In optics, a GiresâÂÂTournois etalon (also known as GiresâÂÂTournois interferometer) is a transparent plate with two reflecting surfaces, one of which has very high reflectivity, ideally unity. Due to multiple-beam interference, light incident on a GiresâÂÂTournois etalon is (almost) completely reflected, but has an effective phase shift that depends strongly on the wavelength of the light.
The complex amplitude reflectivity of a GiresâÂÂTournois etalon is given by
where r<sub>1</sub> is the complex amplitude reflectivity of the first surface,<br>
Suppose that is real. Then , independent of . This indicates that all the incident energy is reflected and intensity is uniform. However, the multiple reflection causes a nonlinear phase shift .
To show this effect, we assume is real and , where is the intensity reflectivity of the first surface. Define the effective phase shift through
One obtains
For R = 0, no reflection from the first surface and the resultant nonlinear phase shift is equal to the round-trip phase change () â linear response. However, as can be seen, when R is increased, the nonlinear phase shift gives the nonlinear response to and shows step-like behavior. GiresâÂÂTournois etalon has applications for laser pulse compression and nonlinear Michelson interferometer.
GiresâÂÂTournois etalons are closely related to FabryâÂÂPérot etalons. This can be seen by examining the total reflectivity of a GiresâÂÂTournois etalon when the reflectivity of its second surface becomes smaller than 1. In these conditions the property is not observed anymore: the reflectivity starts exhibiting a resonant behavior which is characteristic of Fabry-Pérot etalons.