DE10139753A1 - Longitudinally pumped laser for reflecting/scattering pumped light has a source of pumped light to emit pumped light, a resonator with a first mirror, a laser medium with end surfaces and a surface area and a second mirror. - Google Patents

Abstract

A source (1) of pumped light emits pumped light (2). A resonator (4) has a first mirror (6). A laser medium (5) has two end surfaces (8,9) and a surface area (10). There is also a second mirror (7) for a pumped laser. The surface area of the laser medium is partly coated by a light-conducting layer (11) to reflect/scatter the pumped light. The light-conducting layer forms a surface area coating for a laser medium.

Description

The invention relates to a longitudinally pumped laser, which is at least constructed of a pump light emitting pump light source and a resonator with a first mirror, a having two end faces and a lateral surface Laser medium and a second mirror.

In the case of a longitudinally pumped laser, this is from a pump light source emitted pump light radiated into an end face of the laser medium. In interest For a good efficiency of the laser, the irradiated pump light must Laser medium are absorbed as completely as possible. An escape of the pump light The surface area of the laser medium must therefore be kept as small as possible.

In addition, the contact of the pump light with the lateral surface of the laser medium can be avoided by placing the pump light in the center as a beam with low divergence the laser medium is irradiated (e.g. DE 195 17 963) or with a short one Laser medium the pump light is focused into the laser medium (e.g. W. A. Clarkson, P.J. Hardmann, D.C. Hanna, High-power diode-bar end-pumped Nd: YLF laser at 1,053 µm, Optics Letters 23, 1363-1365 (1998)). A disadvantage of these two The procedure is that the laser medium only has a small part of its volume pump light shines through and is therefore poorly used.

There is also the possibility of the pump light by total reflection at the To keep the lateral surface of the laser medium in it (e.g. DE 29 62 1859 or C. Bibeau, R. Beach, S. Mitchell, M. Emanuel, J. Skidmore, C. Ebbers, S. Sutton and K. Jancaitis. High-power power 1 µm performance and frequency conversion of a diode-pumped Yb: YAG laser. IEEE Journal of Quantum Electronics 34, 2010-2019 (1998)). To do this, the angle of incidence of the pump light on the lateral surface must be greater than the total reflection angle remain. The sine of the total reflection angle results from the ratio of the refractive index of the surrounding medium to the refractive index of the laser medium. For example, the total reflection angle for one is off Nd: YLF existing laser medium, which is surrounded by water for cooling at 67.45 °. Taking into account the refraction at the air / laser medium transition, a maximum half divergence angle of 30.65 ° for a pump light beam that passes through Total reflection should be kept in the laser medium. Is the laser medium with curved end faces or non-cylindrical end pieces, so can divide the beam path of the pump light, thereby permitting the permissible divergence of the Pump lights is further restricted.

When using a pump light source with a strongly divergent pump light beam, additional optical components are inserted to reduce the divergence. In areas where the laser medium is held or against a surrounding one Cooling water chamber is sealed, additional losses occur due to the here lack of total reflection. Should the laser medium directly into a metallic Heatsinks are embedded, so is a pump light guide through total reflection not possible at all, since with this arrangement no total reflection at the Surface area of the laser medium occurs.

The object of the invention is to provide a laser of the type mentioned, with which radiated pump light is kept as completely as possible in the laser medium without that the disadvantages of the prior art described occur.

The object is achieved in that the lateral surface of the laser medium at least partly by one designed to be reflective and / or scattering for the pump light Light guide layer is surrounded. In the subclaims are further advantageous Embodiments of the invention called.

The advantage of the invention is that pump light sources with a beam divergence of almost 90 ° can be used and that the laser medium can also be used directly in a metallic Heatsink can be embedded without loss of irradiated Pump light comes over the outer surface of the laser medium.

The light guide layer is designed so that it the pump light in the Laser medium reflected or scattered back. It is also possible to get one transparent or opaque scattering layer combined with a reflective layer to use. Pump light that passes through the scattering layer is used by the reflecting layer reflected back into the laser medium.

A scattering layer has the advantage that it pumps the pump light evenly Laser medium distributed than would be possible with a purely reflective layer. As scattering layer, the outer surface of the laser medium itself can act by with a defined roughness at which it optimally scatters the pump light. A scattering effect can also be achieved by a reflective layer is provided with such roughness.

