magnetic conductance

简明释义

磁导

英英释义

例句

1.The team published a paper detailing how magnetic conductance affects the performance of superconductors.

团队发表了一篇论文，详细说明了磁导通性如何影响超导体的性能。

2.In the experiment, we found that increasing temperature decreased the magnetic conductance significantly.

在实验中，我们发现温度升高显著降低了磁导通性。

3.The magnetic conductance of the material was essential for designing efficient magnetic circuits.

该材料的磁导通性对于设计高效的磁电路至关重要。

4.The researchers measured the magnetic conductance of the new alloy to determine its suitability for electronic applications.

研究人员测量了这种新合金的磁导通性以确定其在电子应用中的适用性。

5.Engineers often consider magnetic conductance when developing new sensors for industrial applications.

工程师在开发工业应用的新传感器时，常常考虑磁导通性。

作文

In the realm of physics, the term magnetic conductance refers to a material's ability to conduct magnetic fields. This concept is crucial in understanding how various materials respond to magnetic forces and how they can be used in applications such as electrical engineering and material science. To grasp the significance of magnetic conductance fully, we must explore its definition, properties, and practical implications.Firstly, magnetic conductance can be defined as the measure of a material's ability to allow magnetic field lines to pass through it. This property is often characterized by the material's permeability, which indicates how easily a magnetic field can penetrate the substance. High permeability materials, such as iron, demonstrate high magnetic conductance, making them ideal for use in transformers and inductors, where efficient magnetic field transfer is essential.Moreover, the concept of magnetic conductance is closely related to the idea of magnetism itself. Magnetism arises from the motion of electric charges, and different materials exhibit varying levels of magnetic properties. For example, ferromagnetic materials, which have a strong response to magnetic fields, possess high magnetic conductance. In contrast, diamagnetic materials, which repel magnetic fields, exhibit low magnetic conductance.Understanding magnetic conductance is not only important for theoretical physics but also has practical applications in technology. For instance, in the design of electrical circuits, engineers must consider the magnetic conductance of materials to ensure efficient energy transfer. In magnetic resonance imaging (MRI), the principles of magnetic conductance are utilized to create detailed images of the human body, demonstrating the importance of this concept in medical technology.Furthermore, advancements in nanotechnology have opened new avenues for exploring magnetic conductance. Researchers are investigating how nanoscale materials behave under magnetic fields, which could lead to the development of new devices with enhanced magnetic properties. These innovations may pave the way for more efficient energy storage systems, improved sensors, and even quantum computing technologies.In conclusion, magnetic conductance is a fundamental concept in the study of magnetism and materials science. Its definition as a measure of a material's ability to conduct magnetic fields highlights the importance of understanding how different substances interact with magnetic forces. From practical applications in engineering and medicine to cutting-edge research in nanotechnology, the implications of magnetic conductance are vast and significant. As we continue to explore the properties of materials and their interactions with magnetic fields, the importance of magnetic conductance will undoubtedly grow, shaping the future of technology and science.

在物理学领域，术语磁导指的是材料传导磁场的能力。这个概念对于理解各种材料如何响应磁力以及它们在电气工程和材料科学等应用中的使用至关重要。要充分掌握磁导的意义，我们必须探讨其定义、特性和实际应用。首先，磁导可以定义为材料允许磁场线通过的能力的度量。该属性通常通过材料的磁导率来表征，磁导率表示磁场穿透物质的难易程度。高磁导率材料，如铁，表现出高磁导，使其成为变压器和电感器中理想的材料，在这些应用中，高效的磁场传输至关重要。此外，磁导的概念与磁性本身密切相关。磁性源于电荷的运动，不同材料表现出不同水平的磁性。例如，铁磁材料对磁场的响应强烈，具有高磁导。相反，抗磁材料则排斥磁场，表现出低磁导。理解磁导不仅对理论物理学重要，而且在技术上也具有实际应用。例如，在电路设计中，工程师必须考虑材料的磁导以确保高效的能量传输。在磁共振成像（MRI）中，磁导的原理被用于创建人体的详细图像，展示了这一概念在医疗技术中的重要性。此外，纳米技术的进步为探索磁导开辟了新的途径。研究人员正在调查纳米尺度材料在磁场下的行为，这可能导致新设备的开发，具有增强的磁性。这些创新可能为更高效的能源存储系统、改善传感器甚至量子计算技术铺平道路。总之，磁导是研究磁性和材料科学的基本概念。作为衡量材料传导磁场能力的指标，其定义突显了理解不同物质如何与磁力相互作用的重要性。从电气工程和医学中的实际应用到纳米技术中的前沿研究，磁导的影响深远而重要。随着我们继续探索材料的特性及其与磁场的相互作用，磁导的重要性无疑会不断增长，塑造科技和科学的未来。