Comparison of Quantum and Classical Local-field Effects on Two-Level Atoms in a Dielectric

Abstract

The macroscopic quantum theory of the electromagnetic field in a dielectric medium interacting with a dense collection of embedded two-level atoms fails to reproduce a result that is obtained from an application of the classical Lorentz local-field condition. Specifically, macroscopic quantum electrodynamics predicts that the Lorentz redshift of the resonance frequency of the atoms will be enhanced by a factor of the refractive index n of the host medium. However, an enhancement factor of (n2 + 2)/3 is derived using the Bloembergen procedure in which the classical Lorentz local-field condition is applied to the optical Bloch equations. Both derivations are short and uncomplicated and are based on well-established physical theories, yet lead to contradictory results. Microscopic quantum electrodynamics confirms the classical local-field-based results. Then the application of macroscopic quantum electrodynamic theory to embedded atoms is proved false by a specific example in which both the correspondence principle and microscopic theory of quantum electrodynamics are violated.

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Document Details

Document Type
Technical Report
Publication Date
Dec 24, 2010
Accession Number
ADA537520

Entities

People

  • Michael E. Crenshaw

Tags

DTIC Thesaurus Topics

  • Dielectrics
  • Dipole Moments
  • Electrodynamics
  • Electromagnetic Fields
  • Equations
  • Equations Of Motion
  • Field Conditions
  • Frequency
  • Materials
  • Optics
  • Physical Theories
  • Physics
  • Quantum Electrodynamics
  • Quantum Mechanics
  • Radiation
  • Refractive Index
  • Resonance

Fields of Study

  • Physics

Readers

  • Computational Modeling and Simulation
  • Plasma Physics / Magnetohydrodynamics
  • Quantum Dot Semiconductor Device Photonics and Graphene Optoelectronic Materials and THz Physics.

Technology Areas

  • Quantum Computing