NL8100754A - METHOD OF FORMING A LASER BUNDLE WITH A WAVE LENGTH OF 2.71 MICRON. - Google Patents

Description

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- 813014 / vdV

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Short designation: Method for forming a laser beam with a wavelength of 2.71 microns.

The invention relates to a method of forming a laser beam with a wavelength of 2.71 microns.

A known method for forming a laser beam with a wavelength of 2.71 microns is described in the American article "Production of population inversions among the electronic states atomic species by processes of intermolecular V * -> E energy transfer" (JA Blauer and 6.D. Hager) from "Electronic transition lasers" (JI Steinfeld) HIT Press, 1976, pages 105 to 111.

According to this method, a 10-gaseous mixture containing molecular hydrogen and argon is rapidly and vigorously compressed to bring the temperature of the mixture to a temperature above 5000 ° K and to form atomic hydrogen therein. The compressed mixture is then annealed by passing it through a nozzle and gaseous hydrobromic acid is injected into the gas stream leaving the nozzle. Hydrobromic acid reacts with atomic hydrogen to form vibrationally excited molecular hydrogen and 2 bromine atoms with quantum level ^ 2/2 'exc ** a ** e energy of molecular hydrogen is therefore transferred to bromine to form the bromine atoms of the state ^ 2/2 over * one ^ on 9an * excited state 202P ^ 2. The gas containing the excited bromine is passed through an optically resonant cavity.

According to this method, it is in principle possible to obtain an impulse laser with a wavelength of 2.71 microns by compressing the gaseous mixture. In practice, this method provides unsatisfactory and non-reproducible results.

On the other hand, it is not possible to obtain a continuous laser beam in this way.

The invention therefore relates to a method of forming a laser beam with a wavelength of 2.71 microns and industrial manufacturing of a laser transmitter capable of emitting such a .8100754 / a -2 beam.

The object of the invention is now to provide a method for forming a laser beam with a wavelength of 2.71 microns, wherein: 5 - atomic hydrogen is formed in a starting gas containing molecular hydrogen, - the gas containing the atomic hydrogen is annealed, by passing through by nozzles at a supersonic speed, - gaseous hydrobromic acid injects at the exit of the nozzles in the direction of flow of the gas, which acid reacts with atomic hydrogen to form molecular excited hydrogen 2 and atomic bromine with quantum level. where the excitation energy of the molecular hydrogen is transferred to 2 bromine to excite the bromine atoms to the level Pj / g - the gas exiting the samples and contains bromine atoms with the 2 level Pj in an optically resonant cavity, perpendicular to the axis of the cavity, leads to obtain at the exit of the cavity a laser beam with a wavelength of 2.71 microns, which is characterized by obtaining the formation of the atomic hydrogen in the gas by forming a high voltage electric discharge upstream of each nozzle, which discharge additionally forms vibrated molecular hydrogen, which excited molecular hydrogen, after passing through the nozzles, added to the hydrogen formed by the action of atomic hydrogen on hydrobromic hydrochloric acid to increase the number of bromine atoms that transition from the level to the level Ρ 1/2, the laser beam leaving the cavity being a continuous beam.

A particular embodiment of the present invention is, for example, described below with reference to the accompanying drawing, in which the figure shows in longitudinal section a laser transmitter for carrying out the method according to the invention.

In this figure, a number of cylindrical insulating tubes 1, 2, 3, etc., which are equal and mutually parallel, have inputs 9 in a plane perpendicular to the direction of the tubes .

An annular coaxial electrode 4 is arranged in each tube adjacent to the entrance 9. Another annular coaxial electrode 5 is provided at the exit of each tube.

The outlets of the cylindrical tubes are connected to a set of nozzles 7. Injectors 8 are placed downstream of the neck 6 of the nozzles. For example, each injector may be located in the common wall of two consecutive nozzles, so that the injection shaft 20 is oriented in the direction of flow of the gas in the nozzles. The injectors 8 are connected via tubes not visible in the figure to a device 16 for forming gaseous hydrobromic acid.

The nozzles open into a chamber 21 which is bounded by a cylindrical wall 11. This wall has two opposite openings which are impermeable to two closed openings by two cylindrical parts 12 and 13. These parts have two reflectors 14 and 15, respectively, arranged to form an optical resonant cavity along an axis 23 perpendicularly through the openings in the flow direction of the gas in the nozzles. The reflector 15 is partially transmissive to radiation with a wavelength of 2.71 microns.

Chamber 21, at the end opposite the nozzles, has a device 19 with a diffuser followed by a pumping system or a vacuum device.

The electrodes 4 and 5 are connected to a continuous high voltage current source 17 via a resistor 18.

The device shown in the figure works as follows.

A low pressure gas consisting of molecular oxygen, which can be diluted with a neutral gas such as helium or argon, is introduced into the tubes 1 via the inputs 9. This gas is subjected to the electrical discharges occurring in the elongated tubes between the electrodes 4 and 5 provided by the source 17 with a .8100754

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0 ά -4 charge with a large potential difference. By this discharge, the gas is brought to a temperature of about 400 to 500 ° K and hydrogen in atomic state and molecular hydrogen excited in level 1 is formed.

Preferably, the electric discharge is regulated such that the ratio E / p between the electric field E and the pressure p of the gas is between 2 and 10 V / cm.torr. This promotes the formation of level 1 hydrogen molecules. For example, 10 to 15 hydrogen molecules excited at level 1 and a few percent of hydrogen atoms can be obtained relative to the original hydrogen molecules.

