magnetic strength
简明释义
磁场强度
英英释义
The measure of the ability of a magnet to exert a magnetic force on objects, typically quantified in terms of magnetic field strength or magnetic flux density. | 磁铁对物体施加磁力的能力的度量,通常以磁场强度或磁通密度来量化。 |
例句
1.The lab experiment focused on increasing the magnetic strength of the superconducting material.
实验室实验集中在提高超导材料的磁强度。
2.As the distance from the magnet increased, the magnetic strength diminished significantly.
随着距离磁铁的增加,磁强度显著减弱。
3.Engineers often test the magnetic strength of materials used in aerospace applications.
工程师们通常测试用于航空航天应用的材料的磁强度。
4.A refrigerator magnet's magnetic strength determines how well it can hold notes on a metal surface.
冰箱磁铁的磁强度决定了它在金属表面上能多好地固定便条。
5.The scientist measured the magnetic strength of the new material to assess its suitability for use in electric motors.
科学家测量了新材料的磁强度以评估其在电动机中使用的适用性。
作文
Magnetic strength is a term that refers to the intensity of a magnetic field produced by a magnet or an electromagnet. This concept is crucial in various fields, including physics, engineering, and even medicine. Understanding the factors that influence magnetic strength (磁场强度) can lead to advancements in technology and improvements in everyday devices. In this essay, we will explore the significance of magnetic strength (磁场强度), its applications, and the principles behind it.To begin with, magnetic strength (磁场强度) is defined by several parameters, including the material of the magnet, its size, and the distance from the magnet. For instance, permanent magnets made from materials such as neodymium have a much higher magnetic strength (磁场强度) compared to traditional ferrite magnets. This is due to the unique properties of neodymium, which allows it to maintain a strong magnetic field over time. Electromagnets, on the other hand, generate magnetic strength (磁场强度) through electric current. The more coils of wire wrapped around a core and the higher the current flowing through them, the stronger the magnetic strength (磁场强度) becomes. This principle is widely utilized in devices such as electric motors, generators, and magnetic resonance imaging (MRI) machines.The applications of magnetic strength (磁场强度) are vast and varied. In the medical field, for example, MRI machines rely on powerful electromagnets to produce detailed images of the human body. The magnetic strength (磁场强度) in these machines is critical for achieving high-resolution images, allowing doctors to diagnose conditions accurately. Similarly, in the automotive industry, the magnetic strength (磁场强度) of magnets is essential for the functioning of electric vehicles, where they are used in motors and regenerative braking systems.Moreover, magnetic strength (磁场强度) plays a vital role in data storage technology. Hard drives and solid-state drives utilize magnetic fields to read and write data. The magnetic strength (磁场强度) of the materials used in these devices directly affects their efficiency and storage capacity. As technology advances, researchers are continually looking for ways to enhance magnetic strength (磁场强度) to improve data storage solutions.In conclusion, magnetic strength (磁场强度) is a fundamental concept that impacts numerous aspects of modern life. From medical imaging to data storage and electric vehicles, understanding and harnessing magnetic strength (磁场强度) is essential for technological progress. As we continue to explore the properties of magnets and electromagnets, the potential for innovation remains vast. By furthering our knowledge of magnetic strength (磁场强度), we can unlock new possibilities that may shape the future of technology and improve our daily lives.
磁场强度是一个术语,指的是由磁铁或电磁铁产生的磁场强度。这个概念在物理学、工程学甚至医学等多个领域都至关重要。理解影响磁场强度(magnetic strength)的因素可以促进技术进步和日常设备的改进。在这篇文章中,我们将探讨磁场强度(magnetic strength)的重要性、应用以及其背后的原理。首先,磁场强度(magnetic strength)由多个参数定义,包括磁铁的材料、大小以及与磁铁的距离。例如,由钕材料制成的永久磁铁相比传统的铁氧体磁铁具有更高的磁场强度(magnetic strength)。这是由于钕的独特性质,使其能够长时间维持强大的磁场。另一方面,电磁铁通过电流产生磁场强度(magnetic strength)。缠绕在核心上的线圈越多,流过它们的电流越高,磁场强度(magnetic strength)就越强。这一原理广泛应用于电动机、发电机和磁共振成像(MRI)机器等设备。磁场强度(magnetic strength)的应用范围广泛而多样。例如,在医疗领域,MRI机器依赖强大的电磁铁生成人体的详细图像。此类机器中的磁场强度(magnetic strength)对获得高分辨率图像至关重要,从而使医生能够准确诊断病症。同样,在汽车工业中,磁铁的磁场强度(magnetic strength)对于电动车的运作至关重要,它们被用于电动机和再生制动系统。此外,磁场强度(magnetic strength)在数据存储技术中也起着重要作用。硬盘和固态硬盘利用磁场来读取和写入数据。存储设备中所用材料的磁场强度(magnetic strength)直接影响其效率和存储容量。随着技术的进步,研究人员不断寻找增强磁场强度(magnetic strength)的方法,以改进数据存储解决方案。总之,磁场强度(magnetic strength)是一个基本概念,影响着现代生活的多个方面。从医学成像到数据存储和电动车,理解和利用磁场强度(magnetic strength)对于技术进步至关重要。随着我们继续探索磁铁和电磁铁的性能,创新的潜力仍然巨大。通过进一步了解磁场强度(magnetic strength),我们可以解锁新的可能性,这可能会塑造技术的未来并改善我们的日常生活。
相关单词
