thermomagnetic

简明释义

英[ˌθɜrmoʊməˈɡænɪk]美[ˌθɜrmoʊməˈɡænɪk]

adj. [物] 热磁的

英英释义

单词用法

同义词

反义词

例句

1.It may be understood by simulating the thermomagnetic recording of magneto optical films all kinds of factors that affect thermomagnetic recording.

对磁光薄膜进行热磁模拟可以了解影响热磁记录过程的各种因素及这些因素间的相互关系以及它们对写入信息的影响。

2.A mathematical model is established for investigating the characteristics of thermomagnetic convection in the temperature-sensitive magnetic fluid in the presence of an external magnetic field.

建立了描述外磁场作用下温度敏感型磁流体热磁对流特性的数学模型，数值模拟了回路中热磁对流的流动与传热特性。

3.A mathematical model is established for investigating the characteristics of thermomagnetic convection in the temperature-sensitive magnetic fluid in the presence of an external magnetic field.

建立了描述外磁场作用下温度敏感型磁流体热磁对流特性的数学模型，数值模拟了回路中热磁对流的流动与传热特性。

4.The thermomagnetic 热磁的 properties of this substance make it ideal for high-temperature applications.

这种物质的thermomagnetic 热磁的特性使其非常适合高温应用。

5.The researchers developed a new type of thermomagnetic 热磁的 material that can convert heat into magnetic energy.

研究人员开发了一种新型的thermomagnetic 热磁的材料，可以将热量转化为磁能。

6.Scientists are exploring the potential of thermomagnetic 热磁的 materials for use in energy harvesting devices.

科学家们正在探索thermomagnetic 热磁的材料在能源收集设备中的潜力。

7.In industrial applications, thermomagnetic 热磁的 sensors are used to monitor temperature variations.

在工业应用中，thermomagnetic 热磁的传感器用于监测温度变化。

8.The thermomagnetic 热磁的 effect can be observed in certain alloys when heated.

在加热时，可以观察到某些合金中的thermomagnetic 热磁的效应。

作文

In the realm of physics, the study of materials and their properties is a fascinating subject that has led to numerous technological advancements. One area of research that has gained significant attention in recent years is the field of thermomagnetic 热磁 materials. These materials exhibit unique behaviors when subjected to changes in temperature and magnetic fields, making them crucial for various applications in modern technology.To understand the significance of thermomagnetic 热磁 materials, it is essential to explore how they function. Essentially, these materials can change their magnetic properties in response to thermal variations. This means that as the temperature increases or decreases, the material's ability to conduct magnetic fields can be altered. Such properties are not only intriguing from a scientific standpoint but also hold immense potential for practical applications.One of the most exciting applications of thermomagnetic 热磁 materials is in energy conversion technologies. For instance, they can be utilized in thermoelectric generators, which convert heat energy into electrical energy. By leveraging the unique properties of thermomagnetic 热磁 materials, researchers are working on creating more efficient systems that can harness waste heat from industrial processes or even from the human body.Moreover, thermomagnetic 热磁 materials have promising implications for data storage and information technology. The ability to control magnetic properties through temperature changes opens up new avenues for developing advanced memory devices. For example, by using thermomagnetic 热磁 materials, one could potentially create hard drives that can store more data while consuming less power. This innovation could lead to significant improvements in the performance and efficiency of electronic devices.In addition to energy and data storage applications, thermomagnetic 热磁 materials are also being explored for use in medical technologies. Magnetic resonance imaging (MRI) is a widely used diagnostic tool that relies on magnetic fields to produce detailed images of the inside of the body. By incorporating thermomagnetic 热磁 materials into MRI machines, researchers believe they can enhance image quality and reduce scanning times, ultimately leading to better patient outcomes.Despite the exciting prospects of thermomagnetic 热磁 materials, there are still challenges to overcome in their development and application. Researchers must continue to explore the underlying mechanisms that govern their behavior and seek ways to optimize their performance under various conditions. Furthermore, the scalability of these materials for industrial applications is another critical aspect that needs to be addressed.In conclusion, the study of thermomagnetic 热磁 materials represents a vibrant intersection of physics and engineering with vast potential for real-world applications. As we continue to unravel the mysteries of these materials, we are likely to witness groundbreaking innovations that can transform industries ranging from energy to healthcare. The future of thermomagnetic 热磁 materials is bright, and it is an exciting time for researchers and technologists alike to delve deeper into this captivating field.

在物理学领域，材料及其特性的研究是一个迷人的主题，已经导致了无数技术进步。近年来，热磁 材料的研究引起了广泛关注。这些材料在温度和磁场变化时表现出独特的行为，使它们在现代技术的各种应用中至关重要。要理解热磁 材料的重要性，就必须探讨它们的功能。本质上，这些材料可以在热变化的影响下改变其磁性。这意味着随着温度的升高或降低，材料导电磁场的能力可以被改变。这种特性不仅从科学角度令人着迷，而且在实际应用中也具有巨大的潜力。热磁 材料最令人兴奋的应用之一是在能量转换技术中。例如，它们可以用于热电发电机，将热能转换为电能。通过利用热磁 材料的独特特性，研究人员正在努力创建更高效的系统，以利用工业过程或甚至人体产生的废热。此外，热磁 材料在数据存储和信息技术方面也有着良好的前景。通过温度变化控制磁性特性，开启了开发先进存储设备的新途径。例如，通过使用热磁 材料，可以创造出能够存储更多数据并消耗更少电力的硬盘。这一创新可能会显著改善电子设备的性能和效率。除了能源和数据存储应用外，热磁 材料还被探索用于医疗技术。磁共振成像（MRI）是一种广泛使用的诊断工具，依赖于磁场产生身体内部的详细图像。通过将热磁 材料纳入MRI机器，研究人员相信可以提高图像质量并减少扫描时间，最终改善患者的治疗效果。尽管热磁 材料的前景令人兴奋，但在其开发和应用中仍面临挑战。研究人员必须继续探索支配其行为的基本机制，并寻求优化其在各种条件下的性能。此外，这些材料在工业应用中的可扩展性也是一个需要解决的关键问题。总之，热磁 材料的研究代表了物理学与工程学的生动交汇，具有广阔的现实应用潜力。随着我们继续揭示这些材料的奥秘，我们可能会见证能够转变能源到医疗等行业的突破性创新。热磁 材料的未来光明，研究人员和技术人员在这个迷人的领域深入探索的时机正好。