cross magnetization

简明释义

正交磁化

英英释义

例句

1.During the simulation, we observed cross magnetization that affected the overall magnetic field strength.

在模拟过程中，我们观察到交叉磁化影响了整体磁场强度。

2.To mitigate the effects of cross magnetization, engineers applied specific shielding techniques.

为了减轻交叉磁化的影响，工程师们应用了特定的屏蔽技术。

3.The research team studied cross magnetization effects in magnetic materials to improve data storage technologies.

研究小组研究了磁性材料中的交叉磁化效应，以改善数据存储技术。

4.In electrical engineering, understanding cross magnetization is crucial for designing efficient transformers.

在电气工程中，理解交叉磁化对设计高效的变压器至关重要。

5.The phenomenon of cross magnetization occurs when magnetic fields interact with each other, leading to unexpected results in the experiment.

当磁场相互作用时，会出现交叉磁化现象，这导致实验中产生意想不到的结果。

作文

In the realm of physics and engineering, particularly in the study of magnetic fields, the term cross magnetization refers to a phenomenon where the magnetic properties of a material are influenced by external magnetic fields in a direction that is perpendicular to the primary magnetization direction. This concept is crucial for understanding how materials respond to complex magnetic environments, especially in applications such as electric motors, transformers, and magnetic storage devices.The significance of cross magnetization can be observed in various practical scenarios. For instance, in electric motors, when a magnetic field is applied, it is not uncommon for the resulting magnetization to have components in multiple directions. This can lead to inefficiencies in motor performance due to unintended energy losses caused by the misalignment of magnetic fields. Understanding and mitigating the effects of cross magnetization is essential for engineers who design more efficient systems.Moreover, cross magnetization plays a vital role in the field of magnetic resonance imaging (MRI). In MRI machines, the precise manipulation of magnetic fields is necessary to obtain clear and accurate images of the human body. If cross magnetization is not properly accounted for, it can result in artifacts or distortions in the images, leading to misdiagnosis or overlooked medical conditions. Therefore, medical physicists must have a deep understanding of this phenomenon to ensure the reliability of MRI technology.In addition to its applications in engineering and medicine, cross magnetization also has implications in the study of geological formations. Geophysicists often rely on magnetic surveys to explore subsurface structures for resources like oil and gas. The presence of cross magnetization can complicate the interpretation of magnetic data, as it may mask or alter the signatures of the geological features being studied. By recognizing and correcting for cross magnetization, geophysicists can improve the accuracy of their analyses and make better-informed decisions regarding resource extraction.Furthermore, the concept of cross magnetization extends beyond just physical applications; it can also serve as a metaphor in various fields such as psychology and sociology. For example, in social dynamics, individuals may exhibit behaviors that are influenced by external societal pressures that contradict their inherent values or beliefs. This can be likened to cross magnetization, where external forces shape internal states in ways that may not align with one’s true self. Understanding this metaphorical application can provide insights into human behavior and interaction, which is valuable in fields like marketing, education, and conflict resolution.In conclusion, the term cross magnetization encapsulates a multifaceted phenomenon that spans across various disciplines, from physics and engineering to medicine and social sciences. Its implications are far-reaching, affecting everything from the efficiency of electrical devices to the clarity of medical imaging and the interpretation of geological data. By gaining a deeper understanding of cross magnetization, professionals in these fields can enhance their work and contribute to advancements in technology and knowledge. As we continue to explore the complexities of magnetism, the importance of cross magnetization will undoubtedly remain a critical area of study and application.

在物理和工程领域，尤其是在磁场研究中，术语cross magnetization指的是一种现象，其中材料的磁性受到外部磁场的影响，且该影响方向与主要磁化方向垂直。这个概念对于理解材料如何响应复杂的磁环境至关重要，特别是在电动机、变压器和磁存储设备等应用中。cross magnetization的重要性可以在各种实际场景中观察到。例如，在电动机中，当施加磁场时，产生的磁化往往会在多个方向上具有分量。这可能导致电动机性能的低效，因为由于磁场的不对齐而造成的无意能量损失。理解和减轻cross magnetization的影响对于设计更高效系统的工程师至关重要。此外，cross magnetization在磁共振成像（MRI）领域也起着重要作用。在MRI机器中，精确操控磁场是获得清晰和准确的人体图像所必需的。如果未能妥善考虑cross magnetization，可能会导致图像中的伪影或失真，从而导致误诊或遗漏医疗状况。因此，医学物理学家必须深入理解这一现象，以确保MRI技术的可靠性。除了在工程和医学中的应用外，cross magnetization在地质构造研究中也有其意义。地球物理学家通常依赖磁测量来探索地下结构，例如石油和天然气的资源。cross magnetization的存在可能会使磁数据的解释变得复杂，因为它可能掩盖或改变正在研究的地质特征的信号。通过识别和校正cross magnetization，地球物理学家可以提高分析的准确性，并就资源开采做出更明智的决策。此外，cross magnetization的概念不仅限于物理应用；它还可以作为心理学和社会学等各个领域的隐喻。例如，在社会动态中，个体可能表现出受外部社会压力影响的行为，这些行为与其固有的价值观或信仰相矛盾。这可以比作cross magnetization，外部力量以不符合个人真实自我的方式塑造内部状态。理解这一隐喻应用可以为人类行为和互动提供洞见，这在市场营销、教育和冲突解决等领域都是非常宝贵的。总之，术语cross magnetization概括了一种跨学科的多面现象，从物理和工程到医学和社会科学。它的影响深远，影响着从电气设备的效率到医学成像的清晰度以及地质数据的解释等方方面面。通过深入理解cross magnetization，这些领域的专业人士可以提升他们的工作，并推动技术和知识的进步。随着我们继续探索磁性复杂性，cross magnetization的重要性无疑将继续成为研究和应用的关键领域。