Sum-frequency generation

For a description of experimental techniques using sum-frequency generation, see Sum frequency generation spectroscopy.

Sum-frequency generation (SFG) is a nonlinear optical process. This phenomenon is based on the annihilation of two input photons at angular frequencies $\omega _{1}$ and $\omega _{2}$ while, simultaneously, one photon at frequency $\omega _{3}$ is generated. As with any second order $\chi ^{(2)}$ phenomenon in nonlinear optics, this can only occur under conditions where:

The light is interacting with matter, which is asymmetric (for example, surfaces and interfaces);
The light has a very high intensity (typically from a pulsed laser).

Sum-frequency generation is a "parametric process",^[1] meaning that the photons satisfy energy conservation, leaving the matter unchanged:

\hbar \omega _{3}=\hbar \omega _{1}+\hbar \omega _{2}

A special case of sum-frequency generation is second-harmonic generation, in which ω₁=ω₂. In fact, in experimental physics, this is the most common type of sum-frequency generation. This is because in second-harmonic generation, only one input light beam is required, but if ω₁≠ω₂, 2 simultaneous beams are required, which can be more difficult to arrange. In practice, the term "sum-frequency generation" usually refers to the less common case where ω₁≠ω₂.

For sum-frequency generation to occur efficiently, a condition called phase-matching must be satisfied:^[2]

\hbar k_{3}\approx \hbar k_{1}+\hbar k_{2}

where $k_{1},k_{2},k_{3}$ are the angular wavenumbers of the three waves as they travel through the medium. (Note that the equation resembles the equation for conservation of momentum.) As this condition is satisfied more and more accurately, the sum-frequency generation becomes more and more efficient. Also, as sum-frequency generation occurs over a longer and longer length, the phase-matching must become more and more accurate.

Some common SFG applications are described in the article sum frequency generation spectroscopy.

References

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