NO810462L - PROCEDURE FOR AA MAKING A LASER RADIATION WITH WAVE LENGTH 2.71 m. - Google Patents

Description

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A known method for producing a laser beam with a wavelength of 2.71 ym is described in the American article: "Production of population inversions amohg the electronic states of atomic species by processes of intermolecular 'V»-»-E energy transfer" by J.A. Blauer and G.D. Hager on pages 105 - 111 of the work "Electronic transition lasers" (J.I. Stein-feid), published by MIT Press in 1976.

In this method, a gas mixture comprising molecular hydrogen and argon is shock-heated so that the temperature of the gas mixture is raised to over 5000°K and atomic hydrogen is formed in the mixture. The compressed mixture is then expanded by being passed through a nozzle, while hydrobromic acid in gaseous form is introduced into the gas stream leaving the nozzles. The hydrobromic acid reacts with the atomic hydrogen to form vibrationally excited molecular hydrogen and atomic bromine in the quantum level 2?2/ 2' The excitation energy of the molecular hydrogen is then transferred to the bromine to transfer the bromine atoms from the state 2 ^ 2/ 2 to ^an excited state< 2>p-|/2*The9ass containing the excited bromine is passed through an optical cavity resonator.

In principle, with this method it is possible to produce a laser pulse with a wavelength of 2.71 µ/m by compression of the gas mixture, but in practice it gives unsatisfactory and non-reproducible results. Furthermore, with this method, it is not possible to achieve a continuous laser beam.

The purpose of the present invention is to specify a reliable wavelength of 2.71 jjm and to provide a basis for manufacturing on an industrial scale a laser transmitter capable of emitting such a beam.

The present invention thus applies to a method for

to produce a Vlaser beam with a wavelength of 2.71^>m, the method being that: atomic hydrogen is produced in an initial gas comprising molecular hydrogen, the gas containing atomic hydrogen is expanded by passing it through nozzles at supersonic speed,

hydrobromic acid in gaseous form is supplied at the outlet of the nozzles in the direction of gas flow, so that this acid reacts with the atomic hydrogen to form vibrationally excited molecular hydrogen and atomic bromine in a quantum level 2^ 2/ 2'

and the excitation energy of the molecular hydrogen is transferred to the bromine - so that the bromine atoms are excited to the quantum level <2>Pi/2' and

the gas leaving the nozzles and containing bromine atoms in the level Pi/2 ^^^^ res an optical cavity resonator perpendicular to the axis of the resonator, to produce said laser beam with a wavelength of 2.71^m on the output side of the resonator.

On this background of the state of the art, the method has

according to the invention, as a distinctive feature, atomic hydrogen is obtained by creating a high-voltage electrical discharge upstream of each nozzle, this discharge also producing vibrationally excited molecular hydrogen, so that this vibrationally ion-excited molecular hydrogen, after having passed through the nozzles, is added to the which is produced by atomic hydrogen being affected by hydrobromic acid, so that the number of bromine atoms that pass from the level 2 ^ 2/ 2 to<2>^1/2 increases, and the laser beam that leaves the resonator a continuous beam.

The invention will be described in more detail by means of an embodiment and with reference to the attached drawing with a single figure, which shows a longitudinal section through a laser transmitter arranged to carry out the present method according to the invention.

The figure shows a number of cylindrical insulating tubes.

as indicated by reference numbers 1, 2 and 3, and which are equal and mutually parallel and equipped with inlet 9

which lies in a plane perpendicular to the pipes' axial direction.

A coaxial ring-shaped electrode 4 is arranged inside each of. the tubes at its inlet end 9. Another coaxial annular electrode 5 is arranged at the outlet end of each tube.

The outlets for the cylindrical tubes are connected by a set

. nozzles 7. Injectors 8 are placed downstream of constrictions 6 in the nozzles. Each injector 8 can e.g. be arranged in a wall that is common to two neighboring nozzles, so that the injection axis points in the gas flow direction 20 in the nozzles. The injectors 8 are supplied with hydrobromic acid in gaseous form through passages that are not shown in the figure, but are in connection with a source 16 for hydrobromic acid in gaseous form. The nozzles lead to a chamber 21 which is bounded by a cylindrical wall 11 with two diametrically opposite openings which are tightly covered by means of two cylindrical parts 12 and 13. These parts each carry a reflector 14 and 15 which is arranged to form an optical cavity resonator along an axis 23 which extends past the nozzle openings perpendicular to the direction of the gas flow through them. The reflector 15 is partially penetrating for radiation at the wavelength of 2.1} m.

At the end opposite the nozzles, the chamber 21 comprises an apparatus 19 with a diffuser followed by a pump system or a vacuum chamber in the downstream direction.

The electrodes 4 and 5 are connected to a high-voltage direct current source 17 through a resistor 18. The apparatus shown in the figure works in the following way.

A gas consisting of molecular hydrogen is supplied at low pressure through the inlets 9 for the pipes 1. This gas can be diluted with an inert gas, such as helium or argon. The gas is exposed to electrical discharge inside the pipes between the electrodes 4 and 5, which are separated from each other in the longitudinal direction of the pipe and is charged by the source 17 up to a high potential difference. The discharge brings the gas to a temperature of around 400 - 500^K and forms hydrogen in the atomic state as well as molecular hydrogen which is vibrationally excited in level 1.

