FR2535072A1 - Optical phase-shifting device and application to a laser generator. - Google Patents

Abstract

The device comprises, successively applied one on top of the other, a substrate 5, a reflecting metal film 4, a transparent dielectric plate 1 and a grating 2 formed from equidistant parallel conducting wires (lines) 3. Application to laser generators.

Description

Optical phase shift device and application to a laser generator
The present invention relates to an optical phase shift device and an application of this device to a laser generator.

 There are known phase shift optical elements such as quarter wave birefringent plates which make it possible to modify the polarization of a laser beam by optical phase shift of the radiation. These optical plates have the disadvantage of having two dioptres, perpendicular to the beam, which cause annoying parasitic reflections, in particular in telemetry. In addition, when the laser beam is of great power, for example in the case of a laser applied to machining, the blade can undergo significant heating by absorption of optical power.

 There are other devices, with multidielectric layers, for modifying the polarization of a laser beam by optical phase shift of the radiation. However, these devices have the drawback of being difficult to produce and of being sensitive to the conditions of the ambient environment.

 The object of the present invention is to overcome these drawbacks and to provide an optical phase shift device which is simple to make and easy to use.

 It relates to an optical phase shift device comprising at least one optical element, characterized in that the optical element comprises - a grid polarizer formed of a transparent dielectric plate and of a grid constituted by conductive metal wires arranged in a plane , parallel to each other, at equal distance from each other, this grid being applied to one face of the dielectric plate - and a plane reflective metallic film, one face of which is applied to the other face of the dielectric plate, this element being capable of modifying the phase of a beam of coherent monochromatic radiation whose wavelength is greater than the distance between the wires of the grid, the phase shift between the radiation leaving the element and the incident radiation being substantially proportional to the thickness of the dielectric plate.

 The present invention also relates to a laser generator comprising said optical device, characterized in that it further comprises, - another grid polarizer arranged parallel to the optical element, the grids of the optical element and of the another polarizer being opposite one another, so as to form with the optical element a resonant optical cavity, - an active medium disposed inside the cavity - and means for exciting the active medium, capable of causing the formation of amplified radiation in the cavity, part of this radiation leaving the cavity through the other grid polarizer so as to form a laser beam, the optical transmission coefficient of the other polarizer at grid being a function of the angle which the grid wires between the optical phase shift element and the other grid polarizer make between them.

 Particular embodiments of the object of the present invention are described below, by way of example, with reference to the accompanying drawings, in which - Figure 1 shows in space an embodiment of a optical device according to the invention, - Figure 2 schematically represents the path of a light beam through the optical device illustrated by Figure 1, - Figure 3 shows in space another embodiment of the optical device according to l invention - and Figure 4 schematically shows an embodiment of the laser generator according to the invention.

 In FIG. 1 is shown an optical element 10 comprising a grid polarizer formed by a transparent dielectric plate 1, for example made of germanium and by a grid 2 applied to one face of the plate 1. The grid 2 consists of metallic wires conductors 3 made for example of aluminum. The wires 3 may have, as shown, a rectangular section and are arranged in a plane, parallel to each other, at equal distance from each other.

 Preferably, an anti-reflective layer 23 is deposited on the dielectric plate 1 between said face of the plate 1 and the grid 2.

 The optical element 10 also comprises a reflective flat metallic film 4, one face of which is applied to the other face of the dielectric plate 1.

 Grid polarizers are known in the art and their properties are described in the American book "Handbook of optics" (WALTER G. DRISCOLL), Editor Mac Graw Hill, 1978 pages 10-72 to 10-77.

 The metal film 4 can be produced by vacuum deposition of a metal layer on the rear face of the plate 1, this face being opposite to that supporting the grid 2.

 Preferably, the optical element 10 is mechanically reinforced by a flat support 5 fixed for example by bonding to the other face of the metallic film. This support can be made of metal.

 In FIG. 2, the optical element 10 is shown diagrammatically, cut along a plane perpendicular to the plane of the grid 2 and parallel to the direction of the wires 3. To clarify this figure, the section of the optical element has been represented under form of a rectangle whose long sides represent respectively the grid 2 and the film 4, the interior surface of this rectangle, free of hatching, representing the dielectric plate 1.

 A coherent monochromatic radiation beam, the axis 6 of which is located in a plane of incidence coincident with the plane of the figure, propagates towards the grid 2. The wavelength of the radiation which is for example situated in the range infrared is greater than the distance "d" between the wires of the grid (see figure 1). The light vibration of the radiation has a component 7 parallel to the plane of incidence and a component 8 perpendicular to this plane. Component 7 is reflected> - chied by grid 2 along axis 9 with a phase shift t 1. Component 8 is transmitted entirely by grid, then is refracted in the dielectric plate 1, and arrives with an angle of incidence "a" on the reflective film 4 which reflects it with a phase t 2. The component 8 reflected on the film 4 again crosses the plate 1 and the grid 2 and leaves the optical element in a beam 11 after having underwent a phase shift t 3.

La valeur de Y 3 est donnée par l'expression

dans laquelle "e" représente l'épaisseur de la plaque diélectrique, "n" représente l'indice de réfraction de la plaque diélectrique et n A n la longueur d'onde du rayonnement. Ultimately, the total phase shift introduced by the optical element is equal to

The value of Y 3 is given by the expression

in which "e" represents the thickness of the dielectric plate, "n" represents the refractive index of the dielectric plate and n A n the wavelength of the radiation.

 In practice, in the vast majority of cases, the difference t can be neglected and expression 2 gives the total phase shift introduced by the optical element. The total phase shift is therefore proportional to the thickness of the dielectric plate.

 The optical element described above has the advantage of operating without loss of optical energy and of being able to operate with a beam at zero incidence (a = o).

