• DocumentCode
    953297
  • Title

    From thermostatistics to Maxwell´s equations: a variational approach of electromagnetism

  • Author

    Mazauric, Vincent G.

  • Author_Institution
    Corporate Res. Div., Schneider Electr., Grenoble, France
  • Volume
    40
  • Issue
    2
  • fYear
    2004
  • fDate
    3/1/2004 12:00:00 AM
  • Firstpage
    945
  • Lastpage
    948
  • Abstract
    The Maxwell equations are derived from thermodynamic principles. While flux density divergence-free is obtained everywhere from the stationary condition on the Gibbs\´ free energy, the Maxwell-Faraday equation and the Ohm\´s law with motion are obtained, in conductors, by assuming an adiabatic and reversible evolution of the field. Hence, the Maxwell-Faraday equation may be extended in the dielectric region for any time-varying excitation. Besides, magnetic- and dielectric-behavior laws result from the convexity of the magnetic and electrostatic Gibbs\´ potentials. Furthermore, the conservation of the power yields the so-called Lorentz force from virtual work principle. Extension to high frequency is also proposed beyond the plasma pulsation of metal. To sum up, the approach is shown to be: 1) consistent with the finite element method; 2) coherent with a coarse graining optimization, from "scratch" to the design scale; and 3) suitable to consolidate energy processes involved in electromagnetic and electromechanical conversion.
  • Keywords
    Maxwell equations; electromagnetic fields; electromagnetism; entropy; finite element analysis; Gibbs free energy; Lorentz force; Maxwell equations; Maxwell-Faraday equation; Ohm law; adiabatic evolution; coarse graining optimization; design scale; dielectric region; dielectric-behavior laws; electromagnetic fields; electromagnetism; electromechanical conversion; energy conversion; energy processes; entropy; finite element method; finite element methods; flux density; magnetic- behavior laws; plasma pulsation; power conservation; reversible evolution; stationary condition; thermodynamic principles; thermostatistics; time-varying excitation; variational approach; virtual work principle; Conductors; Dielectrics; Electrostatics; Finite element methods; Frequency; Lorentz covariance; Magnetic flux; Maxwell equations; Plasmas; Thermodynamics;
  • fLanguage
    English
  • Journal_Title
    Magnetics, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9464
  • Type

    jour

  • DOI
    10.1109/TMAG.2004.825419
  • Filename
    1284571