The electric discharge is preferably set so that the ratio — E between the electric field E and the gas pressure p is between 2 and 10 V/cm x torr. This promotes the production of hydrogen molecules that are excited in level 1. In relation to the original hydrogen molecules, e.g. 10 - 15% of the hydrogen molecules can be excited in level 1 and a few percent of hydrogen atoms can be produced.

The pump system (or vacuum chamber) evacuates the chamber 21 and the gas containing molecular hydrogen excited in level 1 as well as atomic hydrogen expands when it passes through the pipes towards the chamber 21 through the nozzles 7 at supersonic speed. In order to avoid recombination of hydrogen atoms against the walls of the nozzles, these walls are preferably made of ceramic material or a metal coated with a layer of poly-tetrafluoroethylene.

Hydrobromic acid' in gaseous form is introduced at the outlet of the nozzles through the injectors 8.

Atomic hydrogen reacts with hydrobromic acid so that molecular hydrogen is formed which is vibrationally excited in level 1 and atomic bromine in level<2>^3/2 in accordance with the reaction equation:

The hydrogen molecules that are produced by the electrical discharge are in addition to the hydrogen molecules that are excited in level 1 and are produced by reaction (1). If the discharge is set as indicated above, the excited hydrogen molecules in the gas will in this case mainly be produced by the electrical discharge. "^ U^ J^^ Aj*-**- 1'^-

The excitation energy of the hydrogen molecules is then transferred to the bromine, so that the bromine atoms are brought to the excited quantum level 2P^2 * in accordance with the reaction equation:

In relation to the previously known method, the indicated addition of excited hydrogen molecules produced by the discharge will involve a very large increase of the inverted population in the bromine.

Furthermore, the reaction (2) is balanced so that a minimum amount of hydrogen excited in level 1 is necessary in relation to the amount of hydrogen in the ground level 0 to achieve a population inversion in the bromine. This minimum size varies as a function of the gas temperature. It is 3.2% at 200^K, 10.2% at 300^K and 18% at 40A.

To make it easier to achieve population inversion, the nozzle type used in the apparatus for carrying out the method of the invention produces a high degree of expansion for the gas passing through the nozzles. The temperature of the expanded gas is thus preferably kept below 300 K

for a temperature of 50 upstream of the nozzles.

The expanded gas containing excited bromine then passes through the optical cavity resonator 14 - 15. This leads to the formation of a continuous laser beam 22 of the bromine atoms falling from the level 2p-j/2 to n:"-v^et 2P3/2 ' The wavelength for this continuous beam leaving the partially penetrating reflector 15 is 2.71 µm.

It can be further stated that the gas pressure . upstream of the nozzles is between 20 and 100 torr. The discharge tubes have a dia-

in

meter of 1 cm and a length of around 20 cm. The gas flow velocity in the nozzles is between Mach 1.5 and Mach 2. The two reflectors for the laser resonator are mirrors with the electric layers, and their respective reflection coefficients are 100% and 97% at the wavelength 2.71^Jm.

Under these conditions, the emitted laser power will be 1 - 2 kW for a molecular hydrogen discharge of 1 mol/second.

The electrical efficiency (ratio between laser energy and excitation energy) is around 10%.

The present method according to the invention can be used to produce laser beams for distance measurement and for telecommunications in space.

Claims (6)

1. Method for producing a laser beam with a wavelength of 2.71 µm, the method being that: atomic hydrogen is produced in an initial gas comprising molecular hydrogen, the gas containing atomic hydrogen is expanded by passing it through nozzles at supersonic speed, hydrobromic acid in gaseous form is supplied at the outlet of the nozzles in the direction of gas flow, so that this acid reacts with the atomic hydrogen to form vibrationally excited molecular hydrogen and atomic bromine in a quantum level ^ 2/ 2' °<P/^^- s^~ the cation energy of the molecular hydrogen is transferred to the bromine so that the bromine atoms are excited to the quantum level <2> P^^' and the gas leaving the nozzles containing bromine atoms in the level "P-j/2 is supplied to an optical cavity resonator perpendicular to the axis of the resonator, to produce said laser beam with a wavelength of 2.71 JJm on the output side of the resonator, characterized in that atomic hydrogen is obtained by creating a high-voltage electrical discharge upstream of each nozzle, as this discharge also produces vibrationally excited molecular hydrogen, so that this vibrated ion-excited molecular hydrogen, after passing through the nozzles, is in addition to that produced by that atomic hydrogen is affected by hydrobromic acid, so that the number of bromine atoms that pass from the level p ^/ 2 the level 2pi/2 Increases' °9 ^a laser beam leaving the resonator is one continuous beam, 2. Method as stated in claim 1, characterized in that the ratio between the electric discharge field and the pressure in the gas which is exposed to the discharge is between 2 and 10 v/cm x torr. 3. Method as stated in claim 1, characterized in that the expansion of the gas is sufficiently high for the temperature of the expanded gas to be less than 300^K. 4. Method as stated in claim 1, characterized in that the initial gas is pure hydrogen. 5. Method as stated in claim 1, characterized in that the initial gas is a mixture of molecular hydrogen and a neutral gas. 6. Method as stated in claim 1, characterized in that the discharge is produced in the longitudinal direction by and inside pipes which are arranged upstream of each respective nozzle. IN