residual magnetization

简明释义

剩余磁化

英英释义

例句

1.The process of demagnetization is essential to reduce residual magnetization 剩余磁化 in electric motors after maintenance.

在电机维护后，去磁过程对于减少剩余磁化 剩余磁化至关重要。

2.High levels of residual magnetization 剩余磁化 can lead to inaccuracies in measurement devices.

高水平的剩余磁化 剩余磁化可能导致测量设备的不准确。

3.Engineers must account for residual magnetization 剩余磁化 when designing magnetic sensors.

工程师在设计磁传感器时必须考虑到剩余磁化 剩余磁化。

4.The study focused on the effects of residual magnetization 剩余磁化 in ferromagnetic materials.

该研究集中在铁磁材料中的剩余磁化 剩余磁化的影响。

5.To ensure optimal performance, it's crucial to minimize residual magnetization 剩余磁化 in transformers.

为了确保最佳性能，减少变压器中的剩余磁化 剩余磁化至关重要。

作文

Residual magnetization is a phenomenon observed in ferromagnetic materials, where a material retains some magnetization even after an external magnetic field is removed. This property is significant in various fields, including electronics, data storage, and magnetic materials research. Understanding residual magnetization (剩余磁化) is crucial for engineers and scientists who work with magnetic materials.When a ferromagnetic material, such as iron, is exposed to a magnetic field, the domains within the material align in the direction of the field. Once the external field is removed, some of these domains remain aligned, leading to a permanent magnetization known as residual magnetization (剩余磁化). This retained magnetization can be beneficial or detrimental, depending on the application. For instance, in magnetic storage devices, residual magnetization (剩余磁化) is utilized to store data. However, in certain electronic components, it can lead to interference and performance issues.The measurement of residual magnetization (剩余磁化) is typically done using techniques like vibrating sample magnetometry or superconducting quantum interference devices (SQUID). These methods allow researchers to quantify the amount of residual magnetization present in a sample, which is essential for understanding its magnetic properties and potential applications. The ability to control and manipulate residual magnetization (剩余磁化) is also important in the development of new materials and technologies.In the context of environmental science, residual magnetization (剩余磁化) has been used in paleomagnetism to study the Earth's magnetic field over geological time scales. By examining the residual magnetization (剩余磁化) of rocks, scientists can infer information about the history of the Earth's magnetic field, plate tectonics, and even climate changes. This interdisciplinary approach highlights the importance of residual magnetization (剩余磁化) beyond just materials science.Moreover, the concept of residual magnetization (剩余磁化) is also relevant in the field of magnetic therapy, where practitioners use magnets to promote healing. While the scientific community remains divided on the efficacy of such treatments, the underlying principle of residual magnetization (剩余磁化) plays a role in how these therapies are believed to work.In conclusion, residual magnetization (剩余磁化) is a fundamental concept in magnetism that has far-reaching implications across various disciplines. Its ability to retain magnetization after the removal of an external magnetic field opens up numerous possibilities in technology, environmental science, and even alternative medicine. As research continues, a deeper understanding of residual magnetization (剩余磁化) will likely lead to innovative applications and advancements in both theoretical and applied physics.