RU2053588C1 - Laser with active element built up of set of plane-parallel plates - Google Patents

Abstract

FIELD: quantum electronic instruments. SUBSTANCE: laser with active element built up of set of plane-parallel plates has open optical cavity, pump lamps, active element in the form of stack of plane-parallel plates made of stimulating material and optically isolated by transparent film which is in optical contact with plane-parallel plates. Film reflectivity index is lower than that of stimulating material and its thickness is equal to or smaller than quarter wavelength of laser radiation. EFFECT: improved laser power. 1 dwg

Description

 The invention relates to devices of quantum electronics, namely to powerful solid-state optical quantum generators (lasers).

A solid-state laser is known, the active element of which is made in the form of segments forming lenses of zero optical power and separated by gaps for the flow of coolant [1]
However, in this laser, most of the pump energy passes between the plates of the working substance of the active element, not being absorbed in them, as a result of which the efficiency of the entire device as a whole decreases.

 Closest to the invention is a laser [2] the active element of which is made in the form of a set of plane-parallel plates glued along the edges with a gap for the refrigerant in the central part.

 The disadvantage of this laser is that each plate generates independently of the others, i.e. radiation from individual plates of the active element will not be correlated in phase with each other (there will be no coherence over the cross section of the active element).

 In the proposed device containing an open optical resonator, pump lamps, an active element in the form of a package of plane-parallel plates of stimulating material, the plates are separated by a film of a material transparent to optical radiation having optical contact with the plates, the refractive index of the film being less than the refractive index of the plates, and the thickness the film is less than or equal to a quarter of the wavelength of the laser radiation.

 The use of an active element in the form of a package of plane-parallel plates of stimulating material separated by an optically transparent film with a refractive index lower than the refractive index of the stimulating material and a thickness of a quarter of the laser radiation wavelength allows one to correlate the phase of radiation from all plates, i.e. increase the coherence of radiation over the cross section of the active element.

 The drawing shows a laser with an active element from a set of plane-parallel plates.

 The laser consists of an open optical resonator 1, pump lamps 2, an active element 3, made in the form of a package of plane-parallel plates 4 of stimulating material, separated by layers 5, which are in optical contact with the plates 4, optically transparent, and the layers are made in the form of a film of material, having a refractive index less than the refractive index of the stimulating material and a thickness equal to or less than a quarter of the wavelength of the laser radiation.

 The laser operates as follows.

 The optical radiation from the pump lamps 2 enters the active element 3 and penetrates into each of the plates 4 by optical tunneling through the film 5. Due to resonant optical tunneling, energy is transferred from one plate to another, which leads to an increase in the coherence of radiation over the cross section of the active element. Open optical resonator 1 contributes to the accumulation of energy in the active element 3.

Claims (1)

 A LASER WITH AN ACTIVE ELEMENT FROM A SET OF FLAT-PARALLEL PLATES, containing pump lamps, an open optical resonator, and an active element in the form of a packet of plane-parallel plates of stimulating material, separated by layers having optical contact with the plates and transparent to optical radiation, characterized in that the layers are made in the form film from a material whose refractive index is less than the refractive index of the wafer material and the film thickness is less than or equal to a quarter of the laser radiation wavelength.

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