magnetics
简明释义
n. [电磁] 磁学
英英释义
The branch of physics that deals with the study of magnetic fields and their effects on matter. | 研究磁场及其对物质影响的物理学分支。 |
与磁性相关的特性或现象。 |
单词用法
磁场 | |
磁共振;磁谐振 |
同义词
反义词
| 电 | 电力对于为设备供电至关重要。 | ||
| 非磁性 | Materials that are non-magnetic do not respond to magnetic fields. | 非磁性材料对磁场没有反应。 |
例句
1.Kate magnetics would like to sincerely for your service, is willing to do your best matching suppliers.
凯特磁材愿真诚为您服务,愿做您最佳的配套供应商。
2.In this paper the measurement methods based on optics, acoustics, magnetics and radiology are mentioned for research of mesomechanics.
本文以应用较多的光测技术为主,综述了细观力学测量中光、声、磁、射线等试验技术。
3.The Gyrator-Capacitor model is first introduced to modeling two-phase integrating magnetics Voltage Regulator Module(VRM), which can deduce the corresponding self-inductance and mutual inductance.
文章首先利用回转器-电容模型对两相电压调整模块进行建模研究,并推导出具体的磁集成自感和互感表达式;
4.By integrating the main transformer and output inductor with magnetics integration technique, an ACFC with high efficiency and high power density was obtained.
对变换器中的主变压器和输出电感进行集成,得到高效率、高功率密度的有源箝位正激变换器。
5.It is important that the theoretical study works of electricity, magnetics and optics for conducting polymer materials.
研究导电高分子材料的电学、磁学和光学等方面的理论日显重要。
6.A novel method of coupling magnetics, acoustics and electrics is presented to measure neural currents.
提出了一种基于磁声电相互耦合的神经电流检测方法。
7.The status, role and research contents for high-frequency magnetics technology in power electronics are discussed.
论述了高频磁技术在现代电力电子技术中的地位、作用、研究内容及其发展趋势。
8.This should tell you something else because of the physics of magnetics.
因为这个磁力物理,还可以告诉你们其它的一些事。
9.RRI's product line includes high performance gradient and shim coils, high stability shim power supplies, gradient amplifiers, magnetic field management and consulting on magnetics.
RRI的产品线包括高性能梯度和填充线圈,高稳定性电源,梯度放大器,磁场管理和电磁学咨询。
10.In the field of engineering, understanding magnetics (磁学) is crucial for designing efficient motors.
在工程领域,理解magnetics(磁学)对设计高效电动机至关重要。
11.The study of magnetics (磁学) helps in developing new technologies for data storage.
对magnetics(磁学)的研究有助于开发新的数据存储技术。
12.The principles of magnetics (磁学) are applied in creating magnetic levitation trains.
在制造磁悬浮列车时应用了magnetics(磁学)的原理。
13.Many medical devices rely on magnetics (磁学) to function properly, such as MRI machines.
许多医疗设备依赖于magnetics(磁学)才能正常工作,例如MRI机器。
14.Research in magnetics (磁学) can lead to breakthroughs in renewable energy technologies.
