DE10241984A1 - Optically pumped solid body laser comprises at least one intracavity laser crystal having two spaced regions having different doping material concentrations - Google Patents

Abstract

Optically pumped solid body laser comprises at least one intracavity laser crystal (1) having at least one optical axis (2) along which a continuous pump light source or pulsed emitted pump light source is directed into the crystal. The laser crystal has two spaced regions having different doping material concentrations.

Description

Technical field

The invention relates to a optically pumped solid-state laser with at least one intracavitary arranged laser crystal, which has at least one optical axis, along the one of at least one pump light source continuously or pulsed emitted pump light beam is directed into the laser crystal.

Furthermore, the laser crystal has the Pump light beam absorbing dopants.

In the US 6,185,235 B1 describes a diode-pumped solid-state laser that has been designed with a high light output and high beam quality. For this purpose, the longitudinally diode-pumped solid-state laser has a laser crystal which has only a very low dopant concentration of less than 0.5% dopant content within the entire laser crystal. In this way it is possible to optically excite the entire length of the laser crystal with a powerful diode pump light source without running the risk that the pump light is almost completely absorbed in the area of the light entry within the laser crystal. The principle described in this document of extending the absorption length of the pump light radiation along the laser crystal by means of reduced laser crystal doping enables the use of powerful diode pump light sources, but also reduces the optical efficiency of the laser crystal with a lower doping concentration, which in turn adversely affects the actually achievable output power of the solid-state laser effect.

Another possibility to optically excite laser crystals with high-power pump light sources without destroying the laser crystal or causing the adverse effects of thermal lens effects and the resulting induced birefringence on the optical beam path is provided by optical excitation apart from the absorption peak of the laser crystal. Absorption peaks or bands of known laser crystal materials, such as Nd: YAG and Nd: YVO ₄ , are in the range of 808 nm. An alternative, equally frequently used laser crystal, Nd: YLF, absorbs, for example, in the wavelength range between 792 and 797 nm Pump light wavelength chosen just such that it lies just next to the absorption peaks or absorption bands of the respective laser crystals, this measure also leads to a lower absorption capacity within the laser crystal, so that the use of light-powerful pump light sources is made possible.

Depending on the type of pumping light source can be used accordingly Assembled pump light sources, for example diode lasers, targeted chosen whose emission pump light wavelengths are strong or less strong deviate from the absorption peak of the laser crystal. It is also possible to Pump light wavelength through change to change the operating temperature of the laser diode accordingly, especially since the pump diode wavelength of the operating temperature typically changes at 0.25 nm per degree Kelvin.

The invention is based on the object an optically pumped solid-state laser with at least one intracavitary arranged laser crystal, which has at least one optical axis, along the one of at least one pump light source continuously or pulsed emitted pump light beam is directed into the laser crystal, and contains dopants absorbing the pump light beam, such to further develop the use of powerful pump light sources for the purpose of scaling the output light power to higher values than is possible with previous techniques. In particular the aim is to have a more effective pump light absorption within the laser crystal to create without heating the laser crystal too much, thereby the formation of strong thermal lenses and the associated induced birefringence reduced within the laser crystal can be.

The solution of the basis of the invention Task is specified in claim 1. The idea of the invention advantageous further education features are the subject of the subclaims as well the description with reference to the embodiments.

According to the invention is an optically pumped solid-state laser according to the characteristics of claim 1 designed such that the laser crystal at least two spatially Regions spaced apart from one another in the direction of the optical axis which has about have different dopant concentrations.

In contrast to the previously known, doped laser crystals in which the dopant concentration evenly within of the entire laser crystal volume is distributed, sees the idea of the invention a targeted uneven distribution in the manufacture of the laser crystal in the dopant concentration at least along the optical axis of the Laser crystal. In this way it is possible to do the spatial Adjust the absorption behavior of the laser crystal individually and adapt to the respective pump light output.

In a particularly preferred embodiment, the optically pumped solid-state laser provides a longitudinally pumped laser crystal, which is a first in relation to the pump light beam ten surface over which the pump light beam enters the laser crystal, and provides a second side surface over which the pump light beam exits the laser crystal along the optical axis. A dopant concentration profile is introduced within the laser crystal by way of laser crystal production in such a way that the dopant concentration increases from the side of the first side surface along the optical axis in the direction of the second side surface. The dopant concentration profile can in principle be gradual or step-wise; the level of the dopant concentration and its course preferably depend on the pump light power actually applied within the laser crystal. With a suitable adjustment to the pump light power actually introduced into the laser crystal along the optical axis, with a suitable design of the doping, the absorption of the pump light radiation and thus also the heat introduced within the laser crystal is distributed uniformly over the crystal length or parts of the crystal length.

