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相关概念视频

Harmonic Mean01:09

Harmonic Mean

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The arithmetic mean is usually skewed towards the larger values in the data set. Therefore, to avoid this inherent bias towards smaller values, the harmonic mean is used.
Take the example of the speed of a car, which is the measure of the rate of distance traveled. If the vehicle traverses the same distance back-and-forth, its average speed equals the total distance traveled divided by the total time taken. However, if the car moves with varying speeds, then the arithmetic mean is more skewed...
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Simple Harmonic Motion01:21

Simple Harmonic Motion

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Simple harmonic motion is the name given to oscillatory motion for a system where the net force can be described by Hooke's law. If the net force can be described by Hooke's law and there is no damping (by friction or other non-conservative forces), then a simple harmonic oscillator will oscillate with equal displacement on either side of the equilibrium position. To derive an equation for period and frequency, the equation of motion is used. The period of a simple harmonic oscillator is given...
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Energy in Simple Harmonic Motion01:23

Energy in Simple Harmonic Motion

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To determine the energy of a simple harmonic oscillator, consider all the forms of energy it can have during its simple harmonic motion. According to Hooke's Law, the energy stored during the compression/stretching of a string in a simple harmonic oscillator is potential energy. As the simple harmonic oscillator has no dissipative forces, it also possesses kinetic energy. In the presence of conservative forces, both energies can interconvert during oscillation, but the total energy remains...
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Characteristics of Simple Harmonic Motion01:17

Characteristics of Simple Harmonic Motion

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The key characteristic of the simple harmonic motion is that the acceleration of the system and, therefore, the net force are proportional to the displacement and act in the opposite direction to the displacement. Additionally, the period and frequency of a simple harmonic oscillator are independent of its amplitude. For example, diving boards move faster or slower based on their thickness. A stiff, thick diving board has a large force constant, which causes it to have a smaller period, while a...
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Problem Solving: Energy in Simple Harmonic Motion01:17

Problem Solving: Energy in Simple Harmonic Motion

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Simple harmonic motion (SHM) is a type of periodic motion in time and position, in which an object oscillates back and forth around an equilibrium position with a constant amplitude and frequency. In SHM, there is a continuous exchange between the potential and kinetic energy, which results in the oscillation of the object.
Consider the spring in a shock absorber of a car. The spring attached to the wheel executes simple harmonic motion while the car is moving on a bumpy road. The force on the...
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Simple Harmonic Motion and Uniform Circular Motion01:42

Simple Harmonic Motion and Uniform Circular Motion

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While simple harmonic motion and uniform circular motion may be two separate concepts, they correlate and interlink with each other. Simple harmonic motion is an oscillatory motion in a system where the net force can be described by Hooke's law, while uniform circular motion is the motion of an object in a circular path at constant speed.
There is an easy way to produce simple harmonic motion by using uniform circular motion. For instance, consider a ball attached to a uniformly rotating...
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Harmonic Nanoparticles for Regenerative Research
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和的非赫米蒂安式皮肤效应.

Qicheng Zhang1, Liwei Xiong1, Shuaishuai Tong1

  • 1Key Laboratory of Artificial Micro- and Nano-Structures of Ministry of Education and School of Physics and Technology, Wuhan University, Wuhan, China.

Nature communications
|January 30, 2026
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概括
此摘要是机器生成的。

研究人员在声学系统中探索了和非赫密特皮肤效应 (NHSE). 他们通过重新配置频率来证明单极和双极NHE之间的可控切换,在非赫密斯物理学中开辟了新的途径.

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科学领域:

  • 凝聚物质物理学 凝聚物质物理学
  • 声学 声学 在声学方面
  • 非赫尔密斯系的系统

背景情况:

  • 非赫密斯皮肤效应 (NHSE) 描述了非赫密斯系统中的边界定位.
  • 浮板工程是扩展NHSE应用的关键方法.
  • 在Floquet系统中的波响应仍然未被充分探索.

研究的目的:

  • 介绍和实验证明和非赫米蒂安皮肤效应 (NHSE).
  • 研究动态合和光谱拓在和NHSE中的作用.
  • 在一个声学平台中实现NHSE属性的可控切换.

主要方法:

  • 使用动态合的哈塔诺-尼尔森模型进行理论建模.
  • 在可编程声学网格中实验实施,带有单向合器.
  • 频率重新配置以控制激发和调制参数.

主要成果:

  • 一个单频输入产生多个和声与不同的皮肤形态.
  • 每个波的形态由其特定频率的光谱绕拓管理.
  • 在单极和双极和NHE之间实现了可控切换.
  • 单极和双极NHSEs分别表现出均和相反的声音收集.

结论:

  • 这项研究引入了和NHSE的新概念.
  • 证明了在声学中实现和NHSE的实验实现和控制.
  • 突出了研究具有和效应的非赫尔密斯物理学的潜力.