electrodynamic

简明释义

英[ɪˌlektrəʊdaɪˈnæmɪk]美[ɪˌlektroʊdaɪˈnæmɪk]

adj. 电力学的

英英释义

单词用法

同义词

反义词

例句

1.The control system comprises the electrodynamic type cryogenic fluid expansion valve, the programmable controller, the temperature transmitter and the like.

本发明由电 动式低温流体膨胀阀、可编程控制器、温度传感器等组成。

2.Observations from NCAR Incoherent Scatter Radar Base are used for case study of the dynamic and electrodynamic coupling.

本文用美国NCAR非相干散射雷达链的观测资料进行了两个事例分析。

3.Electrodynamic shakers are used in most cases because they can operate over a broad frequency range with accurately controlled waveform.

极大多数的情况下应用电动振动台，因为它能在一定广的频率范围内工作并且能准确地控制波形。

4.When you analyze and calculate the induction and circuit and transmission systems, you would involve the induction electrodynamic potential concept.

在分析计算含电感电路和电力拖动系统时，要涉及感应电动势的概念。

5.Both switching points have electrodynamic drives which open and close very quickly.

两个开关点都具有可以非常快地打开和闭合的电动驱动器。

6.These two basic electrodynamic properties give superconductivity its unique interest.

上述两个基本电动力学性质使超导电性具有无比的重要性。

7.Electrodynamic tethers with low thrust-to-weight ratios can only perform orbital transfers over a large number of revolutions, which poses a real challenge to short time scale optimal control methods.

电动力绳系卫星的推力幅值较小且方向固定，完成轨道机动任务的周期长，其最优控制问题的求解比较困难。

8.Electrodynamic vibration equipment is a most widely used vibration equipment in vibration test.

电动振动试验系统中的应用。

9.The principles of electrodynamic 电动力学 theory are crucial for understanding how electric fields interact with moving charges.

电动力学理论的原理对于理解电场如何与移动电荷相互作用至关重要。

10.In advanced physics, electrodynamic 电动力学 simulations help predict the behavior of charged particles in various environments.

在高级物理学中，电动力学模拟有助于预测带电粒子在各种环境中的行为。

11.The research focused on the electrodynamic 电动力学 effects on superconductors at high temperatures.

研究集中在高温超导体的电动力学效应上。

12.Engineers use electrodynamic 电动力学 principles to design efficient motors and generators.

工程师利用电动力学原理设计高效的电动机和发电机。

13.The team developed a new electrodynamic 电动力学 model to enhance the performance of electric vehicles.

团队开发了一种新的电动力学模型，以提高电动车的性能。

作文

The field of physics has always been a source of fascination for many, particularly in understanding the forces that govern our universe. One of the most intriguing aspects of this field is the study of electromagnetic phenomena, which encompasses both electricity and magnetism. A key concept within this realm is electrodynamic, which refers to the study of the interaction between electric charges and currents and the magnetic fields they produce. This relationship is fundamental to many technologies we use today, from electric motors to wireless communication systems. To grasp the significance of electrodynamic principles, it is essential to consider how they manifest in everyday life. For instance, when you switch on an electric fan, the flow of electricity through the wires generates a magnetic field. This magnetic field interacts with the coils in the motor, causing the blades to spin and circulate air. This simple yet effective mechanism illustrates the core idea of electrodynamic interactions: the conversion of electrical energy into mechanical energy through the influence of magnetic fields. Moreover, electrodynamic principles are not limited to just motors; they play a crucial role in various applications, including magnetic levitation trains, which utilize the repulsive forces generated by magnets to float above the tracks, reducing friction and allowing for high-speed travel. Such innovations highlight the power of electrodynamic effects in transforming transportation and enhancing efficiency. In addition to practical applications, the study of electrodynamic phenomena extends into theoretical realms, such as quantum electrodynamics (QED). QED is a fundamental theory in physics that describes how light and matter interact at quantum levels. It combines principles of quantum mechanics with electrodynamic interactions, providing insights into the behavior of particles like electrons and photons. Understanding these interactions is vital for advancements in technology, including the development of lasers and semiconductors, which are integral to modern electronics. Furthermore, the implications of electrodynamic studies reach into the environmental domain. For example, researchers are exploring how electrodynamic principles can be applied in renewable energy technologies, such as wind turbines and solar panels. By optimizing the electrodynamic interactions within these systems, engineers aim to enhance energy conversion efficiencies and reduce reliance on fossil fuels. In conclusion, the concept of electrodynamic is pivotal in both theoretical and practical applications across various fields. Its influence can be seen in everyday devices, advanced technologies, and even in efforts to create a sustainable future. As we continue to explore and understand the intricacies of electrodynamic interactions, we unlock new possibilities for innovation and improvement in our world. Embracing the principles of electrodynamic science not only enriches our knowledge but also empowers us to harness these forces for the betterment of society.

物理学领域一直以来都是许多人感兴趣的源泉，尤其是在理解支配我们宇宙的力量方面。其中一个最引人入胜的方面是电磁现象的研究，它包含了电和磁的相互作用。在这个领域中，一个关键概念是electrodynamic，指的是电荷和电流与它们产生的磁场之间相互作用的研究。这个关系是我们今天使用的许多技术的基础，从电动机到无线通信系统。 要理解electrodynamic原理的重要性，必须考虑它们在日常生活中的表现。例如，当你打开电风扇时，电流通过电线流动，产生一个磁场。这个磁场与电动机中的线圈相互作用，导致叶片旋转并循环空气。这个简单而有效的机制说明了electrodynamic相互作用的核心思想：通过磁场的影响将电能转化为机械能。 此外，electrodynamic原理不仅限于电动机；它们在各种应用中发挥着至关重要的作用，包括磁悬浮列车，这种列车利用磁铁产生的排斥力在轨道上悬浮，减少摩擦并允许高速旅行。这些创新突显了electrodynamic效应在改变交通运输和提高效率方面的力量。 除了实际应用，electrodynamic现象的研究还延伸到理论领域，例如量子电动力学（QED）。QED是物理学中的一项基本理论，描述光与物质在量子层面上的相互作用。它结合了量子力学和electrodynamic相互作用的原则，为理解电子和光子等粒子的行为提供了见解。理解这些相互作用对于技术进步至关重要，包括激光和半导体的发展，这些都是现代电子设备不可或缺的部分。 此外，electrodynamic研究的影响还延伸到环境领域。例如，研究人员正在探索如何将electrodynamic原理应用于可再生能源技术，如风力发电机和太阳能电池板。通过优化这些系统中的electrodynamic相互作用，工程师旨在提高能量转化效率，减少对化石燃料的依赖。 总之，electrodynamic的概念在各个领域的理论和实际应用中都至关重要。它的影响可以在日常设备、先进技术，甚至在创造可持续未来的努力中看到。随着我们继续探索和理解electrodynamic相互作用的复杂性，我们为创新和改善我们的世界解锁了新的可能性。拥抱electrodynamic科学的原则不仅丰富了我们的知识，而且使我们能够利用这些力量来造福社会。