DE2932204A1 - Optical pumping system for laser and maser matching spectrums - uses fluorescent elements fitted with metallic, dielectric or diffusive reflectors - Google Patents

Abstract

The optical pumping system is for lasers and masers and gives an improved match between the emission spectrum of the pump light source and the absorption spectrum of the laser material. It achieves a high light intensity with a low thermal loading of the active laser material. The pump light originates from one or more fluorescent bodies (2). The narrow ends of the fluorescent body are fitted with metallic, dielectric or diffusive reflectors. They prevent the fluorescent light from being coupled to the laser material. Clear intermediate bodies (10) are provided between the ends of each fluorescent body and that of the optical conductor.

Description

Device for the optical pumping of lasers and measles.

The efficiency of optically pumped lasers is all the more favorable, the better the emission spectrum of the pump light source with the absorption spectrum of the laser material and ae more light from the pump light source into the Laser medium can be concentrated.

If the inversion is incomplete, the degree of inversion depends on the intensity of the pump light.

To use a laser not only as an amplifier, but as a light source, that is to say, to operate a laser oscillator in self-excitation must have a certain Pump power density are exceeded, referred to below as the laser threshold will.

Finally, the output intensity of lasers increases with the pump power.

So far, lasers with gas discharge tubes (mostly xenon) or Incandescent lamps pumped with halogen additives. In both cases there will be a wide range with some lines created in it. In the most important embodiments in practice the laser rod is on the axis of a circular cylinder and is driven by a spiral-shaped gas discharge tube wrapped around. But it can also be in a focal line of an elliptical cylinder, in whose second focal line there is a linear Lamp is located. In both cases, the inner walls of the cylinder are mirrored1 around the Concentrate lamplight in the laser rod. The service life of the lamps is a few hundred hours at most, significantly less in high-performance operation. the end Often only a fraction of the wide range of laser-active material can be used will. The position of the emission lines is fixed and is therefore only available for a few materials cheap. With continuous operation of the lamps, the achievable power density is small amount.

Higher power densities are achieved by flash lamps, their service life however, decreases very sharply with the load.

The invention is based on the object of a device for optical To design pumps of lasers and measles with the simplest possible means Generates light with good efficiency and high intensity and the laser material that can be optimally absorbed by it. It will also be a great one Lifetime of the pump light source and a low thermal load on the laser-active Materials aspired to.

This object is achieved in that the pump light is one or more Comes from fluorescent bodies. The fluorescent body consists of a transparent one Material with a refractive index n> 1, (solid or liquid, organic or inorganic) in the fluorescent Particles are included that are impinging Absorb light and emit fluorescent light due to total internal reflection to a large extent is held and conducted in the fluorescent body. For example can it be organic fluorescent dyes in polymethyl methacrylate (Plg * A) or a liquid solution that is in a suitably shaped, transparent Vessel is located.

Gas discharge lamps are preferably used to excite the fluorescent body used. Since the light of many lamps is collected over a large area and on a small one Outcoupling surface of the fluorescent body can be concentrated, for example a narrow side of a plate-shaped fluorescent body, are high pump power densities achievable. It is noteworthy that the radiation density at this coupling-out point can be significantly higher than the radiation thickness inside the lamps. The continuous Operation of lasers with high output power is thereby made much easier and the efficiency can be increased considerably.

The arrangement according to the invention is also simple and cheap. In addition, it has a relatively long service life and only makes low demands like the adjustment accuracy because the pump light through light guide up tight is brought up to the laser-active material.

According to a further development of the invention, the emission spectrum is Fluorescent body matched to the absorption spectrum of the laser-active material. This increases the pumping efficiency.

According to a further embodiment of the invention, metallic, dielectric or diffuse reflectors such narrow sides of the Fluorescent body provided that the fluorescent light does not enter the laser material decouple. With a corresponding design of the device according to the invention there is almost no light for the laser excitation on the narrow sides of the fluorescent body lost.

According to a further development of the invention, there are fluorescent bodies between and laser-active material, clear light guides are provided. This has the advantage that the fluorescent body is easily exchangeable and that furthermore during use of very many lamps, which for spatial reasons are at a certain distance must be arranged by the laser-active material, the light of the fluorescent body, which should be located close to the lamps, the laser-active material without loss can be forwarded. In addition, the large distance between the lamps from the laser-active material whose heat load is reduced.

In the context of the invention, the pump device is also together with built the laser-active material in an internally reflective housing, wherein the mirror coating can be metallic, diffuse or dielectric. In this way can almost all of the light generated by the lamps, which is shorter than the excitation light for the laser, through the choice of suitable dyes for the pumping process can be made usable. This reflector guides the light that has not yet turned into fluorescent light was converted, as well as not carried away in the plates (fluorescent bodies) Fluorescent light to the plates always new. This gives you the choice of the dye concentration largely free.

According to a further embodiment of the invention, the housing reflector reflects only light that is excitation of the fluorescent body or the laseraiftiven material can be exploited. Such a selectively executed one Reflector lets through unusable light, for example infrared. This will the thermal load of the laser-active material as well as d e of the fluorescent body decreased.

According to a further embodiment of the invention, metallic or dielectric reflections at the points of the fluorescent body or light guide attached, where for structural reasons (e.g. brackets) total reflections are not guaranteed. This will reduce losses caused by the attachment of for example, brackets could occur, avoided.

According to a further embodiment of the invention, the laser-active material is surrounded by a sheath for thermal insulation, which is only covered by light guides or Fluorescent body parts interrupted and preferably on the one facing the lamps Surface is reflective. The fluorescent body or the laser-active one A cooling medium can flow around the material, which is also used for both areas can be different.