在magnetics(磁学)方面的研究可能会导致可再生能源技术的突破。
作文
Magnetics is a fascinating field of study that delves into the properties and behaviors of magnetic materials and their interactions with electric currents. This discipline plays a crucial role in various technological advancements, from electric motors to data storage devices. Understanding the principles of magnetics (磁学) allows us to harness the power of magnetism for practical applications that improve our daily lives.The basic concept of magnetics (磁学) revolves around the idea that certain materials can produce magnetic fields, which are invisible forces that can attract or repel other magnetic materials. These materials are classified as ferromagnetic, paramagnetic, or diamagnetic, each exhibiting unique magnetic properties. For instance, iron is a ferromagnetic material, meaning it can be magnetized and retain its magnetic properties over time. This characteristic is essential in the manufacturing of permanent magnets used in various devices.One of the most significant applications of magnetics (磁学) is in the development of electric motors. Electric motors convert electrical energy into mechanical energy through the interaction of magnetic fields. By understanding how magnetics (磁学) works, engineers can design more efficient motors that consume less energy and produce more power. This innovation has led to advancements in transportation, such as electric vehicles, which are becoming increasingly popular due to their environmental benefits.Another important application of magnetics (磁学) is in the field of data storage. Hard drives and solid-state drives rely on magnetic materials to store information. The ability to manipulate magnetic fields allows data to be written and erased efficiently. As technology evolves, the demand for faster and more reliable data storage solutions continues to grow, making the study of magnetics (磁学) even more relevant.Furthermore, magnetics (磁学) is also crucial in medical technology. Magnetic Resonance Imaging (MRI) is a widely used diagnostic tool that employs strong magnetic fields and radio waves to create detailed images of the body's internal structures. The principles of magnetics (磁学) enable healthcare professionals to visualize organs and tissues non-invasively, leading to better diagnosis and treatment plans.In addition to these applications, magnetics (磁学) is also involved in emerging technologies such as quantum computing. Quantum computers utilize the principles of quantum mechanics and magnetics (磁学) to perform calculations at unprecedented speeds. Researchers are exploring how magnetic materials can be used to create qubits, the building blocks of quantum computers, which could revolutionize the way we process information.In conclusion, the study of magnetics (磁学) is essential for understanding and advancing various technologies that shape our world today. From electric motors to data storage and medical imaging, the applications of magnetics (磁学) are vast and impactful. As we continue to explore the potential of this field, we will likely uncover new innovations that enhance our lives and drive progress in numerous industries. Therefore, investing time in learning about magnetics (磁学) is not only beneficial for students and professionals in science and engineering but also for anyone interested in the future of technology.
磁学是一个迷人的研究领域,深入探讨了磁性材料的特性和行为,以及它们与电流的相互作用。这个学科在各种技术进步中扮演着至关重要的角色,从电动机到数据存储设备。理解磁学(magnetics)的原理使我们能够利用磁力进行实际应用,从而改善我们的日常生活。磁学(magnetics)的基本概念围绕着某些材料能够产生磁场的理念,这些磁场是看不见的力量,可以吸引或排斥其他磁性材料。这些材料被分类为铁磁性、顺磁性或抗磁性,每种材料都表现出独特的磁性特性。例如,铁是一种铁磁性材料,意味着它可以被磁化并保留其磁性特性。这一特征在制造用于各种设备的永久磁铁时至关重要。磁学(magnetics)最重要的应用之一是在电动机的开发中。电动机通过磁场的相互作用将电能转化为机械能。通过理解磁学(magnetics)的工作原理,工程师可以设计出更高效的电动机,消耗更少的能量并产生更多的功率。这一创新推动了交通运输的发展,例如电动车,由于其环境效益,越来越受到欢迎。磁学(magnetics)在数据存储领域也是一个重要的应用。硬盘和固态硬盘依赖于磁性材料来存储信息。操控磁场的能力使得数据能够高效地写入和擦除。随着技术的发展,对更快、更可靠的数据存储解决方案的需求持续增长,使得磁学(magnetics)的研究变得更加相关。此外,磁学(magnetics)在医疗技术中也至关重要。磁共振成像(MRI)是一种广泛使用的诊断工具,利用强大的磁场和无线电波创建身体内部结构的详细图像。磁学(magnetics)原理使得医疗专业人员能够非侵入性地可视化器官和组织,从而制定更好的诊断和治疗计划。除了这些应用,磁学(magnetics)还涉及到量子计算等新兴技术。量子计算机利用量子力学和磁学(magnetics)原理以空前的速度进行计算。研究人员正在探索如何利用磁性材料来创建量子比特,这是量子计算机的基本构建块,这可能会彻底改变我们处理信息的方式。总之,磁学(magnetics)的研究对于理解和推进塑造我们今天世界的各种技术至关重要。从电动机到数据存储和医学成像,磁学(magnetics)的应用广泛且影响深远。随着我们继续探索这一领域的潜力,我们可能会发现新的创新,提升我们的生活并推动众多行业的进步。因此,花时间学习磁学(magnetics)不仅对科学和工程领域的学生和专业人士有益,而且对任何对未来技术感兴趣的人都是有益的。
