WO1992015135A1

WO1992015135A1 - Laser

Info

Publication number: WO1992015135A1
Application number: PCT/EP1992/000295
Authority: WO
Inventors: Peter Reimer; Maximilian Reindl
Original assignee: Aesculap Ag
Priority date: 1991-02-23
Filing date: 1992-02-12
Publication date: 1992-09-03
Also published as: DE4105717A1

Abstract

A laser (1) has a source (2) of pumping radiation, a resonator arrangement, in which a crystal (3) made of a laser-active material is arranged between two mirrors (5, 6), and a reflector (12) that reflects the pumping radiation and directs it onto the crystal. In order to simplify the design of the laser and to generate laser beams having various wavelengths, an additional resonator arrangement having two mirrors (7, 8), between which is arranged a crystal (4) made of laser-active material, is located next to the source of pumping radiation and to the first resonator arrangement. The crystal of the additional resonator arrangement receives the pumping radiation of the single source of pumping radiation directly and over the reflector. The crystal (4) of the additional resonator arrangement is made of a different material than the other crystal (3), so that both crystals generate laser radiations within different wavelength domains.

Description

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A S E R

The invention relates to a laser with a pump radiation source, a resonator arrangement in which there is a crystal made of a laser-active material arranged between two mirrors, and with a reflector reflecting the pump radiation and directing it onto the crystal.

Such a laser arrangement is usually used to generate laser radiation with a specific wavelength by means of a laser-active crystal, for example with an Er.YAG laser crystal, radiation with a wavelength of 2.94 μm or with an NdrYAG laser crystal a wavelength of 1.06 μm.

If radiation in several wavelengths is required, these laser devices must be made available separately for each wavelength. H. the complete equipment for each laser must be available.

It is an object of the invention to design a generic laser in such a way that it can generate radiation of a plurality of wavelengths, the outlay on equipment being reduced compared to conventional devices. This object is achieved according to the invention in the case of a laser of the type described at the outset in that, in addition to the pump radiation source and in addition to the resonator arrangement, there is at least one further resonator arrangement with two mirrors and a crystal of laser-active material arranged therebetween that the crystal of the Another resonator arrangement is acted upon by the radiation of the single pump radiation source directly or via the reflector with the pump radiation and that the crystal of the further resonator arrangement consists of a material which is different from the material of the other crystal, so that the two crystals have a different wavelength ¬ Generate rich laser radiation.

In the context of the present invention, therefore, a single pump radiation source, for example a flash or arc lamp, is assigned not only a single resonator with a laser-active crystal, but at least one further resonator arrangement in which there is a further, different laser-active material. The laser-active material in the further resonator is also excited by the same pump radiation source, the reflector reflecting the pump radiation irradiating the laser-active crystals in all resonators.

It has surprisingly been found that with such an arrangement laser powers of the individual resonators can be achieved which are hardly lower than when only one resonator is operated with the respective pump radiation source. It is therefore possible to supply several laser resonators for different laser radiation with one pump radiation source, so that the apparatus structure is considerably simplified. This is because not only is there no further pump radiation source, but also the entire associated outlay, which is caused by network supply devices, cooling, etc. Each pump radiation source can be assigned, for example, two, three, four or even more resonators, each of which contains laser-active crystals, at least two of which are made of different materials. In any case, it is favorable if the reflector surrounds the pump radiation source and all the laser arrangements irradiated by it together.

Particularly good results can be achieved if the reflector reflects diffusely.

It is expedient if the pump radiation source is arranged in the middle between the resonators.

Particularly high efficiencies can be achieved if the laser-active materials of the resonators absorb in different wavelength ranges, since then the absorption of the individual crystals in no way influences that of the other crystals.

In the preferred embodiment, diaphragms that can be inserted into the beam path of the resonators are provided. In this way it is possible to specifically suppress the laser activity in different resonators, so that then only the laser resonators emit radiation in which no diaphragm is inserted. It can be provided, for example, that the diaphragms can be inserted in such a way that only one resonator oscillates at a time. Radiation with a certain wavelength can therefore be selected by inserting the diaphragms.

A laser which can be used in particular in the medical field is characterized in that one crystal is doped with erbium, the other with neodymium, for example one crystal can be an Er: YAG crystal, the other an Nd: YAG crystal. Crystal. Such a crystal can optionally be used to generate laser radiation which is used for cutting tissue or for coagulating tissue. The beams emerging from the resonators can be directed into a single beam path by optical means, but it is also possible that each of the beams emerging from the resonators is directed separately into its own radiation transmitter, for example into an optical fiber.

In another preferred embodiment it is provided that one crystal is doped with holmium or tulium, the other with neodymium.