The light guide layer can be used as a coating on the outer surface of the laser medium be trained. For this, e.g. B. a gold, silver or aluminum layer on the The outer surface can be evaporated or sputtered on, or it can be Coating can be produced by a dipping process. It is also possible to get one reflective coating by vapor deposition of suitable interference layers or to produce dielectric layers.

In a further embodiment of the invention, the outer surface of the Laser medium placed around a film, the outer surface of the laser medium facing surface serves as a light guide layer. The film can e.g. B. made of gold, Silver or aluminum exist.

Another material can be used for the film, which is then on the the surface of the laser medium facing surface with a reflective material such as B. gold, silver or aluminum or one Interference layer or dielectric layer is coated. This Embodiment is particularly advantageous if the laser medium directly into one metallic heat sink to be embedded. In the interest of an optimal Thermal contact is made between the two half-shells Heat sink and the outer surface of the laser medium a ductile film made of z. B. Indium placed. If the two half-shells are then pressed together, they deform ductile foil and fills the gap between the heat sink and the lateral surface of the Laser medium optimally. Will this ductile film on the surface of the Laser medium side facing coated reflective, so it also serves as Light guide layer.

Furthermore, it is possible to have a first around the lateral surface of the laser medium reflective film and then additionally put a ductile film. It can also do that The outer surface of the laser medium has a reflective coating and then a ductile film to be placed around them.

In principle, the invention can be used for all types of longitudinally pumped lasers, especially for solids. In addition to the components mentioned, the laser other components such. B. further laser media, nonlinear crystals for Frequency conversion, polarization filter, Q-switch, etc. can be used. The Both mirrors of the laser can be connected to the laser medium or they can be designed as separate components. The cross-sectional area of the Laser medium can be both round and square. As a pump light source, everyone can suitable light sources such as B. lasers, laser diodes, laser diode arrays, Light-emitting diodes, discharge lamps, white light sources, etc. are used.

The pump light can be directly, via a coupling optics and / or an optical fiber in the Laser can be coupled. The pump light can be, in this case, as Coupling mirror serving the mirror of the laser into the laser medium be coupled. Is one of the two mirrors at a suitable distance from arranged the laser medium, the pump light can also be inclined to the optical Axis past the mirror into the laser medium. Furthermore is it is possible to use a pump light with one of the end faces of the laser medium to couple the connected end piece into the laser medium.

The invention is explained in more detail using exemplary embodiments and the drawing.

In a schematic representation:

Fig. 1: a solid state laser with a coating designed as the circumferential surface of the laser medium light guide layer,

Fig. 2: a solid state laser with a set to a light-scattering-acting lateral surface of the laser medium gold foil as a light guide layer,

Fig. 3: a solid state laser with an embedded into a cooling-state laser medium and

FIG. 4: a variant of the solid-state laser according to FIG. 3, in which an indium foil coated with gold is used.

In the laser shown in FIG. 1, the pump light 2 generated by a pump light source 1 is coupled into a resonator 4 via an optical fiber 3 . As pump light source 1 comes z. B. a laser diode array is used. The resonator 4 consists of a laser medium 5 , a first mirror 6 serving as a coupling mirror and a second mirror 7 serving as a coupling mirror. The mirrors 6 and 7 are vapor-deposited as suitable interference layers on the end faces 8 , 9 of the laser medium 5 . The outer surface 10 of the laser medium 5 is vapor-coated with a gold layer 11 , which serves as a light guide layer.

The pump light 2 generated by the pump light source 1 reaches the coupling mirror 6 via the optical fiber 3 . It is designed as an interference layer that is transparent to the pump light but that is reflective to the laser light. In the laser medium 5, the pumping light propagates and is reflected back when passing through the circumferential surface 10 of the laser medium 5 of the light guide layer 11 in the laser medium. 5 The pump light 2 is largely absorbed on the way through the laser medium 5 . The laser generates laser radiation 12 , which leaves the resonator 4 through the coupling mirror 7 . The coupling-out mirror 7 is designed as an interference layer which is partially transparent to the laser radiation 12 but which is reflective for the pump light 2 .

