DE1919821A1 - Molecular amplifier for high performance - Google Patents

Description

High Performance Molecular Amplifiers The invention relates to one Molecular enhancers for generating and / or amplifying very short, preferably Electromagnetic waves located in the optical range, consisting of a stimulable one Medium, a pump energy source and a pump energy to the stimulable Medium concentrating reflector system.

Molecular amplifiers can be used very well in pulse mode achieve high radiation energy densities in a narrow frequency range. This attribute the molecular amplifiers have a multitude of technical possible uses opened up.

Two important representatives of molecular amplifiers for the generation of high Impulse energies are the so-called giant impulse laser and the through amplifier according to the traveling wave principle. In both types, a stimulable medium, e.g. Ruby, irradiated with a pump energy source, usually an intense light source. The irradiated energy is generated by the inversion of the atomic level in the stimulable Medium saved. It can be in the form of stimulated radiation with coherent and monochromatic Properties are released again in a pulsed manner.

E; In contrast to the spontaneous, alo is an induced one Emission.

The maximum achievable values of the emitted pulse energy so far are in the order of 50 MW / ccm of the stimulable medium and a pulse width of about 10 nsec.

To generate maximum values of the emitted power in the order of magnitude of 1 GW, one is forced to use too large a volume (about 100 ccm) of the stimulable mediums to pass.

However, pumping larger volumes poses some problems. That The stimulable medium usually has a cylindrical shape for reasons of symmetry. To a high To obtain a medium energy density, the stimulable medium must be at least antithetic be pumped evenly. This can be done with thin rods (up to a diameter of of 1 cm) still meet reasonably well. In thicker dusts there is a uniform one However, illumination is no longer guaranteed. When using conventional reflector systems, such as the ellipsoid of revolution, the density of the pump energy increases along the axis of the stimulable medium increases strongly. On top of that, especially when it comes to optical Molecular amplifiers through thermal lens effect narrow the laser function near-axis areas of the rod are concentrated, so that at relatively low levels Power per volume partial energy flux densities arise that lead to destruction of the material.

The invention is based on the object of large cross-sectional areas and thus large volumes of the stimulable medium of a molecular amplifier to pump evenly and thus to achieve extremely high output power.

This object is achieved according to the invention in that dns can be stimulated Medium designed as a hollow cylinder and the outer diameter of the Radiation volume of the pump energy source at least equal to the outer diameter of the hollow cylindrical stimulable medium and the inner diameter of this Hollow cylinder is dimensioned such that over its entire cross-section a sets at least approximately constant inversion density.

The invention is based on the knowledge that a stimulable Medium in the form of a hollow cylinder is much more uniform over the entire cross-section can be pumped or inverted than is possible with rod form Rod-shaped stimulable media usually shows in the center of the cross-section a pronounced maximum As already mentioned, comes with particularly important Amrendungsfall the optical molecular amplifier added that Due to the thermal lens effect, the laser function is usually only limited to a narrow axis close to the axis Areas of the staff curtained. The rest of the rod volume contributes to the output power little, which necessarily leads to relatively low performance per unit volume of the stimulable medium leads. Through the formation of the stimulable medium as a hollow cylinder, this possibility is completely eliminated by the geometry. The uniform inversion density in the stimulable medium is therefore essential higher output powers per volume unit. There is also the possibility to move to larger volumes and thus the previously possible output power better known To greatly increase molecular enhancers. The output power that can be achieved with it Of course, they also require correspondingly high pump capacities that only come from pump energy sources can be applied, the outer diameter of their radiation volume at least is equal to the outer diameter of the stimulable medium. An arrangement of the Pump energy source in Inside the hollow cylinder, as it was known Having arrangements therefore certainly does not lead to the desired success To achieve high inversion density in the stimulable medium, it is advantageous to that the radiation volume of the pump energy source is rod-shaped or hollow-cylindrical is designed with a length that is at least approximately the length of the stimulable medium matches.

An approximately hollow cylindrical radiation volume with a high energy density can be achieved in that the hollow cylinder shape of the radiation volume Pump energy source through helical winding of an elongated pump energy source is approximated.

Mine particularly simple arrangement of the reflector system is obtained in that the pump energy source is a pump light source.

Such an arrangement of the reflector system is that the Mirror system is an ellipsoid of revolution or an elliptical cylinder, and that the stimulable medium and the pump energy source in this mirror system are exfocal are arranged.

To generate Ricsen pulses, the stimulable medium is in a Introduced resonator, which is advantageous with regard to the invention is that at least one of the two reflectors of the Depending so nator is ring-shaped is.

In order to carry out the adjustment of the resonator in a plane @ uncritically, is it favorable that one of the both reflectors of the resonator is designed as a beam-reversing prism.

A preferred embodiment of a molecular amplifier for amplification of signals is that the wave to be amplified is in the form of a hollow cylindrical Beam is fed.

A further increase in the maximum output energy of a molecular amplifier according to the invention is achieved that for the stimulable medium and / or the pump energy source a cooling device is provided.

With regard to an even pumping of the stimulable medium Over the entire cross-section there is a degree of freedom in the dimensioning of the Inner diameter of the stiiaulbaren medium achieved in that a further Pump energy source in the interior of the hollow cylindrical stimulable medium is provided on the basis of the exemplary embodiments shown in the drawing the invention will be explained in more detail.

It shows Fig.1a and ib the course of the inversion density over the Cross section of a rod-shaped and a hollow cylindrical stimulable medium according to the invention, Fig.2 in a schematic representation of the stimulable medium with cooling device and devices for generating giant pulses according to the Invention, Figure 3 in a schematic representation of the arrangement of the stimulable medium and the pump light source in a rotationally elliptical reflector system according to the invention.

