Physics:Parametric process (optics)

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Short description: Interacting phenomenon between light and matter

A parametric process is an optical process in which light interacts with matter in such a way as to leave the quantum state of the material unchanged. As a direct consequence of this there can be no net transfer of energy, momentum, or angular momentum between the optical field and the physical system. In contrast a non-parametric process is a process in which any part of the quantum state of the system changes.[1]

Temporal characteristics

Because a parametric process prohibits a net change in the energy state of the system, parametric processes are "instantaneous". For example, if an atom absorbs a photon with energy E, the atom's energy increases by ΔE = E, but as a parametric process, the quantum state cannot change and thus the elevated energy state must be a temporary virtual state. By the Heisenberg Uncertainty Principle we know that ΔEΔt~ħ/2, thus the lifetime of a parametric process is roughly Δt~ħ/2ΔE, which is appreciably small for any non-zero ΔE.[1]

Parametric versus non-parametric processes

Linear optics

In a linear optical system the dielectric polarization, P, responds linearly to the presence of an electric field, E, and thus we can write

[math]\displaystyle{ {\mathbf P} = \varepsilon_0\chi{\mathbf E} = (n_r+in_i)^2{\mathbf E}, }[/math]

where ε0 is the electric constant, χ is the (complex) electric susceptibility, and nr(ni) is the real(imaginary) component of the refractive index of the medium. The effects of a parametric process will affect only nr, whereas a nonzero value of ni can only be caused by a non-parametric process.

Thus in linear optics a parametric process will act as a lossless dielectric with the following effects:

Alternatively, non-parametric processes often involve loss (or gain) and give rise to:

Nonlinear optics

Main page: Physics:Nonlinear optics

In a nonlinear media, the dielectric polarization P responds nonlinearly to the electric field E of the light. As a parametric process is in general coherent, many parametric nonlinear processes will depend on phase matching and will usually be polarization dependent.

Sample parametric nonlinear processes:

  • Second-harmonic generation (SHG), or frequency doubling, generation of light with a doubled frequency (half the wavelength)
  • Third-harmonic generation (THG), generation of light with a tripled frequency (one-third the wavelength) (usually done in two steps: SHG followed by SFG of original and frequency-doubled waves)
  • High harmonic generation (HHG), generation of light with frequencies much greater than the original (typically 100 to 1000 times greater)
  • Sum-frequency generation (SFG), generation of light with a frequency that is the sum of two other frequencies (SHG is a special case of this)
  • Difference frequency generation (DFG), generation of light with a frequency that is the difference between two other frequencies
  • Optical parametric amplification (OPA), amplification of a signal input in the presence of a higher-frequency pump wave, at the same time generating an idler wave (can be considered as DFG)
  • Optical parametric oscillation (OPO), generation of a signal and idler wave using a parametric amplifier in a resonator (with no signal input)
  • Optical parametric generation (OPG), like parametric oscillation but without a resonator, using a very high gain instead
  • Spontaneous parametric down-conversion (SPDC), the amplification of the vacuum fluctuations in the low gain regime
  • Optical Kerr effect, intensity dependent refractive index
  • Self-focusing
  • Kerr-lens modelocking (KLM)
  • Self-phase modulation (SPM), a [math]\displaystyle{ \chi^{(3)} }[/math] effect
  • Optical solitons
  • Cross-phase modulation (XPM)
  • Four-wave mixing (FWM), can also arise from other nonlinearities
  • Cross-polarized wave generation (XPW), a [math]\displaystyle{ \chi^{(3)} }[/math] effect in which a wave with polarization vector perpendicular to the input is generated

Sample non-parametric nonlinear processes:

  • Stimulated Raman scattering
  • Raman amplification
  • Two-photon absorption, simultaneous absorption of two photons, transferring the energy to a single electron
  • Multiphoton absorption
  • Multiple photoionisation, near-simultaneous removal of many bound electrons by one photon

See also

Notes

  1. 1.0 1.1 See Section Parametric versus Nonparametric Processes, Nonlinear Optics by Robert W. Boyd (3rd ed.), pp. 13-15.

References