The pumping system (or the vacuum device) discharges the gas present in the chamber 21, and the gas containing the molecular hydrogen excited at level 1 and the atomic hydrogen becomes 15 as it passes through the tubes and nozzles 7 into the chamber 21 tempered at a supersonic speed. To prevent the re-union of hydrogen atoms on the walls of the nozzles, they are preferably formed from a ceramic material or a metal coated with a polytetrafluoroethylene layer.

Gaseous hydrobromic acid is injected via the injectors at the discharge of the nozzles 8.

Atomic hydrogen reacts with hydrobromic acid to form molecular hydrogen excited at level 1 and 2 atomic bromine at level Pq / 2 Vo ^ 9 in the reaction equation: 25 H + HBr-> H „(1) + Br (2„). m 2 P3 / 2

To the hydrogen molecules excited at level 1, formed according to the reaction equation (1), are added the molecules from the electrical discharge. When this discharge is controlled as indicated above, the excited hydrogen molecules present in the gas at that moment mainly originate from the electric discharge.

.8100754 *% -5-

The excitation energy of the hydrogen molecules is then transferred to bromine, to bring the bromine atoms to the excited 2 quantum level according to the reaction equation:

Br (% / 2) + H2 (1) ± 5 Br (2P1 / 2) + H2 (0). (2) The feed which determines the excited hydrogen molecules constitutes by the discharge used, compared to the known method, a very important increase in the conversion of the gas mixture as regards bromine.

On the other hand, the reaction equation (2) is an equilibrium equation, so that a minimum amount of hydrogen excited at level 1 to hydrogen in the ground state is required to obtain the conversion of the content to bromine.

This minimum amount varies depending on the temperature of the gas. It is 3.2% at 200 ° K, 10.2% at 300 ° K and 18 * at 400 ° K.

In order to facilitate the conversion of the contents, the nozzles of the device according to the invention are of a type which allows a powerful annealing of the gas flowing through them. Preferably, a temperature of the mixture is thus obtained

20 tempered gas that is less than 300 ° K at a temperature of 500 ° K

upstream of the nozzles.

The excited bromine-containing annealed gas then flows through the optically resonant cavity 14-15, forming a continuous laser beam 22, through transition of the bromine atoms of the 2. Level Pjy2 ° P the level Pg / 2 * The continuous beam 22 leaving the partially transmissive reflector 15 has a wavelength of 2.71 microns.

For example, the pressure of the gas upstream of the nozzles may be between 20 and 100 torr, if the discharge tubes 30 have a diameter of 1 cm and a length of about 20 cm, the flow rate of the gas in the nozzles is approximately between 1, 5 Mach and 2 Mach are located, the two reflectors of the laser cavity are 8100754 6-6 mirrors with dielectric layers whose reflection coefficients are 100% and 97% at the wavelength of 2.71 microns, respectively.

Under these conditions, the specific laser power is 1 to 2 KW with a molecular hydrogen feed of 1 mol / sec.

5 The electrical efficiency (ratio of the laser energy to the excitation energy) is approximately $ 10.

The method according to the invention can be used in the manufacture of lasers for telemetry and spatial telecommunication.

8100754

Claims (7)

A method of forming a laser beam with a wavelength of 2.71 microns, in which - atomic hydrogen is formed in a starting gas containing molecular hydrogen, 5. the gas containing atomic hydrogen is annealed by passing through nozzles at a supersonic speed, - gaseous hydrobromic acid injects at the exit of the nozzles in the direction of flow of the gas, which acid reacts with atomic hydrogen to form vibratory molecular hydrogen and atomic bromine with quantum level ^ / 2, whereby the excitation energy of the molecular hydrogen is transferred to bromine to deposit the bromine atoms at level 2p Pl / 2 '- the gas exiting the nozzles and the bromine atoms with level 2 Pjy2 contained in an optically resonant cavity, perpendicular to the axis of the cavity, leads to obtain a laser beam with a wavelength of 2.71 microns at the exit of the cavity, characterized in that the formation of the atomic hydrogen is in the gas by forming a high voltage electric discharge upstream of each nozzle, which discharge additionally forms vibrated molecular hydrogen, which excited molecular hydrogen, after passing through the nozzles, is added to the hydrogen formed by the action of atomic hydrogen on hydrobromic acid about the number of bromine atoms that increase from the level of the level of the level of the laser beam leaving the cavity is a continuous beam. 2. A method according to claim 1, characterized in that the ratio between the electric field of the discharge and the pressure of the gas subjected to this discharge is between 81 and 75V. cm torr. A method according to claim 1, characterized in that the annealing of the gas is sufficiently strong that the temperature of the annealing gas is less than 300 ° K. Process according to claim 1, characterized in that the starting gas is pure hydrogen. Process according to claim 1, characterized in that the starting gas is a mixture of molecular hydrogen and a neutral gas. A method according to claim 1, characterized in that the discharge is generated longitudinally inside a tube located upstream of each nozzle. , 8100/54 V * 0}% t t t 1 I ^ ~; -J7 V ._ \ ï \ 5 * \ \ N $ CM cm £; 7 CM) \ S) '^ fernpK1 ° ill 11111111 10 - - Ή'ιϊ "CMV J? --- +? - üiiiiiPiii sjb" ii Ü ~ iE iE dE ii I it vVirvvvVVVV ^ _s IJ) I 1 tt IM - % CO8100754