DE1944078A1 - Optical molecular amplifier - Google Patents

Description

Optical Molecular Amplifier The invention relates to a optical molecular amplifier with a rod-shaped stimulable medium, a stable pump light source and a hollow cylinder-shaped pump mirror, which the stimulable medium and the pump light source arranged parallel to it in its Extension includes Optical molecular amplifiers are intended in this context also understand such molecular amplifiers whose output radiation is in the infrared or the ultraviolet spectral range, i.e. not directly in the range of the visible Radiation lies.

Bio-enhancers of this kind have due to the generated by them Coherent radiation has found a variety of uses in particular In metrology, the use of optical molecular amplifiers has resulted in processes with great measuring accuracy0 measuring devices with optical molecular amplifiers, especially those with high output powers, however, are very expensive and Relatively expensive compared to the relevant microwave measuring devices. Also their external dimensions are especially in arrangements with high output power that a cooling device the pump light source and the stimulable medium required for the Use in portable devices is still undesirably large.

The invention is based on the object of an optical molecular amplifier indicate the at holioi energy of its generally impulsive output Radiation gets by with extremely small dimensions and that with guarantee the properties otherwise to be promoted on such a radiation source in mobile use.

This object is achieved according to the invention in that the pump mirror, the pump light source and the stimulable medium from an injection-molded one Housings are included, the connection supports open to the housing interior for the connection to an outer cooling circuit, the coolant of which the remaining interior of the pump mirror is completely filled. Further are in opposite one another Wall parts of the housing for receiving the ends of the pump light source and the stimulable Medium designed as elastic mounts openings provided at the same time serve to seal the interior of the housing from the exterior.

An optical molecular amplifier with a hollow cylinder-shaped pump mirror, in its interior the rod-shaped stimulable medium and the rod-shaped pump light source are arranged parallel to one another and parallel to the wall of the pump mirror, can with very small dimensions, on the order of only a few centimeters, carry out. The housing surrounding the pump mirror can be in a simple manner Injection molding processes, for example from plastic, are used in this constructive manner Solution is given a way to make an optical molecular amplifier very cheap to manufacture Through the formation of a closed cooling circuit, a such optical molecular amplifiers also use in portable devices comes as well the shock-insensitive storage of those at risk of breakage Parts, namely those made of crystalline material, for example ruby against the stimulable medium and the pump light source.

In a first preferred embodiment, it is in the form of a hollow cylinder Pump mirror designed with an elliptical cross-section, the major semi-axis of which is essentially larger than the outer diameter of the pump light source or the stimulable medium is.

In a second preferred embodiment, it is in the form of a hollow cylinder Pump mirror designed as a circular cylinder and the arrangement with respect to the pump light source and the stimulable medium dimensioned as an exfocal circular cylinder system.

A very simple and inexpensive embodiment of the invention optical hollow amplifier consists in the fact that the actual pump mirror is a metallic mirror coating, preferably a thin gold layer, is that immediately is applied to the cylindrical inner wall of the housing.

For high output power, it is recommended as a mirror support for the reflective surface layer of the pump mirror is a metallic hollow cylinder to be used, around which the coolant also flows on its outer surface.

To further increase the cooling effect of the coolant, the as Metallic hollow cylinders with openings for the passage of the pump mirror Provide coolant. In the space between the inner surface of the housing and the outer surface of the hollow cylinder are also flow rates J Resistors arranged in this way and designed so that the coolant flows around the pump mirror on all sides.

In a further development of the optical molecular amplifier according to the invention are the electrodes of the rod-shaped pump light source also flowed around by the coolant, by the wall parts of the housing receiving the ends of the pump light source expanded around the electrodes of the pump light source to form a tubular casing are0 To prevent premature aging of the plastic parts, namely the seals and of the housing to prevent the intense radiation from the pump light source the surfaces exposed to the radiation with a substantially opaque one Coating provided by the inclination of the end faces of the rod-shaped, stimulable Medium at the Brewster angle against the rod axis, it is possible in a simple manner to directing the output beam so that it is amplified by the connector caps Ends of the pump light source and its power supply lines are conveniently passed by Such a beam deflection is particularly advantageous when the Electrodes of the pump light source included in a cooling circuit and for this purpose with a tubular sheath are provided.

