Volume holograms are holograms where the thickness of the recording material is much larger than the light wavelength used for recording. In this case diffraction of light from the hologram is possible only as Bragg diffraction, i.e., the light has to have the right wavelength (color) and the wave must have the right shape (beam direction, wavefront profile). Volume holograms are also called thick holograms or Bragg holograms.
Volume holograms were first treated by H. Kogelnik in 1969 [1] by the so-called "coupled-wave theory". For volume phase holograms it is possible to diffract 100% of the incoming reference light into the signal wave, i.e., full diffraction of light can be achieved. Volume absorption holograms show much lower efficiencies. H. Kogelnik provides analytical solutions for transmission as well as for reflection conditions. A good text-book description of the theory of volume holograms can be found in a book from J. Goodman. [2]
A volume hologram is usually made by exposing a photo-thermo-refractive glass to an interference pattern from an ultraviolet laser. It is also possible to make volume holograms in nonphotosensitive glass by exposing it to femtosecond laser pulses. [3]
In the case of a simple Bragg reflector the wavelength selectivity can be estimated by , where is the vacuum wavelength of the reading light, is the period length of the grating, and is the thickness of the grating. The assumption is just that the grating is not too strong, i.e., that the full length of the grating is used for light diffraction. Considering that because of the Bragg condition the simple relation holds, where is the modulated refractive index in the material (not the base index) at this wavelength, one sees that for typical values () one gets , showing the extraordinary wavelength selectivity of such volume holograms.
In the case of a simple grating in the transmission geometry the angular selectivity can be estimated as well: , where is the thickness of the holographic grating. Here is given by ).
Using again typical numbers (), one ends up with , showing the impressive angular selectivity of volume holograms.
The Bragg selectivity makes volume holograms very important. Prominent examples are:
Volume holograms are holograms where the thickness of the recording material is much larger than the light wavelength used for recording. In this case diffraction of light from the hologram is possible only as Bragg diffraction, i.e., the light has to have the right wavelength (color) and the wave must have the right shape (beam direction, wavefront profile). Volume holograms are also called thick holograms or Bragg holograms.
Volume holograms were first treated by H. Kogelnik in 1969 [1] by the so-called "coupled-wave theory". For volume phase holograms it is possible to diffract 100% of the incoming reference light into the signal wave, i.e., full diffraction of light can be achieved. Volume absorption holograms show much lower efficiencies. H. Kogelnik provides analytical solutions for transmission as well as for reflection conditions. A good text-book description of the theory of volume holograms can be found in a book from J. Goodman. [2]
A volume hologram is usually made by exposing a photo-thermo-refractive glass to an interference pattern from an ultraviolet laser. It is also possible to make volume holograms in nonphotosensitive glass by exposing it to femtosecond laser pulses. [3]
In the case of a simple Bragg reflector the wavelength selectivity can be estimated by , where is the vacuum wavelength of the reading light, is the period length of the grating, and is the thickness of the grating. The assumption is just that the grating is not too strong, i.e., that the full length of the grating is used for light diffraction. Considering that because of the Bragg condition the simple relation holds, where is the modulated refractive index in the material (not the base index) at this wavelength, one sees that for typical values () one gets , showing the extraordinary wavelength selectivity of such volume holograms.
In the case of a simple grating in the transmission geometry the angular selectivity can be estimated as well: , where is the thickness of the holographic grating. Here is given by ).
Using again typical numbers (), one ends up with , showing the impressive angular selectivity of volume holograms.
The Bragg selectivity makes volume holograms very important. Prominent examples are: