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Magnetic Damping01:17

Magnetic Damping

815
Eddy currents can produce significant drag on motion, called magnetic damping. For instance, when a metallic pendulum bob swings between the poles of a strong magnet, significant drag acts on the bob as it enters and leaves the field, quickly damping the motion.
If, however, the bob is a slotted metal plate, the magnet produces a much smaller effect. When a slotted metal plate enters the field, an emf is induced by the change in flux; however, it is less effective because the slots limit the...
815
Types of Damping01:20

Types of Damping

7.2K
If the amount of damping in a system is gradually increased, the period and frequency start to become affected because damping opposes, and hence slows, the back and forth motion (the net force is smaller in both directions). If there is a very large amount of damping, the system does not even oscillate; instead, it slowly moves toward equilibrium. In brief, an overdamped system moves slowly towards equilibrium, whereas an underdamped system moves quickly to equilibrium but will oscillate about...
7.2K
Damped Oscillations01:07

Damped Oscillations

6.5K
In the real world, oscillations seldom follow true simple harmonic motion. A system that continues its motion indefinitely without losing its amplitude is termed undamped. However, friction of some sort usually dampens the motion, so it fades away or needs more force to continue. For example, a guitar string stops oscillating a few seconds after being plucked. Similarly, one must continually push a swing to keep a child swinging on a playground.
Although friction and other non-conservative...
6.5K
Poisson's And Laplace's Equation01:25

Poisson's And Laplace's Equation

3.9K
The electric potential of the system can be calculated by relating it to the electric charge densities that give rise to the electric potential. The differential form of Gauss's law expresses the electric field's divergence in terms of the electric charge density.
3.9K
RLC Series Circuits01:30

RLC Series Circuits

3.4K
An RLC series circuit comprises an inductor, a resistor, and a charged capacitor connected in series. When the circuit is closed, the capacitor begins to discharge through the resistor and inductor by transferring energy from the electric field to the magnetic field. Here, the resistor connected to the circuit causes energy losses; therefore, on the complete discharge of the capacitor, the magnetic field energy acquired by the inductor is less than the original electric field energy of the...
3.4K
RLC Circuit as a Damped Oscillator01:30

RLC Circuit as a Damped Oscillator

1.7K
An RLC circuit combines a resistor, inductor, and capacitor, connected in a series or parallel combination.
Consider a series RLC circuit. Here, the presence of resistance in the circuit leads to energy loss due to joule heating in the resistance. Therefore, the total electromagnetic energy in the circuit is no longer constant and decreases with time. Since the magnitude of charge, current, and potential difference continuously decreases, their oscillations are said to be damped. This is...
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Related Experiment Video

Updated: Nov 25, 2025

Determination of the Excitation and Coupling Rates Between Light Emitters and Surface Plasmon Polaritons
07:39

Determination of the Excitation and Coupling Rates Between Light Emitters and Surface Plasmon Polaritons

Published on: July 21, 2018

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Plasmon Damping in Electronically Open Systems.

Kirill Kapralov1, Dmitry Svintsov1

  • 1Center for Photonics and 2d Materials, Moscow Institute of Physics and Technology, Dolgoprudny 141700, Russia.

Physical Review Letters
|December 18, 2020
PubMed
Summary
This summary is machine-generated.

Plasmons in connected semiconductors experience extra damping from charge carriers entering contacts. This lead-induced damping affects plasmon lifetime and reflection, impacting devices like photodetectors.

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Area of Science:

  • Solid-state physics
  • Plasmonics
  • Quantum electronics

Background:

  • Electrically controlled plasmonics is advancing rapidly.
  • The influence of electronic reservoirs on plasmon properties remains an open question.

Purpose of the Study:

  • To investigate the effects of electronic reservoirs on plasmon properties in open systems.
  • To develop a theoretical framework for lead-induced damping in plasmons.

Main Methods:

  • Developed a theory based on the kinetic equation with microscopic boundary conditions.
  • Applied perturbation theory concerning transport nonlocality.
  • Analyzed plasmon lifetime and reflection loss at semiconductor-metal contacts.

Main Results:

  • Plasmons in electronically open systems exhibit additional damping due to charge carrier penetration and thermalization.
  • Finite plasmon lifetime in open ballistic systems is proportional to conductor length divided by carrier Fermi velocity.
  • Finite reflection loss at semiconductor-metal contacts is proportional to Fermi velocity divided by wave phase velocity.

Conclusions:

  • Lead-induced damping is a significant factor affecting plasmon behavior in connected electronic systems.
  • This phenomenon provides a new perspective for understanding plasmon-assisted photodetection experiments.
  • The developed theory offers insights into plasmon dynamics in realistic solid-state devices.