nonmagnetic material

简明释义

非磁性体

英英释义

例句

1.When designing electronic devices, engineers often choose nonmagnetic materials 非磁性材料 for components that need to function near magnets.

在设计电子设备时，工程师通常选择非磁性材料用于需要在磁铁附近工作的组件。

2.The frame of the speaker is constructed from nonmagnetic material 非磁性材料 to prevent any distortion in sound quality.

扬声器的框架由非磁性材料构成，以防止音质失真。

3.The watch is made from a nonmagnetic material 非磁性材料, ensuring it won't be affected by magnetic fields.

这款手表是由非磁性材料制作的，确保不会受到磁场的影响。

4.In medical imaging, using nonmagnetic materials 非磁性材料 is crucial to avoid interference with MRI machines.

在医学成像中，使用非磁性材料至关重要，以避免干扰MRI机器。

5.The laboratory requires tools made of nonmagnetic material 非磁性材料 to avoid contamination of sensitive experiments.

实验室需要使用由非磁性材料制成的工具，以避免对敏感实验的污染。

作文

In the field of materials science, understanding the properties of different substances is crucial for various applications. One important category of materials is nonmagnetic material, which refers to substances that do not exhibit magnetic properties. This means that they are not attracted to magnets and do not become magnetized themselves. Examples of nonmagnetic materials include aluminum, copper, and certain types of plastics. These materials are essential in many industries, especially in electronics and aerospace, where magnetic interference can lead to malfunctions or inaccuracies.The significance of nonmagnetic materials can be observed in everyday technology. For instance, in the manufacturing of electronic devices such as smartphones and laptops, components made from nonmagnetic materials are often used to ensure that sensitive components operate without disruption. If a magnetic material were used in these devices, it could interfere with the signals and performance of the internal circuits, leading to potential failures.Moreover, in the field of medical imaging, particularly in MRI (Magnetic Resonance Imaging), the use of nonmagnetic materials is imperative. Equipment must be constructed with materials that will not distort the magnetic fields used to create images of the human body. The presence of any magnetic material could compromise the quality of the images or even pose risks to patients with implanted medical devices, such as pacemakers.Additionally, the construction industry also benefits from nonmagnetic materials. In environments where there is a risk of explosion, such as oil rigs and chemical plants, using nonmagnetic materials can enhance safety. Tools and equipment made from these materials minimize the risk of sparks that could ignite flammable substances. Thus, the choice of materials in such critical environments is vital for ensuring safety and operational efficiency.On the other hand, the study of nonmagnetic materials also leads to advancements in the development of new technologies. Researchers are constantly exploring ways to enhance the properties of these materials to suit specific needs. For instance, innovations in nonmagnetic materials are paving the way for lighter and more durable products. This research can lead to breakthroughs in various fields, including transportation, where lighter materials contribute to fuel efficiency and reduced emissions.In conclusion, nonmagnetic materials play an integral role in modern technology and industry. Their unique properties allow for safe and efficient operation in various applications, from electronics to medical imaging and construction. As we continue to innovate and develop new technologies, the importance of understanding and utilizing nonmagnetic materials will only grow. The future of material science will undoubtedly rely on these versatile substances to meet the demands of an ever-evolving world.

在材料科学领域，理解不同物质的特性对于各种应用至关重要。其中一个重要的材料类别是非磁性材料，指的是不表现出磁性特性的物质。这意味着它们不会被磁铁吸引，也不会自己被磁化。非磁性材料的例子包括铝、铜和某些类型的塑料。这些材料在许多行业中都是必不可少的，尤其是在电子和航空航天领域，在这些领域中，磁干扰可能导致故障或不准确。非磁性材料的重要性可以在日常技术中观察到。例如，在制造智能手机和笔记本电脑等电子设备时，通常使用由非磁性材料制成的组件，以确保敏感组件在没有干扰的情况下运行。如果在这些设备中使用了磁性材料，它可能会干扰信号和内部电路的性能，从而导致潜在的故障。此外，在医学成像领域，特别是在MRI（磁共振成像）中，使用非磁性材料是必要的。设备必须用不会扭曲用于创建人体图像的磁场的材料构造。任何磁性材料的存在都可能影响图像的质量，甚至对植入医疗器械的患者（如心脏起搏器）构成风险。此外，建筑行业也受益于非磁性材料。在有爆炸风险的环境中，例如石油平台和化工厂，使用非磁性材料可以提高安全性。由这些材料制成的工具和设备最小化了可能引发可燃物质火花的风险。因此，在这些关键环境中选择材料对于确保安全和操作效率至关重要。另一方面，研究非磁性材料也推动了新技术的发展。研究人员不断探索增强这些材料特性的方式，以满足特定需求。例如，非磁性材料的创新正在为更轻且更耐用的产品铺平道路。这项研究可以在各个领域带来突破，包括交通运输，较轻的材料有助于提高燃油效率并减少排放。总之，非磁性材料在现代技术和工业中发挥着不可或缺的作用。它们独特的性质使得在从电子产品到医学成像和建筑的各种应用中安全高效地运行成为可能。随着我们继续创新和开发新技术，理解和利用非磁性材料的重要性只会增加。材料科学的未来无疑将依赖这些多功能物质来满足不断发展的世界的需求。