According to a further embodiment of the invention, devices are z. B. electro-optical, mechanical or acoustic type to modulate the intensity the pump light from the fluorescent bodies provided. In this way, the Laser beam can be modulated with simple means via the pump light, in particular when its intensity is only slightly above the laser threshold.

The modulation preferably takes place with a Kerr cell, there the Kerr effect can be switched particularly quickly and the geometric adaptation to it the fluorescent body geometry is easily possible. Because the fluorescent body can be made very thin and the layer thickness of the Kerr liquid with the Thickness of the fluorescent body matches, low switching voltages are sufficient for the Kerr effect.

According to a further development of the invention, the fluorescent bodies are Fibers, rods or narrow strips with any, but preferably round or rectangular cross-section. In practice, these fluorescent bodies are next to each other for example to a fiber mat or a plate made of narrow strips or Rods arranged, with at least one of the small end faces of such Elements the laser-active material or

facing a light guide and the decoupling point for pump light forms. In this way, only those light rays are directed whose direction of propagation does not deviate too much from the direction in which the light should be directed. The differences in the path of the light rays are therefore not very large, which is the case with is important for some modulation techniques.

The invention is explained with reference to the figures. They show: figure 1 shows a device according to the invention, FIG. 2 shows a modification according to FIG. 1 and FIG. 3 shows an open arrangement in which ambient light is used.

For the sake of clarity, electrical leads are shown in the figures and mechanical parts, e.g. B.

Brackets that do not contribute to the understanding of the invention are omitted been. In addition, the same parts are given the same reference symbols in all the figures Mistake.

In the figures, lamps are schematically indicated with 1 and fluorescent bodies with 2 designated. The exemplary embodiments are plate-shaped fluorescent bodies. For example, it can be organic fluorescent dyes in Plexiglas. However, the fluorescent bodies do not have to be plate-shaped, as in the examples shown be formed, but can assume any geometric shape in which the total reflection is guaranteed. When using fluorescent liquids be these are pumped through appropriate transparent housing.

3 is the cut through a laser rod. Between the fluorescent body 2 and the laser-active material 3 is no direct optical Contact. With a reflector 4 is designated, which surrounds the entire arrangement. Of the The reflector will generally be applied to the inside of a housing wall.

In contrast to the representation in Figures 1 and 2, the reflector not be cylindrical, but can e.g. B.

also have a cuboid shape or any other spatial shape.

With 5 is a cylinder for thermal insulation of the laser rod in relation to the heat development of the lamps. Appropriately is the The surface of this body facing the lamps, which is not necessarily cylindrical must be reflective. Reflectors 6 close in the representation according to the figure 3 from the fluorescent body on the side facing away from the laser-active material.

The light generated with conventional lamps 1 is partly in the Absorbs fluorescent plates 2 and emits fluorescent light. The biggest part of the fluorescent light is held in the plate due to total reflection (at n = 1.5 approx. 75%).

A light beam 7 from one of the lamps 1 hits directly or via the Reflector 4 on a fluorescent particle 8. By shaping or mirroring it is ensured that the fluorescent light 9 by total reflection to the laser rod 3 and is used there to excite the laser-active material.

Light guides can expediently be used in area 10. Switching elements for modulating the pump light, which are preferably in this area are arranged, are not shown for reasons of space.

The invention is not limited to the illustrated embodiments. In particular, a large number of other spatial shapes can be implemented.

12 claims 3 figures Blank page

Claims (12)

Claims. Device for the optical pumping of lasers and measles, d a d u r it is not indicated that the pump light is one or more fluorescent bodies (2) comes from. 2. Apparatus according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that the emission spectrum of the fluorescent body (2) on the absorption spectrum of the laser-active material (3) is matched. 3. Apparatus according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that metallic, dielectric or diffuse reflectors (6) on the narrow sides of the fluorescent body are provided that the fluorescent light does not enter the laser material out mopping. 4. Apparatus according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that clear light guides between the fluorescent body (2) and the laser-active material (10) are provided. 5. Apparatus according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that the pumping device together with the laser-active material (3) in an internally reflective housing (4) is constructed, the mirroring of which is metallic, can be diffuse or dielectric. 6. Apparatus according to claim 5, d a d u r c h g e -k e n n z e i c h n e t that the housing reflector (4) only reflects light that is necessary for the excitation the fluorescent body (2) or the laser-active material (3) can be used can. 7. Apparatus according to claim 1 and 3, d a d u r c h g e k e n n z E i c h n e t that metallic or dielectric reflections on the places of the fluorescent body (2) or light guide (10) are attached to which from For structural reasons (e.g. brackets), total reflection is not guaranteed is. 8. Device according to claims 1 and 3, d a d u r c h g e k e n n z e i c h n e t that the laser-active material (s) with a jacket (5) for thermal insulation is surrounded by light guides (10) or fluorescent body parts (2) is interrupted and preferably on the surface facing the lamps (1) is reflective. 9. Apparatus according to claim 8, d a d u r c h g e -k e n n z e i c It does not mean that the fluorescent body or the laseriçtisre material is from a cooling medium are flowed around. 10. The device according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that devices, e.g. B. electro-optical, mechanical or acoustic type, for modulation the intensity of the pump light from the fluorescent bodies are provided. 11. The device according to claim 10, d a d u r c h g e -k e n n z e i c h n e t that a Kerr cell between two polarizers to modulate the pump light Is used. 12. The device according to claim 1, d a d u r c h g e -k e n n z e i c h n e t that the fluorescent body (2) fibers, rods or narrow strips with any, but preferably round or rectangular cross-section.