So the pump light beam on the Way along through the laser crystal depending on the concentration of the dopant atoms weakened by absorption, so that starting from a maximum input pump light output and one in the range of first side surface provided minimum dopant concentration the dopant concentration increases to a maximum value in the direction of the region of the second side face, especially since the pump light beam just before it emerges from the laser crystal through the second side surface has dropped to a minimum light output due to absorption. The local dopant concentration is preferably within of the laser crystal just chosen so that the absorbed pump light power per volume element within the crystal is largely constant.

Depending on the choice of pump light intensity and training of the pump light beam profile individual dopant concentration profiles within the laser crystal be provided.

A further advantageous embodiment provides a dopant concentration profile from minimal doping in the area of the first side surface a maximum value of dopant concentration up to approximately in the middle of the laser crystal is reached, which is constant to the second side surface along the optical axis remains.

Both explained above Laser crystal doping is suitable for unidirectional radiation with pump light, i.e. the pump light beam passes through the laser crystal from the first to second side surface and then kicks through a corresponding resonator end mirror from the solid-state laser out.

Optically pumped solid-state laser systems are also known, the pump light beams often within the resonator are reflected back and forth and thus the laser crystal several times lengthways traverse its optical axis. They are also optically pumped Solid-state lasers known whose laser crystals act on both sides with pump light beams become. As a rule, there are two separate pump light sources for this provided, the pump light beams by means of suitable optical fiber optics longitudinally through the first and second side surface of the Laser crystal are coupled. For such a bilateral A laser crystal is preferably suitable for optical pump light arrangement with a dopant concentration profile that runs symmetrically to the center of the laser crystal, that from the side of the first and second side surface of the Laser crystal the dopant concentration from a minimum to a maximum value prevailing in the center of the laser crystal. In this case, too, by individually adjusting the dopant concentration profile with regard to the pump light intensity introduced into the laser crystal that the absorption efficiency and the associated warming of the laser crystal along remains largely evenly distributed over the entire optical axis, whereby the thermal load of the laser crystal within limits and the training one through crystal warming associated thermal lens effect and an induced Birefringence can be largely avoided.

Alternatively to that explained above one-piece Formation of the laser crystal with a not necessarily symmetrical dopant concentration profile running to the center axis of the laser crystal, sees another execution option two separate laser crystals in front, each with comparable absorption properties exhibit. Both laser crystals each have one first and second side surface and see a dopant concentration profile from the side of the first side surface increases towards the second side surface. Both laser crystals are longitudinal their common optical axis within the resonator introduced that their respective second side surfaces are medium or immediate are opposite. Both laser crystals are preferably by means of bonding or with a corresponding one Firing technique over their second side in each case firmly attached to each other. Providing two separate laser crystals, as explained above, opens up also the basic one possibility two different types of laser crystals in a single solid-state laser resonator to integrate.

In a particularly advantageous manner are suitable as YAG or laser crystals doped with neodymium atoms YVOa crystals (vanadate). Alternatively, there are other dopant atoms to disposal: Yb, Cr, Tm, Ho or Er.

Depending on the concept and performance range, the following doped laser crystals of the following types are available for the implementation of solid-state lasers: Nd: YAG, Nd: YVO ₄ , Nd: YLF, Nd: GVO ₄ , Nd: YPO ₄ , Nd: BEL, Nd: YALO, Nd: LSB, Yb: YAG, Yb: FAB, Cr: LiSAF, Cr: LiCAF, Cr: LiSGAF, Cr: YAG, Tm-Ho: YAG, Tm-Ho : YLF, Er: YAG, Er: YLF or Er: GSGG.

The invention is hereinafter without restriction the general inventive concept based on exemplary embodiments described by way of example with reference to the drawing. Show it:

1a Laser crystal with constant dopant distribution

1b Laser crystal with continuously increasing dopant distribution, as well

1c Laser crystal combination with mirror-symmetric dopant distribution.

Ways to Execute the Invention, industrial applicability

In 1a is a known laser crystal 1 shown schematically over an optical axis 2 , a first side surface 3 as well as a second side surface 4 features. It is assumed that the laser crystal 1 according to 1a by means of a single pump light beam P, which is along the optical axis 2 through the first side surface 3 into the laser crystal 1 occurs, is optically pumped.

That under the laser crystal 1 The diagram shows that the laser crystal has a constant dopant concentration D along its entire length L (see the horizontal dashed line). Starting from an initially constant high pump light output occurs in the area of the side surface 3 inside the laser crystal 1 very strong absorption on that along the optical axis 2 towards the second side surface 4 due to the decrease in pump light intensity due to absorption processes (see decreasing continuous function curve).

In contrast, looks according to 1b the laser crystal 1 one from the side of the face 3 towards the side surface 4 along the optical axis 2 increasing dopant concentration D before (see dashed lines in the diagram). The dopant concentration profile D is tuned as a function of the pump light intensity P such that it runs along the entire length L of the laser crystal 1 which, as in the previous case study 1a is pumped on one side with a pump light beam P, the pump light absorption A remains almost constant. At this point, the associated advantage already mentioned, namely a largely uniform heat deposition within the laser crystal through light absorption and a thermal lens effect which is only weakly developed per unit volume, is again pointed out here.

