Definition: the phenomenon that an input laser beam generates a beam with four times the optical frequency
Alternative term: fourth-harmonic generation
More general terms: nonlinear frequency conversion
Frequency quadrupling is a process of nonlinear frequency conversion where the resulting optical frequency is four times that of the input laser beam, which means that the wavelength is reduced by a factor of 4. That can be accomplished with two sequential frequency doublers (Figure 1). Another possibility would be to use a single frequency doubler and two sum frequency generation stages for mixing with residual pump light, but that approach is not common.
Figure 1: A typical configuration for frequency quadrupling: an infrared input beam at 1064 nm generates a green 532-nm wave in a first frequency doubler, and a second frequency doubler converts this to light at 266 nm.
A common type of frequency quadrupling configuration begins with a continuous-wave or pulsed Nd:YAG laser at 1064 nm for generating 532-nm light in a first frequency doubler stage (based e.g. on LBO = lithium triborate) and then 266 nm in a second stage (based e.g. on CLBO = cesium lithium borate). Such ultraviolet light is useful e.g. for pumping a dye laser or an optical parametric oscillator, for Raman spectroscopy in flames, or for laser material processing, e.g. the writing of fiber Bragg gratings.
Limited Lifetime due to Crystal Degradation
As explained in the article on frequency tripling, nonlinear crystals can be degraded during operation by the intense ultraviolet light. For frequency quadrupling, the correspondingly shorter UV wavelength tentatively cause stronger problems of that type, compared with frequency tripling, and lead to short lifetimes of crystals and other optics. Otherwise, similar aspects apply as discussed in the article on frequency tripling.
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