oersted

简明释义

英[ˈɜːsted]美[ˈɜːrsted]

n. 奥斯特（磁场强度单位）

英英释义

单词用法

同义词

反义词

例句

1.Will hold Olympiad, being injured is able to open Closing Ceremony, track and field competition and football match final oersted.

将举行奥运会、残奥会开闭幕式、田径比赛及足球比赛决赛。

2.Will hold Olympiad, being injured is able to open Closing Ceremony, track and field competition and football match final oersted.

将举行奥运会、残奥会开闭幕式、田径比赛及足球比赛决赛。

3.For each percent of cobalt the maximum directional variation of linewidth may be of the order of 4 oersted.

每百分之一的钴在正型铁氧体中所导致的最大与最小的线宽间的差值约为4奥。

4.Where the Shandong Qingdao development zone can buy an oersted carat of haptic lens?

山东青岛开发区哪里可以买奥克拉隐形眼镜?。

5.Oersted demonstrated that electric currents could produce magnetic effects.

奥斯忒表演了电流能引起磁效应。

6.The strength of the magnetic field is measured in units called oersted.

磁场的强度以称为奥斯特的单位进行测量。

7.In a laboratory, we found that the magnetic field reached up to 50 oersted.

在实验室中，我们发现磁场达到了50奥斯特。

8.An electromagnet can produce a magnetic field of several hundred oersted.

电磁铁可以产生几百奥斯特的磁场。

9.The unit oersted is named after the Danish physicist Hans Christian Ørsted.

单位奥斯特是以丹麦物理学家汉斯·克里斯蒂安·奥斯特命名的。

10.To measure the intensity of the magnetic field, we use a gaussmeter calibrated in oersted.

为了测量磁场的强度，我们使用校准为奥斯特的高斯计。

作文

In the field of physics, particularly in electromagnetism, the term oersted refers to a unit of measurement that quantifies magnetic field strength. Named after the Danish physicist Hans Christian Ørsted, who discovered the relationship between electricity and magnetism, one oersted is defined as the strength of a magnetic field that will produce a force of one dyne on a unit magnetic pole placed in the field. This concept is essential for understanding how electric currents can create magnetic fields and vice versa, which is fundamental in many technologies we rely on today, such as motors and generators. Understanding the significance of oersted is crucial for students and professionals in the fields of physics and engineering. For instance, when designing electrical devices, engineers must consider the magnetic fields produced by currents flowing through wires. The strength of these fields is often measured in oersteds, allowing engineers to predict how the device will behave under different conditions. Moreover, the concept of oersted extends beyond theoretical discussions; it has practical applications in various industries. In medical technology, for example, magnetic resonance imaging (MRI) machines utilize strong magnetic fields to produce detailed images of the human body. The strength of these magnetic fields is often expressed in terms of oersteds, highlighting the importance of this unit in real-world applications. In addition to its applications in engineering and medicine, the study of oersted also plays a role in advancing scientific knowledge. Researchers exploring the properties of materials at the atomic level often investigate how these materials respond to magnetic fields measured in oersteds. This research can lead to the development of new materials with unique magnetic properties, which may have future applications in technology, data storage, and energy production. Furthermore, the historical context of the oersted provides insight into the evolution of scientific thought. Hans Christian Ørsted's discovery in 1820 was pivotal in establishing the field of electromagnetism, which later influenced the work of other prominent scientists, such as James Clerk Maxwell and Albert Einstein. Their contributions built upon Ørsted’s findings, leading to a deeper understanding of the interplay between electricity and magnetism. In conclusion, the term oersted is more than just a unit of measurement; it represents a fundamental concept in physics that has far-reaching implications in technology, medicine, and scientific research. By grasping the significance of oersted, individuals can better appreciate the intricate connections between electricity and magnetism, as well as their impact on our daily lives. As we continue to explore the mysteries of the universe, the principles associated with oersted will undoubtedly remain a vital part of our scientific journey.

在物理学领域，特别是在电磁学中，术语oersted指的是一种测量单位，用于量化磁场强度。这个单位以丹麦物理学家汉斯·克里斯蒂安·厄尔斯特德的名字命名，他发现了电与磁之间的关系。一个oersted被定义为在该磁场中放置一个单位磁极所产生的力为一达因的磁场强度。这个概念对于理解电流如何产生磁场以及反之亦然是至关重要的，这在我们今天依赖的许多技术中都是基础，比如电动机和发电机。 理解oersted的重要性对于物理学和工程学领域的学生和专业人士至关重要。例如，在设计电气设备时，工程师必须考虑通过电线流动的电流所产生的磁场。这些磁场的强度通常以oersted为单位进行测量，使工程师能够预测设备在不同条件下的表现。 此外，oersted的概念超越了理论讨论；它在各个行业中都有实际应用。例如，在医疗技术中，磁共振成像（MRI）机器利用强磁场生成人体的详细图像。这些磁场的强度通常用oersted表示，突显了这个单位在现实应用中的重要性。 除了在工程和医学中的应用外，oersted的研究也在推动科学知识的发展。研究人员探索材料在原子级别的特性时，常常调查这些材料如何响应以oersted为单位的磁场。这项研究可能导致新材料的开发，这些材料具有独特的磁性，未来可能在技术、数据存储和能源生产中得到应用。 此外，oersted的历史背景提供了对科学思想演变的深入了解。汉斯·克里斯蒂安·厄尔斯特德在1820年的发现对于建立电磁学领域至关重要，后来影响了其他著名科学家的工作，如詹姆斯·克拉克·麦克斯韦和阿尔伯特·爱因斯坦。他们的贡献建立在厄尔斯特德的发现之上，导致对电与磁之间相互作用的更深入理解。 总之，术语oersted不仅仅是一个测量单位；它代表了物理学中的一个基本概念，对技术、医学和科学研究有着深远的影响。通过掌握oersted的重要性，个人可以更好地理解电与磁之间的复杂联系，以及它们对我们日常生活的影响。随着我们继续探索宇宙的奥秘，与oersted相关的原则无疑将继续成为我们科学旅程的重要组成部分。