On the basis of the embodiments shown in the drawing the invention will be explained in more detail below.-Mean in the drawing 1 shows a section through a first exemplary embodiment of the optical molecular amplifier with air-cooled electrodes of the pump light source, FIG. 2 shows a section through a second embodiment the optical molecular enhancer, in which the electrodes of the pump light source are also included in a cooling circuit , Fig. 3 is the side view of the second embodiment according to Fig.2, Fig.4 the cross-sectional representation of the second embodiment according to Figure 2, Figure 5 a Arrangement of the optical molecular amplifier with optical resonator according to the invention.

The optical molecular amplifier shown in Figure 1 consists of essentially from a hollow cylindrical pump mirror 1 and the one in its interior arranged rod-shaped, stimulable medium 2 with the parallel lying Rod-shaped pump light source 30 The actual pump mirror is a mirror support 1 "is applied to a tubular, metallic mirror carrier 1 '. That is the pump mirror 1 accommodating housing 7 is'mit two connecting pieces open to the housing interior 22 provided by a ring-shaped flow resistance 23 on the inner wall of the housing it is ensured that the coolant, for example water, is severely hindered, to take the direct route between the two connecting pieces. The pump mirror 1 is provided with two openings 24 through which the Xühlmittel ein bzvi. step out can. These two openings are for better flow through the interior of the pump mirror arranged opposite one another and axially offset. The stimulable medium 2 and the pump light source 3 are ill mutually opposite parts of the housing 7 stored. These wall parts are designed in three layers. she consist of a central one enclosed by two rigid plates 5 and 6 elastic end plate 4. When assembling the optical molecular amplifier the outer rigid plate 5 is screwed against the housing. The middle elastic end plate 4 deformed and against the stimulable medium 2 and the Pump light source 3 pressed. In this way, in addition to an elastic bearing of the stimulable medium and the pumping light source, a \ nrequirements sufficient Sealing of the housing interior achieved, the cross section of the openings in the rigid plates 5 and 6 is chosen to be slightly larger than the diameter of the Pump light source and the stimulable medium corresponds. This ensures that the stimulable medium and the pump light source only on the elastic end plates 4, the two inner rigid plates 6 are used to hold the pump mirror 1 equipped with a conical, annular elevation 6 '.

To prevent the material of the elastic closure plates 4 in the immediate area of their openings for the passage of the pump light source, and, if necessary, the stimulable medium at an early stage through the intensive Radiation of the pump light source is destroyed, the end plates are in the above Areas with an at least approximately opaque, which cannot be seen in the figures Covering 7, for example, a metal layer provided in the manner shown in FIGS 4 illustrated second embodiment of the optical molecular amplifier the electrodes 3 'of the pump light source 3 are also included in a second cooling circuit As in the exemplary embodiment described in FIG. 1, the stimulable Medium 2 and the pumped light source 3 are stored in elastic end plates 4. These are again embedded between two rigid plates 5 and 6. The outer rigid plates 5 extend in the area of the pump light source 3 expanded to form a tubular casing 25. The end of the tubular jacket 25 is closed with a cuff 27 containing a sealing ring 26. The coolant in this circuit passes through the connection stub 28 into the cavity 29 of the tubular casing 25 at the end of the electrode of the pump light source. In order not to obstruct the radiation from the stimulable medium 2, the casing is 25 partially brought up close to the pump light source 3. The housing 7 Adjacent section of the casing 25 is therefore also designed to be rectangular At this point there is a good between the casing 25 and the pump light source 3 thermally conductive piece of sheet metal 30 placed, the ends of which dip into the coolant not to heat the plastic casing too much. The coolant then occurs, as can be seen in Fig. 4, through two openings in the elastic End plate 4 and the inner rigid plate 6 in the interior of the housing 7 a The position of these openings is shown in Pig. 4 in a broken line. The coolant flows through such openings in the end plates on the opposite side of the housing 7 further to the other electrode 3 'of the pump light source and after it has passed the interior of the casing 25, it emerges from the other Connection piece 28 from. For cooling the stimulable medium 2 and the one in the pump mirror 1 arranged part of the pump light source 3, a second cooling circuit is provided. The pump mirror 1 is for better cooling of the pump light source 3 and the stimulable Medium 2 is provided with slot-shaped openings 31 lying opposite one another which extend over almost its entire length So that the whole broad the slot-shaped openings 31 are uniformly flowed through by the coolant, are those that support the two connecting pieces 28 for the second cooling circuit Housing walls across the width of the openings 31 end with "flow resistances" Rows of holes 32 provided. The connecting pieces 28 are in their, the housing facing portion to a chamber 33 expanded so that each a whole Row of holes is detected. The flow resistances 34 visible in FIG tubular inner surface of the housing 7 are used to separate the two cooling circuits in the area of the housing.

