一个关键领域，影响着我们生活的诸多方面。从增强通信系统到推动医疗技术发展，再到支持环境倡议，光子学在现代社会中证明了其重要性。随着我们继续探索光的能力及其应用，认识到并支持这一杰出学科的发展至关重要。拥抱光子学的进步无疑将引领我们走向一个更加光明和创新的未来。