A New Computational Tool for Understanding Light-Matter Interactions

Abstract

Plasmonic resonance of a metallic nanostructure results from coherent motion of its conduction electrons driven by incident light. At the resonance, the induced dipole in the nanostructure is proportional to the number of the conduction electrons, hence 10-million times larger than that in an atom. The interaction energy between the induced dipole and fluctuating virtual field of the incident light can reach a few tenths of an eV. Therefore, the classical electromagnetism dominating the field may become inadequate. We propose that quantum electrodynamics (QED) may be used as a fundamental theory to describe the interaction between the virtual field and the oscillating electrons. Based on QED, we derive analytic expressions for the plasmon resonant frequency, which depends on three easily accessible material parameters. The analytic theory reproduces very well the experimental data, and can be used in rational design of materials for plasmonic applications.

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Document Details

Document Type
Technical Report
Publication Date
Feb 11, 2016
Accession Number
AD1007392

Entities

People

  • G. Lu

Organizations

  • California State University, Northridge

Tags

Communities of Interest

  • Advanced Electronics

DTIC Thesaurus Topics

  • Density Functional Theory
  • Electromagnetic Fields
  • Electromagnetism
  • Frequency Shift
  • Materials Science
  • Metallic Nanoparticles
  • Nanoparticles
  • Optical Properties
  • Physical Theories
  • Quantum Electrodynamics
  • Quantum Mechanics
  • Quasiparticles
  • Resonant Frequency
  • Scattering
  • Standing Waves
  • Surface Plasmon Resonance
  • Surface Plasmons

Fields of Study

  • Physics

Readers

  • Calculus or Mathematical Analysis
  • Nanoscale Plasmonic Nanotechnology
  • Plasma Physics / Magnetohydrodynamics

Technology Areas

  • Microelectronics
  • Quantum Computing
  • Quantum Science - Quantum Dots