magnetized

简明释义

英[ˈmæɡ.nə.taɪzd]美[ˈmæɡ.nə.taɪzd]

adj. 已磁化的

v. 使……磁化，使……有磁性（magnetize 的过去式和过去分词）

英英释义

单词用法

同义词

反义词

例句

1.There, copper plates near the entrance bear snippets of Morse code, and a naturally magnetized lodestone sits by a compass rose etched in granite.

这面铜板离入口很近，在入口的地方刻有一段莫尔斯电码，旁边还有一块天然磁石摆放在一块刻有罗盘刻度的花岗岩上。

2.Watch has a component called gossamer, this thing is most afraid of watch in the magnetic field near a magnet, spring will be magnetized.

手表里有个部件叫游丝，这东西最怕的就是磁场，手表在靠近磁铁后，游丝会被磁化。

3.Rosen and His DIY MRI: How it works: A patient stands in the scanner, wearing a vest connected to a computer, and inhales magnetized helium.

Rosen和他DIY的MRI如何工作：一个患者站在扫描仪中，穿着一件与计算机相连的背心，然后吸入被磁化的氦气。

4.He magnetized the crowd with his beautiful voice.

他用美妙歌喉迷住了这群人。

5.As the electrons move through the magnetized nebula, they radiate away their energy and create the elaborate nebula seen by Chandra.

当电子通过被磁化的星云时释放出能量，造就出“钱德拉”望远镜所看到的精致的星云。

6.There are no bearings to fail or requirements for flexible couplings because its magnetized drum assembly is attached directly to the shaft.

没有轴承失败或弹性联轴器的要求，因为它的磁化鼓大会直接连接到轴。

7.The compass needle is magnetized, allowing it to point north.

指南针的指针是磁化的，使其能够指向北方。

8.After rubbing the metal with a magnet, it became magnetized.

用磁铁摩擦金属后，它变得磁化的。

9.The magnetized paper clips stuck together easily.

那些磁化的纸夹很容易粘在一起。

10.He used a magnetized screwdriver to pick up screws in tight spaces.

他用一把磁化的螺丝刀来拾起狭小空间里的螺丝。

11.The refrigerator door has magnetized seals to keep it closed.

冰箱门有磁化的密封条，以保持关闭。

作文

In today's world, we often encounter various phenomena that can be explained through the principles of physics. One such fascinating concept is that of materials becoming 磁化. This process occurs when certain materials, typically metals like iron, cobalt, and nickel, are subjected to a magnetic field. The result is that these materials can exhibit magnetic properties, attracting or repelling other magnetic objects. Understanding how materials become 磁化 not only enhances our knowledge of physics but also has practical applications in everyday life. The process of 磁化 involves aligning the magnetic domains within a material. In an unmagnetized state, these domains are oriented randomly, canceling each other out. However, when exposed to a magnetic field, the domains align in the direction of the field, resulting in a net magnetic moment. This alignment is what causes the material to become 磁化 and exhibit magnetic properties. One of the most common examples of 磁化 can be seen in refrigerator magnets. These magnets are made from materials that have been 磁化 to stick to metal surfaces. When you place a magnet on your refrigerator, it stays in place due to the magnetic attraction between the 磁化 material and the metal of the fridge. This simple application shows how 磁化 plays a crucial role in our daily lives. Furthermore, 磁化 is not limited to small household items. It is also fundamental in technology, particularly in the development of electric motors and generators. In these devices, the interaction between 磁化 materials and electric currents generates motion or electricity. For instance, in an electric motor, a 磁化 rotor spins within a magnetic field, converting electrical energy into mechanical energy. This principle underlies many modern technologies, including electric vehicles and renewable energy systems. Moreover, the concept of 磁化 extends beyond just physical materials. In the realm of data storage, hard drives use 磁化 disks to store information. Data is written onto the disk by changing the 磁化 state of tiny regions on the disk's surface. When reading data, the drive detects the 磁化 patterns, allowing for the retrieval of stored information. This technology revolutionized how we store and access data, making it essential in our digital age. In conclusion, the concept of 磁化 is a fundamental aspect of physics that has far-reaching implications in our daily lives and technological advancements. From simple refrigerator magnets to complex electric motors and data storage systems, 磁化 plays a crucial role in a multitude of applications. By understanding how materials become 磁化, we can appreciate the underlying principles that govern the behavior of matter and harness these principles for innovation and progress in various fields.

在当今世界，我们经常遇到各种现象，这些现象可以通过物理学原理来解释。其中一个引人入胜的概念是材料如何变得磁化。这一过程发生在某些材料，通常是金属如铁、钴和镍，当它们受到磁场的影响时。结果是这些材料可以表现出磁性，吸引或排斥其他磁性物体。理解材料如何变得磁化不仅增强了我们对物理学的认识，还有助于我们在日常生活中的实际应用。 磁化的过程涉及到材料内部磁域的排列。在未磁化状态下，这些磁域随机定向，相互抵消。然而，当暴露于磁场时，磁域会朝着磁场的方向排列，从而产生净磁矩。这种排列就是导致材料变得磁化并表现出磁性特性的原因。 一个最常见的磁化例子可以在冰箱磁铁中看到。这些磁铁由已经被磁化的材料制成，可以粘附在金属表面。当你把磁铁放在冰箱上时，由于磁化材料与冰箱金属之间的磁性吸引力，它保持在原位。这个简单的应用展示了磁化在我们日常生活中的重要作用。 此外，磁化不仅限于小型家居用品。它在技术领域也是基础，尤其是在电动机和发电机的开发中。在这些设备中，磁化材料与电流之间的相互作用产生运动或电力。例如，在电动机中，磁化转子在磁场中旋转，将电能转化为机械能。这一原理是许多现代技术的基础，包括电动车和可再生能源系统。 此外，磁化的概念不仅限于物理材料。在数据存储领域，硬盘使用磁化磁盘来存储信息。通过改变磁盘表面微小区域的磁化状态来写入数据。在读取数据时，驱动器检测磁化模式，从而允许检索存储的信息。这项技术彻底改变了我们存储和访问数据的方式，使其在数字时代至关重要。 总之，磁化的概念是物理学的一个基本方面，对我们日常生活和技术进步有着深远的影响。从简单的冰箱磁铁到复杂的电动机和数据存储系统，磁化在众多应用中发挥着关键作用。通过理解材料如何变得磁化，我们可以欣赏支配物质行为的基本原理，并利用这些原理在各个领域进行创新和进步。