The laser shown in FIG. 2 shows essentially the same structure as the laser of FIG. 1, but here the light-guiding layer is composed of a scattering layer 13 and a reflecting layer 14 . The scattering layer 13 is formed by the lateral surface 10 of the laser medium 5 provided with a defined roughness. The roughness is chosen so that the pump light 2 is optimally scattered. The reflective layer is made of the laser medium 5 facing surface 14 of a placed around the outer surface 10 of the laser medium 5 gold foil 15 °. The pump light 2 is partially scattered back into the laser medium 5 as it passes through the lateral surface 10 of the laser medium 5 . The other part of the pump light 2 is reflected back from the surface 14 of the gold foil 15 into the laser medium 5 and again scattered by the scattering layer 13 . As a result, the pump light 2 is distributed very evenly in the laser medium 5 .

In Fig. 3, another embodiment of the invention is illustrated. The structure of pump light source 1 and resonator 4 is the same as in FIG. 1. The laser medium 5 is embedded in a cooling body 16 consisting of two half-shells. For heat dissipation, the heat sink 16 is provided with a Peltier element (not shown). A gold foil 15 is placed around the lateral surface 10 of the laser medium 5 , whose surface 14 facing the laser medium 5 serves as a light guide layer. An indium foil 17 is arranged between this gold foil 15 and the heat sink 16 . When the two half-shells of the heat sink 16 are pressed together, the indium foil 17 deforms in such a way that it optimally fills the gap between the heat sink 16 and the laser medium 5 with the gold foil 15 that has been folded over and thus produces very good thermal contact between the laser medium 5 and the heat sink 16 .

In Fig. 4 a detail of a further embodiment of the invention is shown. The structure is the same as for the laser from FIG. 3, but here no gold foil is placed around the lateral surface 10 of the laser medium 5 . A gold layer 18 which is vapor-deposited on the side of the indium foil 17 facing the laser medium 5 acts as the light-guiding layer.

Claims (11)

1. Longitudinally pumped laser, at least constructed from a pumping light ( 2 ) emitting pumping light source ( 1 ) and a resonator ( 4 ) with a first mirror ( 6 ), a laser medium having two end faces ( 8 , 9 ) and a lateral surface ( 10 ) 5 ) and a second mirror ( 7 ), characterized in that the lateral surface ( 10 ) of the laser medium ( 5 ) is at least partially composed of at least one light guide layer ( 11 , 13 , 14 , 18 ) that is reflective and / or scattering for the pump light ( 2 ) ) is surrounded. 2. Laser according to claim 1, characterized in that the light-guiding layer is formed as a coating ( 11 ) of the lateral surface ( 10 ) of the laser medium ( 5 ). 3. Laser according to claim 1, characterized in that the light guide layer is formed as a coating ( 18 ) of the laser medium ( 5 ) facing surface of a surface ( 10 ) of the laser medium ( 5 ) surrounding film ( 17 ). 4. Laser according to claim 2 or 3, characterized in that the coating is designed as a reflective metal layer ( 11 , 18 ). 5. Laser according to claim 4, characterized in that the metal layer ( 11 , 18 ) consists of gold, silver or aluminum. 6. Laser according to claim 2 or 3, characterized in that the coating is an interference layer or dielectric layer ( 11 , 18 ) which acts reflectively for the pump light ( 2 ). 7. The laser of claim 1, characterized in that the light guide layer as the laser medium (5) facing one of the laser medium is the outer surface (10) formed (5) surrounding the film (15) (14). 8. Laser according to claim 7, characterized in that the film ( 15 ) consists of gold, silver or aluminum. 9. Laser according to one of claims 2 to 8, characterized in that the light-guiding layer is composed of a reflective layer ( 14 , 18 ) and a scattering layer ( 13 ), the scattering layer ( 13 ) between the reflecting layer ( 14 , 18 ) and the laser medium ( 5 ) is arranged. 10. The laser as claimed in claim 9, characterized in that the lateral surface ( 10 ) of the laser medium ( 5 ) provided with a defined roughness serves as the scattering layer ( 13 ). 11. Laser according to one of claims 1 to 10, characterized in that it as Solid-state laser is formed.