The following description of preferred embodiments of the invention serves in conjunction with the drawing for a more detailed explanation. Show it:

1: a sectional view through a pump chamber with a pump radiation source and two laser resonators supplied by it;

Fig. 2 is a sectional view taken along line 2-2 in Fig. 1 and

3: a view similar to FIG. 2 with a pump chamber with four laser resonators.

The pump chamber 1 of a laser device shown in FIG. 1 centrally receives a pump radiation source 2, for example a flash lamp or an arc discharge lamp, which are supplied via a voltage supply in a manner not explained in the drawing. On both sides of this pump radiation source 2 there is a rod-shaped laser crystal 3 or 4, which extends over the length of the pump radiation source 2 and which consists of a laser-active material, for example Er: YAG or Nd: YAG. Each of the two laser crystals 3, 4 is arranged between two mirrors 5, 6 and 7, 8, respectively, with mirrors 5 and 6 on the one hand and mirrors 7 and 8 on the other each forming a resonator. These are therefore adjusted according to the wavelength emitted by the laser crystal. In each case one mirror 5, 7 of the two resonators is designed to be totally reflective, while the other mirror 6 or 8 is partially transparent, so that laser radiation can be coupled out of the respective resonator. The outcoupled radiation is directed via a partially transparent mirror 9 or, in the case of the other laser resonator, via a deflecting mirror 10 and this partially transparent mirror 9 into a single beam path 11 which leads out of the pump chamber 1.

The walls of the pump chamber 1 are designed as a reflector 12, the walls for the radiation from the pump radiation source 2 preferably being diffusely reflective, for example these walls can be made of plastic or of a metal mirror with a rough surface.

An orifice 13, 14 can be inserted into each laser resonator, which are shown in broken lines in the illustration in FIG. 1. A drive is generally assigned to these diaphragms 13 and 14, so that the diaphragm is either inserted in one of the resonators or, if radiation from both resonators is desired at the same time, in neither resonator. In operation, the pump radiation generated by the pump radiation source 2 falls on the laser crystals 3 and 4 in the same way, so that both crystals are excited and laser activity is generated in the respective resonators. As a result, laser radiation is coupled out of the two laser resonators, provided the diaphragms 13 and 14 are not inserted. The laser beams can be selectively interrupted by inserting the respective apertures 13 or 14, ie the user can easily select the radiation with the desired wavelength.

Overall, both laser resonators are supplied with only a single pump radiation source, so that the structure is very simple.

In the exemplary embodiment in FIG. 3, the pump radiation source 2 is surrounded by four correspondingly constructed laser resonators, each of which contains its own laser-active medium. All four resonators are pumped by a single pump radiation source. As in the exemplary embodiment of FIGS. 1 and 2, diaphragms can be inserted into the individual resonators in order to selectively switch them off.

Claims

P A T E N T A N S P R Ü C H E

Laser with a pump radiation source, a resonator arrangement in which there is a crystal made of a laser-active material arranged between two mirrors, and with a reflector reflecting the pump radiation and directing it onto the crystal,

characterized ,

that in addition to the pump radiation source (2) and next to the resonator arrangement (3, 5, 6) there is at least one further resonator arrangement with two mirrors (7, 8) and a crystal (4) made of laser-active material arranged between them, that the crystal ( 4) the further resonator arrangement is subjected to the radiation from the single pump radiation source (2) directly and via the reflector (12) with the pump radiation and that the crystal (4) of the further resonator arrangement consists of a material which is different from the material of the other crystal (3), so that the two crystals (3, 4) generate laser radiation in a different wavelength range. 2. Laser according to claim 1, characterized in that the reflector (12) surrounds the pump radiation source (2) as well as all the laser resonators irradiated by it.

Laser according to claim 1 or 2, characterized gekennzeich¬ net that the reflector (12) reflects diffusely.

Laser according to one of the preceding claims, characterized in that the pump radiation source (2) is arranged in the middle between the laser resonators.

Laser according to one of the preceding claims, characterized in that the laser-active materials of the resonators absorb in different wavelength ranges.

6. Laser according to one of the preceding claims, characterized in that insertable diaphragms (13, 14) are provided in the beam path of the resonators.

Laser according to Claim 6, characterized in that the diaphragms can be inserted in such a way that only one resonator oscillates at a time. 8. Laser according to one of the preceding claims, characterized in that one crystal consists of an erbium-doped material and the other of a neodymium-doped material.

9. Laser according to one of claims 1 to 7, characterized ge indicates that a crystal consists of a material doped with holmium or tulium and the other of a material doped with neodymium.

10. Laser according to one of the preceding claims, characterized by the fact that the beams emerging from the resonators are directed by optical means (9, 10) into a single beam path (11).

11. Laser according to one of claims 1 to 9, characterized in that each of the beams emerging from the resonators is directed separately into its own radiation transmitter.