The diagram in FIG. 1a shows the typical course of the inversion density I in a rod-shaped stimulable medium over the radius r or cross section shown. The curve shows a pronounced maximum in the center of the cross-section. Because of thermal reasons there is an upper limit of the inversion density determined by the material must not be exceeded, the mean inversion density remains (dashed drawn line) and thus the output power per unit volume of the stimulable Medium always relatively low. This leads to a temperature maximum in the rod axis, in other words, an area where the thermal energy can flow through, especially with thicker rods External cooling is difficult to dissipate. As mentioned earlier, this comes with optical systems usually a thermal lens effect of the adjustable medium is added, which concentrates the laser function even further on a narrow area around the rod axis.

For comparison, Fig. 1b shows the course of the inversion density in the hollow cylinder, which is used in the subject matter of the invention, over its cross-section shown. The course (in the drawn case with a weakly pronounced Maximum) depends on factors such as the design of the reflector system and the attenuation factor of the stimulable medium.

In any case, channel by choosing the ratio of inner and outer radius of the hollow cylinder, the inversion density also has an almost constant curve can be achieved with larger cross-sections. The mean inversion density (dashed drawn line) so hardly below the maximum occurring. A thermal lens effect of the material can also, if it occurs at all, the induced remission at most on a cylinder surface and not as with the rod constrain to one line.

The arrangement shown in Figure 2 is part of a giant pulse laser. The stimulable medium 1 is designed as a hollow cylinder. It contains in his Imlenraun a cooling pipe 2 through which the cooling liquid or cooling gas is pumped. This flows along the inner walls of the cooling tube 2 and the hollow cylinder and passes through the opening 3 off again. The Fabry-Perot type resonator made up of the two mutually parallel mirrors A, 4 'composed, closes next to the stimulable Medium 1 also has a saturable absorber 5. The saturable absorber prevents on, already at the beginning of the pumping process, i.e. still at low inversion densities incipient oscillation of the resonator. It blocks the resonator until as a result high inversion densities in the stimulable medium 1, a spontaneous remission is more considerable Intensity sets in and thereby transfers it to the saturated state. The resonator then comes into effect and the avalanche formation of the emission continues. For decoupling The mirror 4 of the resonator is partially transparent to the radiation energy released educated.

In the arrangement according to Figure 3, the stimulable medium 1 and the Pump energy source 6 in an ellipsoid of revolution 7 on opposite sides Sides each between a focal point 8, 8 'and the vertex adjacent to them arranged. The inner surfaces of the ellipsoid of revolution-7 are mirrored. The light from the pump energy source 6, one helical in this case upset Flashlight lamp, is via the reflection on the inner wall of the ellipsoid of revolution concentrated on the hollow cylindrical stimulable medium 1. The outer diameter of the radiation volume of the pump energy source 6 is to achieve the highest possible inversion density to achieve greater than that of the stimulable medium 1. A mirror of the resonator is replaced by a beam-reversing prism t ".

The roof angle of the prism is 900. A slight tilt of the Prism around its roof edge does not yet lead to beam migration from the resonator, because the incoming and outgoing radiation remains parallel. Adjusting the This makes the resonator less critical. Soohl on the representation of a cooling device for the stimulable medium as well as for the pump energy source, as well as on Q-switch and decoupling devices for the signal light was in favor of a clearer Representation omitted.

3 Figures 10 claims

Claims (10)

P a t e n t a n s p r ü c h e 1. Molecular amplifiers for generation and / or amplification of very short electromagnetic ones, preferably those located in the optical range cells, consisting of a stimulable medium, a pump energy source and a, the reflector system concentrating the pump energy on the stimulable medium, thereby characterized in that the stimulable medium (1) is designed as a hollow cylinder and the outer diameter of the radiation volume of the pump energy source (6) at least equal to the outer diameter of the hollow cylindrical stimulable medium (1) is and the inner diameter of this hollow cylinder is dimensioned such that An at least approximately constant inversion density over its entire cross-section adjusts. 2. Molecular amplifier according to claim 1, characterized in that since the radiation volume of the pump energy source (6) is rod-shaped or hollow-cylindrical is designed with a length that is at least @ napproximately with the length of the stimulable medium (1) matches. 3. Molecular amplifier according to claim 2, characterized in that the hollow cylindrical shape of the radiation volume of the pump energy source (6) by helical Winding an elongated pump energy source. 4. Molecular amplifier according to one of claims 1 to 3, characterized characterized in that the pump energy source (6) is a pump light source. 5. Molecular amplifier according to one of claims 1 to 3 and 4, characterized characterized in that the mirror system is an ellipsoid of revolution (7) or an elliptical one Cylinder, and that the stimulable medium (1) and the pump energy source (6) are arranged exfocally in this mirror system. 6. Molecular amplifier according to one of claims 1 to 5, in which the stimulable medium is introduced into a resonator, characterized in that that at least one of the two reflectors (4, 4 ') of the resonator is annular is. 7. Molecular amplifier according to claim 6, characterized in that one of the two reflectors of the resonator is designed as a beam-reversing prism (4 ") Is. 8. Molecular amplifier according to one of claims 1 to 5, characterized in that that the wave to be amplified is fed in in the form of a hollow cylindrical beam will. 9. Molecular amplifier according to one of claims 1 to 8, characterized in that that for the stimulable medium (1) undjoder the pump energy source (6) a cooling device is provided. 10. Molecular amplifier according to one of claims 1 to 9, characterized characterized in that a further pump energy source (6) in the interior of the hollow cylindrical stimulable medium (1) is provided. L e r s e i t e