Fig. 5 illustrates how the optical molecular amplifier according to 1 as an assembly on a further assembly containing an optical resonator is arranged in a modular design. The assembly containing the stimulable medium 2 is easily detachable from the base plate 12 for easy replacement attached. The, fastening can e.g. by screws or a simple plug lock to be achieved. The optical resonator is firmly connected to the base plate of two mirrors, one of which is a multiple etalon 8 and the other is a 90 -Prism 9 is formed. The 90 ° prism is used to generate a pulse-shaped Output radiation arranged to be rotatable about axis 10. The end faces of the stimulable Medium 2 are in the arrangement shown at the Brewster angle against the Inclined rod axis The multiple etalon 8 and the 90 0 prism 9 are therefore -not Transmitters arranged slightly offset directly in the rod axis of the stimulable medium. The Mehfachetalen 8 is partially permeable, so that one in the Rbsenanzstellung The light pulse triggered by the 900 prism 9 is emitted through the Mehzfachetalon 8 will.

This constructive solution one with a quality-modulated optical Optical molecular amplifier provided with a resonator can be used for many measuring ranges Application. With such arrangements in particular, it is extremely advantageous to that all components that can be expected to have a short service life in one assembly are summarized. This cheap assembly, which is a replacement unit If the pump light source fails, for example, it is simply removed and through replaced another, which makes maintenance of the melocular amplifier extremely easy in practice means.

5 Figures 9 claims

Claims (8)

P a t e n t a n s p r ü c h e Optical X40lektPlar amplifier with a rod-shaped, stimulable medium, a rod-shaped pump light source and a hollow cylinder-shaped pump mirror, which contains the stimulable medium and the corresponding pumping light source arranged in parallel includes in its extension, d a d u r 0 h it is noted that the pump mirror (1), the pump light source (3) and the stimulable medium (2) from a housing manufactured by injection molding (7) are included, the connection piece (22) open to the housing interior for the connection to an outer cooling circuit, the coolant of which the remaining interior of the pump mirror (1; completely filled, and that in opposite Wall parts of the housing (7) for receiving the ends of the pump light source (3) and of the stimulable medium (2) designed as elastic mountings openings are provided, which at the same time to seal the housing interior against the Serve outside space. 2. Optical molecular amplifier according to claim 1, characterized in that that the hollow cylinder-shaped pump mirror (1) has an elliptical cross-section, its major semiaxis insignificantly larger than the outer diameter of the pump light source (3) or the stimulable medium (2) 3. Optical molecular amplifier after Claim 1, characterized in that the hollow cylinder-shaped pump mirror (1) designed as a circular cylinder and with respect to the pump light source (33 and the stimulable Medium (2) is dimensioned as an exfocal circular cylinder system. 4. Optical molecular amplifier according to one of claims 1 to 3, characterized in that the actual pump mirror is a metallic mirror support, preferably a thin gold layer, which is directly on the cylindrical inner wall of the housing (7) is applied. 5. Optical molecular amplifier according to one of claims 1 to 3, characterized in that the mirror support (1 ') for the mirror support (1 ") of the Pump mirror (i) a metallic hollow cylinder is provided, which is also on his The coolant flows around the outer surface. 6. Optical molecular amplifier according to claim 5, characterized in that that the metallic hollow cylinder designed as a pump mirror (1) has openings (24) for the passage of the coolant, and that in the space between the housing inner surface and the outer surface of the hollow cylinder flow resistances (23) such are arranged and designed that the pump mirror (1) on all sides from the coolant is flowed around. 7. Optical molecular amplifier according to one of claims 1 to 6, characterized in that the electrodes (3 ') of the rod-shaped pump light source (3) from the coolant around-Urömt in which the receiving the ends of the pump light source Wall parts of the housing (7) around the electrodes of the pump light source to form a tubular sheath (25) are expanded. 8. Optical molecular amplifier according to one of claims 1 to 7, characterized in that the exposed to the radiation of the pump light source (3) Surfaces of the Plastic parts are essentially opaque Have coating. -9. Optical molecular amplifier according to one of Claims 1 to 8, characterized in that the end faces of the rod-shaped stimulable medium are inclined at the Brewster angle to the rod axis, Blank page