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Symmetry in Maxwell's Equations01:28

Symmetry in Maxwell's Equations

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Once the fields have been calculated using Maxwell's four equations, the Lorentz force equation gives the force that the fields exert on a charged particle moving with a certain velocity. The Lorentz force equation combines the force of the electric field and of the magnetic field on the moving charge. Maxwell's equations and the Lorentz force law together encompass all the laws of electricity and magnetism. The symmetry that Maxwell introduced into his mathematical framework may not be...
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Coulomb's Law and The Principle of Superposition01:15

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Coulomb's Law describes the force experienced by two point charges under each other's presence. But what if there are more than two charges? For example, if there is a third charge, does it experience a force that is a simple combination of the individual forces due to the first two charges? Can it be described mathematically?
The Principle of Superposition answers the question. Yes, Coulomb's Law applies to each pair of charges, and the net force on each charge is the vector sum of...
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Superposition Theorem for AC Circuits01:13

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Consider encountering a circuit in a steady state where all its inputs are sinusoidal, yet they do not all possess the same frequency. Such a circuit is not classified as an alternating current (AC) circuit, and consequently, its currents and voltages will not exhibit sinusoidal behavior. However, this circuit can be analyzed using the principle of superposition.
The principle of superposition stipulates that the output of a linear circuit with several concurrent inputs is equivalent to the...
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Superposition Theorem01:18

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The superposition principle is a fundamental concept stating that in a linear circuit, the voltage across (or current through) an element can be determined by summing the individual contributions of each independent source acting in isolation. When dealing with linear circuits containing multiple independent sources, this principle serves as a valuable tool for analysis. To apply the superposition principle effectively, one should focus on a single independent source at a time while...
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Differential Form of Maxwell's Equations01:17

Differential Form of Maxwell's Equations

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James Clerk Maxwell (1831–1879) was one of the significant contributors to physics in the nineteenth century. He is probably best known for having combined existing knowledge of the laws of electricity and the laws of magnetism with his insights to form a complete overarching electromagnetic theory, represented by Maxwell's equations. The four basic laws of electricity and magnetism were discovered experimentally through the work of physicists such as Oersted, Coulomb, Gauss, and...
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Gauss's Law: Planar Symmetry01:27

Gauss's Law: Planar Symmetry

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A planar symmetry of charge density is obtained when charges are uniformly spread over a large flat surface. In planar symmetry, all points in a plane parallel to the plane of charge are identical with respect to the charges. Suppose the plane of the charge distribution is the xy-plane, and the electric field at a space point P with coordinates (x, y, z) is to be determined. Since the charge density is the same at all (x, y) - coordinates in the z = 0 plane, by symmetry, the electric field at P...
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Related Experiment Video

Updated: Oct 24, 2025

Setting Limits on Supersymmetry Using Simplified Models
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Underlying SUSY in a generalized Jaynes-Cummings model.

F H Maldonado-Villamizar1, C A González-Gutiérrez2, L Villanueva-Vergara3

  • 1CONACYT-Instituto Nacional de Astrofísica, Óptica y Electrónica, Calle Luis Enrique Erro No. 1, Sta. Ma. Tonantzintla, Pue., 72840, Puebla, Mexico. fmaldonado@inaoep.mx.

Scientific Reports
|August 14, 2021
PubMed
Summary
This summary is machine-generated.

We introduce a unified Hamiltonian model for qubit-boson interactions, simplifying complex quantum systems. This framework includes non-linear dynamics and multi-boson exchanges, aiding in the study of quantum optics and condensed matter physics.

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Area of Science:

  • Quantum optics
  • Quantum information science
  • Condensed matter physics

Background:

  • The Jaynes-Cummings model is a fundamental framework for studying light-matter interactions in quantum systems.
  • Extensions to this model are needed to capture more complex phenomena like non-linearities and multi-boson interactions.

Purpose of the Study:

  • To present a general qubit-boson interaction Hamiltonian that unifies the standard Jaynes-Cummings model and its various extensions.
  • To demonstrate how this general Hamiltonian simplifies the analysis of complex quantum systems.

Main Methods:

  • Development of a general Hamiltonian incorporating non-linear qubit and boson dynamics.
  • Inclusion of non-linear, multi-boson excitation exchange terms.
  • Utilizing an underlying algebra with supersymmetric quantum mechanics features for operator-based diagonalization.

Main Results:

  • A single Hamiltonian class is presented that encompasses the Jaynes-Cummings model and its extensions.
  • The developed model allows for operator-based diagonalization, simplifying observable calculations.
  • Simulations show population inversion and boson quadratures for various extended models, including Stark shift and Kerr-like interactions.

Conclusions:

  • The generalized Hamiltonian provides a powerful and unified tool for studying a wide range of qubit-boson interactions.
  • This approach simplifies the theoretical treatment of complex quantum optical phenomena.
  • The framework is applicable to diverse scenarios, including those with non-linearities and multi-boson processes.