periodic permanent-magnetic

简明释义

周期永磁聚焦

英英释义

例句

1.Engineers are developing periodic permanent-magnetic 周期性永磁体 solutions for advanced robotic systems.

工程师们正在为先进的机器人系统开发周期性永磁体解决方案。

2.In the latest research, scientists explored the benefits of periodic permanent-magnetic 周期性永磁体 materials in renewable energy applications.

在最新的研究中，科学家探讨了周期性永磁体材料在可再生能源应用中的好处。

3.The periodic permanent-magnetic 周期性永磁体 arrangement in this generator improves its power output significantly.

这个发电机中的周期性永磁体排列显著提高了其功率输出。

4.The design of the motor incorporates a periodic permanent-magnetic 周期性永磁体 system to enhance efficiency.

该电机的设计采用了一个周期性永磁体系统，以提高效率。

5.The application of periodic permanent-magnetic 周期性永磁体 technology in electric vehicles is gaining traction.

在电动车中应用周期性永磁体技术正越来越受到关注。

作文

In the realm of modern technology, the term periodic permanent-magnetic plays a pivotal role in various applications, particularly in the field of electrical engineering and materials science. To fully comprehend the significance of this phrase, it is essential to break it down into its components: 'periodic', 'permanent', and 'magnetic'. The word 'periodic' refers to something that occurs at regular intervals or is characterized by a repeating pattern. This concept is crucial in understanding how certain materials can exhibit magnetic properties over time. For instance, materials that display periodic magnetic behavior can be utilized in creating efficient magnetic fields that enhance the performance of electronic devices.The term 'permanent' indicates that the magnetic properties of a material are stable and do not diminish over time. Unlike temporary magnets, which lose their magnetism when an external magnetic field is removed, periodic permanent-magnetic materials retain their magnetic characteristics indefinitely. This stability is vital for applications such as electric motors, generators, and magnetic storage devices, where consistent performance is required.Finally, 'magnetic' pertains to the property of attracting or repelling certain materials, typically metals like iron, cobalt, and nickel. The interaction between these materials and magnetic fields is fundamental to numerous technological advancements. Understanding how periodic permanent-magnetic materials function allows engineers to innovate and improve existing technologies.One of the most significant applications of periodic permanent-magnetic materials is in the design of permanent magnets used in various devices. For example, in electric motors, these magnets are crucial for converting electrical energy into mechanical energy. The periodic arrangement of magnetic domains within these materials enhances their efficiency and effectiveness, leading to better performance and reduced energy consumption.Moreover, periodic permanent-magnetic materials are also instrumental in the development of magnetic resonance imaging (MRI) machines. The stable magnetic fields generated by these materials allow for high-resolution imaging of internal body structures, which is essential for accurate medical diagnoses. The periodic nature of the magnetic fields helps in achieving uniformity and consistency in the imaging process, thus improving the quality of the results.In addition to these applications, research continues to explore new ways to utilize periodic permanent-magnetic materials in emerging technologies. For instance, advancements in quantum computing and renewable energy sources are likely to benefit from the unique properties of these materials. By harnessing their stable magnetic characteristics, scientists aim to develop more efficient systems that can operate under a variety of conditions.In conclusion, the phrase periodic permanent-magnetic encompasses a range of concepts that are integral to understanding modern technological applications. By recognizing the importance of periodicity, permanence, and magnetism, we can appreciate the role these materials play in enhancing our daily lives and driving innovation across multiple industries. As technology continues to evolve, the study and application of periodic permanent-magnetic materials will undoubtedly remain at the forefront of scientific research and development, paving the way for future advancements that could revolutionize the way we interact with the world around us.

在现代科技领域，术语周期性永磁在各种应用中扮演着关键角色，特别是在电气工程和材料科学领域。要充分理解这个短语的重要性，必须将其分解为三个部分：'周期性'、'永磁'和'磁性'。'周期性'一词指的是某种事物以规律的间隔发生或具有重复的模式。这一概念对于理解某些材料如何随着时间表现出磁性特性至关重要。例如，显示出周期性磁性行为的材料可用于创建高效的磁场，从而提高电子设备的性能。'永磁'一词表示材料的磁性特性是稳定的，并且不会随着时间的推移而减弱。与临时磁铁不同，后者在去除外部磁场时会失去其磁性，而周期性永磁材料则可以无限期地保持其磁性特征。这种稳定性对于电动机、发电机和磁存储设备等应用至关重要，因为这些应用需要一致的性能。最后，'磁性'涉及到吸引或排斥某些材料（通常是铁、钴和镍等金属）的属性。这些材料与磁场之间的相互作用是众多技术进步的基础。理解周期性永磁材料的功能使工程师能够创新和改善现有技术。周期性永磁材料最重要的应用之一是设计用于各种设备的永磁体。例如，在电动机中，这些磁体对将电能转化为机械能至关重要。这些材料内部磁畴的周期性排列增强了它们的效率和有效性，导致更好的性能和降低的能耗。此外，周期性永磁材料在磁共振成像（MRI）机器的发展中也发挥着重要作用。这些材料生成的稳定磁场允许对内部身体结构进行高分辨率成像，这对于准确的医学诊断至关重要。磁场的周期性特征有助于在成像过程中实现均匀性和一致性，从而提高结果的质量。除了这些应用，研究还在继续探索在新兴技术中利用周期性永磁材料的新方法。例如，量子计算和可再生能源领域的进步可能会受益于这些材料的独特特性。通过利用其稳定的磁性特征，科学家们旨在开发出能够在各种条件下运行的更高效的系统。总之，短语周期性永磁包含了一系列概念，这些概念对于理解现代技术应用至关重要。通过认识到周期性、永恒性和磁性的重要性，我们可以欣赏这些材料在提升我们日常生活和推动多个行业创新方面所发挥的作用。随着技术的不断发展，周期性永磁材料的研究和应用无疑将继续处于科学研究和发展的前沿，为未来的进步铺平道路，这些进步可能会彻底改变我们与周围世界的互动方式。