However, according to 1c a laser crystal arrangement on both sides over both side surfaces 3 . 4 optically pumped, see pump light beams P and P ', two joined laser crystals are suitable 1 . 1' that one according to the diagram 1c have a running dopant concentration profile. Here the two laser crystals border 1 . 1' with their second side faces 4 . 4 ' immediately together. These can advantageously be provided by means of bonding or by means of wringing.

Both laser crystals 1 . 1' have in the same way on the part of the first side surface 3 . 3 ' towards their second side surface 4 . 4 ' increasing dopant concentration profile according to the dashed line in 1c on. If such a laser crystal arrangement is optically pumped from two opposite sides, the absorption effect on the pumping light beams remains largely constant along the entire laser crystal length L in this case (see horizontal line according to the diagram in 1c ).

It is typically recommended Dopant concentrations in a range between 0.1% and 0.5 % to choose, it is assumed that with pump light outputs of at least 10 W is being worked on.

1, 1'

laser crystal

2

optical axis

3, 3 '

First side surface

4, 4 '

Second side surface

P

Pumping light beam

Claims (16)

Optically pumped solid-state laser with at least one intracavitary laser crystal, which has at least one optical axis, along which a pump light beam emitted continuously or in a pulsed manner is directed into the laser crystal and contains dopants that absorb the pump light beam, characterized in that the laser crystal has at least two has spatially spaced regions in the direction of the optical axis, which have different dopant concentrations. An optically pumped solid-state laser according to claim 1, characterized in that the laser crystal is along the optical axis Has dopant concentration profile that is gradual or step-shaped is. Optically pumped solid-state laser according to claim 1 or 2, characterized in that the intracavitarily arranged laser crystal has at least a first side surface over which the Pump light beam falls into the laser crystal, and that the dopant concentration increases along the optical axis from the first side surface at least to the center of the laser crystal according to a predetermined dopant concentration profile. Optically pumped solid-state laser according to claim 1 or 2, characterized in that the intracavitary laser crystal a first side surface over which the pump light beam is incident in the laser crystal, and one of the first side surfaces along the opposite optical axis second side surface has that the dopant concentration along the optical axis of the first side surface to the second side surface gradual or gradual increases. Optically pumped solid-state laser according to claim 3, characterized in that the dopant concentration of the Center of the laser crystal to one of the first side surface along the opposite optical axis second face after a predetermined dopant concentration profile decreases. Optically pumped solid-state laser according to claim 5, characterized in that two pump light beams are provided, one of which is along to the optical axis through the first side surface and the other along optical axis directed through the second side surface into the laser crystal is. Optically pumped solid-state laser according to claim 1 or 2, characterized in that two laser crystals along one common optical axis are arranged intracavitarily, that the laser crystals each have a first and a second side face, that the dopant concentration along the optical axis of the first to the second side surface decreases within the laser crystals, and that the second faces of the two laser crystals are directly or indirectly opposite. Optically pumped solid-state laser according to claim 7, characterized in that the second side surfaces of the the two laser crystals are joined together by means of bonding or wringing technology. Optically pumped solid-state laser according to claim 5 or 6, characterized in that two pump light beams are provided are, of which one through the first side surface of the one and the other through the first side surface of the other laser crystal is directed. Optically pumped solid-state laser according to claim 6 or 9, characterized in that the two pumping light beams can be emitted from a single pump light source and by means of beam splitters and beam steering to which at least one laser crystal can be guided, or that two pump light sources are provided, from which the pump light beams exit each. Optically pumped solid-state laser according to one of claims 2 to 10, characterized in that the dopant concentration profile such in proportion selected for pump light output is that due to pump light absorption within the laser crystal brought in warmth longitudinally at least in some areas the optical axis is largely equally distributed. Optically pumped solid-state laser according to one of claims 1 to 11, characterized in that the pump light source is a diode laser or is a diode laser arrangement. Optically pumped solid-state laser according to claim 12, characterized in that the diode laser has a pump light power of at least 10 W. Optically pumped solid-state laser according to one of claims 1 to 13, characterized in that the laser crystal with one or several of the following dopants is doped: Nd, Yb, Cr, Tm, Ho or Er. Optically pumped solid-state laser according to claim 14, characterized in that the laser crystal consists of the following doped crystals: Nd: YAG, Nd: YVO ₄ , Nd: YLF, Nd: GVOa, Nd: YPO ₄ , Nd: BEL, Nd: YALO, Nd : LSB, Yb: YAG, Yb: FAB, Cr: LiSAF, Cr: LiCAF, Cr: LiSGAF, Cr: YAG, Tm-Ho: YAG, Tm-Ho: YLF, Er: YAG, Er: YLF or Er: GSGG , Optically pumped solid-state laser according to one of claims 1 to 15, characterized in that the dopant concentration within of the laser crystal between 0.01% and 1%, preferably between 0.1% and 0.5%.