Alkali-metal vapour cell, especially for an atomic clock, and manufacturing process

The invention claimed is: 1. An alkali-metal vapour cell, intended in particular for inclusion in an atomic clock, adapted to be associated with a laser for emitting an external input laser beam striking the cell and with a photodetector for receiving an external output laser beam exiting the cell, the laser beam having passed through the cell, said cell comprising, a housing having an upstream optical window and a downstream optical window and forming an optical cavity filled with alkali-metal vapour such as vapour containing cesium, and micro-optical means arranged in the optical cavity and comprising an upstream optical reflector and a downstream optical reflector for reflecting the laser beam, said reflectors being inclined relative to one other, the upstream reflector being inclined relative to the plane of the upstream window and to the axis of the input laser beam, such that: the external input laser beam passes through the upstream window to form an internal input laser beam, the internal input laser beam is reflected on the upstream reflector and deflected towards the downstream reflector to form an internal intermediate laser beam, the internal intermediate laser beam is reflected on the downstream reflector and deflected towards the downstream window to form an internal output laser beam, and the internal output laser beam passes through the downstream window to form the external output laser beam, said cell further comprising upstream deflection means for deflecting the input laser beam, said upstream deflection means being located upstream of the upstream reflector, and downstream deflection means for deflecting the laser beam reflected by the downstream reflector, said downstream deflection means being located downstream of the downstream reflector, so as to combine the deflection produced by the upstream deflection means with the deflection produced by the upstream reflector and to combine the deflection produced by the downstream deflection means with the deflection produced by the downstream reflector. 2. The alkali-metal vapour cell according to claim 1 , wherein the upstream reflector and the downstream reflector are arranged symmetrically relative to a transverse mid-plane of the cell. 3. The alkali-metal vapour cell according to claim 1 , wherein the input laser beam and/or the output laser beam forms a 90° angle with the internal intermediate laser beam, and/or the input laser beam and the output laser beam are arranged parallel to one another. 4. The alkali-metal vapour cell according to claim 1 , wherein the upstream reflector and the downstream reflector are spaced apart from each other, the spacing between them determining the dimension of the optical cavity and of the cell in the direction of axis of the internal intermediate laser beam. 5. The alkali-metal vapour cell according to claim 4 , wherein the spacing between the upstream reflector and the downstream reflector is between about 3 mm and about 9 mm, particularly between about 4 mm and about 8 mm, more particularly between about 5 mm and about 7 mm. 6. The alkali-metal vapour cell according to claim 1 , wherein the upstream optical window and the downstream optical window are arranged on one and the same side of the cell, in particular are formed by two portions separated by one and the same glass plate—or wafer. 7. The alkali-metal vapour cell according to claim 1 , comprising one and the same side of association with the laser emitting the input laser beam and with the photodetector receiving the output laser beam. 8. The alkali-metal vapour cell according to claim 1 , wherein the upstream deflection means, and where appropriate the downstream deflection means, are diffraction means associated with the upstream optical window and where appropriate with the downstream optical window. 9. The alkali-metal vapour cell according to claim 1 , wherein the reflectors and the deflection means, in particular the diffraction means, are chosen so as to maintain the circular polarization state of the laser beam during its path. 10. The alkali-metal vapour cell according to claim 1 , further comprising, in the optical cavity, one or more masks preventing the passage of the laser beam into unwanted area(s). 11. The alkali-metal vapour cell according to claim 1 , wherein the upstream reflector and the downstream reflector are formed by shaping, particularly by etching, a plate—or wafer, and comprise a reflective coating, particularly of metal, more particularly of aluminum. 12. The alkali-metal vapour cell according to claim 1 , comprising, in addition to the optical cavity, a dispenser cavity adjacent to and in communication with the optical cavity, suitable for receiving a dispenser of alkali metal such as cesium, the alkali-metal vapour which is generated by heating after sealing the cell migrating towards and into the optical cavity through the communication between the two cavities. 13. The alkali-metal vapour cell according to claim 1 , wherein the optical cavity is filled with alkali-metal vapour and a buffer gas. 14. The alkali-metal vapour cell according to claim 1 , having associated optical means for shaping the external input laser beam, in particular a quarter-wave plate and a collimating lens. 15. The alkali-metal vapour cell according to claim 1 , wherein the housing comprises, on one hand, a shapeable plate—or wafer shaped so as to form the recess of the optical cavity, the upstream reflector, the downstream reflector, if appropriate the recess of the dispenser cavity and the cleared area of the communication between the two cavities, and on the other hand, a glass plate—or wafer so as to form the upstream optical window and the downstream optical window and to close off the optical cavity, where appropriate the dispenser cavity, and with which are associated deflection means, in particular diffraction means, the glass plate—or wafer and the recess-shaped plate—or wafer being arranged opposite each other and sealed to one another, in particular by anodic bonding. 16. The alkali-metal vapour cell according to claim 1 , comprising a shapeable plate—or wafer etched so as to form the recess of the optical cavity, the upstream reflector, the downstream reflector, if appropriate the recess of the dispenser cavity and the cleared area of the communication between the two cavities, the upstream reflector and the downstream reflector being etched along the crystal planes of the constituent material of the shapeable plate—or wafer. 17. The alkali-metal vapour cell according to claim 16 , comprising a shapeable silicon plate—or wafer, etched with a pyramid shape along the crystal planes [111] at 54.7° so as to form the upstream reflector, the downstream reflector, and the recess of the optical cavity, and, in combination, upstream diffraction means for diffraction towards the adjacent outer edge of the cell and if appropriate downstream diffraction means with an angle of 19.48°. 18. A method for manufacturing an alkali-metal vapour cell according to claim 15 , wherein: a shapeable plate—or wafer—is provided and is shaped to form a recess or recesses, in particular is etched, so as to form the recess of the optical cavity, the upstream reflector, the downstream reflector, if appropriate the recess of the dispenser cavity and the cleared area of the communication between the two cavities, a glass plate—or wafer—is provided that is suitable for forming the upstream optical window and the downstream optical window and for closing off the optical cavity, if appropriate the cavity dispenser, the recess-shaped p