 The relation 2 shows that it is possible to determine the value of "e", for # and "a" given, so as to obtain the desired phase shift.

k étant un nombre entier quelconque.For example, if a quarter wave phase shift is desired, corresponding to a value t of t 3, the angle "a" being 45 degrees, the thickness of the dielectric layer must be equal to one of the following values

k being any integer.

If we want a half-wave phase shift with a = 45 degrees, the thickness of the dielectric layer must be equal to

The device shown in FIG. 3 comprises on the one hand an optical element 10 of the type of that illustrated in FIG. 1 and an electric motor 12 whose output shaft is fixed on the element 10 so as to drive it in rotation about an axis 13 parallel to the plane of the grid of the element 10 and perpendicular to the direction of the wires of this grid.

 A beam of radiation of axis 15 situated in an incidence plane 14 parallel to the wires of the grid of the element 10 is reflected along a beam of axis 16. When the motor 12 rotates the element 10 around the axis 13, the angle of incidence of radiation on the reflective film of the element varies. By giving the thickness "e" of the plate a sufficiently large value, one then obtains a variation of the phase shift t between the beams 16 and 15, this variation being large enough to vary the polarization.

le déphasage ss t est égal à - + k (en supposant toujours t kaj )
2 de sorte qu'un faisceau incident polarisé linéairement donne, après ren- voi par le dispositif, un faisceau polarisé cireulairement. In particular, if, at a time of the rotation of the element 10, the angle of incidence "a" satisfies the following relation

the phase shift ss t is equal to - + k (always assuming t kaj)
2 so that a linearly polarized incident beam gives, after being returned by the device, a circularly polarized beam.

le déphasage Q # est égal à It, de sorte qu'un faisceau incident pola- risé linéairement donne, après renvoi par le dispositif, un faisceau à polarisation linéaire croisée.Similarly, if, at an instant in the rotation of the element 10, the angle of incidence satisfies the following relation

the phase shift Q # is equal to It, so that a linearly polarized incident beam gives, after return by the device, a beam with linear crossed polarization.

 In FIG. 4 is shown a laser generator, the resonant optical cavity of which is formed by an optical element 10 of the type illustrated in FIG. 1 and a grid polarizer 17 formed by a transparent dielectric plate on one face of which is applied. a grid formed by equidistant conductive wires. The element 10 and the polarizer 17 are arranged parallel to each other so that their grids are facing one another. The wires of the element and polarizer grids form an angle b between them.

 Inside an cavity is disposed along an axis 18 an active laser medium 19. The generator further comprises means 20 for exciting the active medium 19 in order to obtain the laser effect.

dans laquelle représente la longueur d'onde du rayonnement laser, + et t 2 étant toujours supposés égaux entre eux.In the laser cavity thus formed, the element 10 behaves like a totally reflecting mirror and the polarizer 17 like a partially transparent mirror whose equivalent reflection coefficient R is given by the following expression
R = 1 4 (1 - cos 4 b) (1
3 3 being the angle of the phase shift caused by the element 10, this phase shift satisfying the following expression

in which represents the wavelength of the laser radiation, + and t 2 being always assumed to be equal to each other.

 It is therefore possible to choose the angle b "so as to obtain a laser beam 21 leaving the cavity through the polarizer 17.

 By means, shown diagrammatically at 22, for rotating the polarizer 17 around the axis 18, it is possible to vary the equivalent reflection coefficient R of the cavity of the laser generator.

Claims (7)

1 / Optical phase shift device comprising at least one optical element, characterized in that the optical element comprises - a grid polarizer formed by a transparent dielectric plate (1) and a grid (2) constituted by metallic wires conductors (3) arranged in a plane, parallel to each other, at equal distance (d) from each other, this grid being applied to one face of the dielectric plate - and a reflective plane metallic film (4) one side of which is applied to the other side of the dielectric plate (1) this element (10) being capable of modifying the phase of a beam of coherent monochromatic radiation (6) whose wavelength is greater than the distance (d) between the wires (3) of the grid (2), the phase difference between the radiation (16) leaving the element and the incident radiation (15) being substantially proportional to the thickness (e) of the dielectric plate (1). 2 / Device according to claim 1, oaractérisé in that the grid polarizer further comprises an antireflection layer (23) disposed between the dielectric plate (1) and the grid (2). 3 / optical device according to claim 1, characterized in that it further comprises a planar support (5) fixed on the other face of the metal film (4). 4 / optical device according to claim 1, characterized in that it further comprises means (12) for rotating the optical element (10) about an axis (13) parallel to the plane of the grid (2) and perpendicular to the direction of the wires (3) of the grid, the rotation of the optical element causing a variation in the phase shift 5 / Device according to claim 1, characterized in that the thickness (e) of the dielectric plate (1 ) is chosen so as to obtain a half-wave phase shift. 6 / Device according to claim 1, characterized in that the thickness (e) of the dielectric plate (1) is chosen so as to obtain a quarter wave phase shift. 7 / laser generator comprising a phase shift device according to claim 1, characterized in that it further comprises - another polarizer (17) with a grid disposed parallel to the optical element (10), the grids of the optical element and the other polarizer being opposite one another, so as to form with the optical element (10) a resonant optical cavity, - an active medium (19) disposed inside the cavity - and means (20) for exciting the active medium, capable of causing the formation of amplified radiation in the cavity, part of this radiation leaving the cavity through the other grid polarizer (17) so as to forming a laser beam (21), the optical transmission coefficient of the other grid polarizer being a function of the angle (b) formed between them by the grid wires of the optical phase shift element (10) and by the 'other grid polarizer (17). 8 / laser generator according to claim 7, characterized in that it further comprises means (22) for varying said angle (b) that between them the grid son of the optical element and the polarizer.