WO2000003293A1 - Method and device for optical frequency conversion and light source containing said device - Google Patents

Abstract

The invention relates to a device for optical frequency conversion in which the beam (2) of a primary light source (1) after a first passage (32) though a non-linear optical medium (5) is deflected (and refocused) by a suitable optical system (35) in such a way that the beam of the primary light source together with the beams having other wavelengths and generated during the first passage carries out at least one further passage (33) through the non-linear optical material (5), which considerably raises the efficiency of the frequency conversion. The device can be used in optical frequency converters and for optical parametric amplification. The device can notably be used with a ferroelectric oxide, for example KNbO3 or a borate, for example LBO, in combination with at least one diode laser, for example AlGaAs or InGaAs, or a solid-state laser, for example, Nd:Y3Al5O12 or Nd:YVO4, for optical frequency multiplication, for producing sum frequencies or difference frequencies and for optical parametric amplification.

Description

METHOD AND DEVICE FOR OPTICAL

FREQUENCY CONVERSION AND THIS

DEVICE CONTAINING DEVICE

The invention relates to a method and a device for optical frequency conversion and a light source according to the preambles of the independent claims.

Frequency conversion of laser light through nonlinear-optical interactions has received some attention since the 1960s. Nonlinear-optical processes enable the generation of laser light at optical frequencies, which cannot or only with difficulty can be generated by a direct laser process. In general, a laser is used as the primary light source for such a frequency conversion process, the light beam of which propagates through a nonlinear-optical material. The nonlinear-optical interaction between the laser beam and the material means that part of the primary light is converted into light of higher or lower frequency. Of the nonlinear-optical processes, frequency doubling (second harmonic generation, SHG), sum frequency generation (SFG), difference frequency generation (DFG) and optical parametric amplification (OPA) are of particular importance. These processes enable the generation of laser radiation in the ultraviolet, visible, near and middle infrared spectral range, ie between 0.1 μm and 10 μm wavelength. Lasers that emit light at these wavelengths are used in spectroscopy, optical data storage, medicine, biology, etc.

Among a large number of crystalline materials which are suitable for nonlinear-optical interactions, the class of ferroelectric oxides has received particular attention, e.g. B. Potassium niobate (KNbθ3), lithium niobate (LiNbθ3), lithium tantalate (LiTaθ3), barium titanate (BaTiθ3) and KTP (KTiOPθ4). In general, crystals of these materials have large nonlinear optical susceptibilities, a material property that is a necessary prerequisite for efficient frequency conversion. Potassium niobate in particular has proven to be an excellent material for nonlinear optical applications due to its properties.

Another class of materials that have interesting nonlinear optical properties are crystals based on borar compounds such as e.g. ß-BaB2θ4 (BBO), L1B3O5 (LBO), CSB3O5 (CBO) and CsLiBöOio (CLBO). This group of nonlinear optical crystals is characterized by the fact that its optical transparency extends far into the ultraviolet spectral range. Because of this property, borate crystals are of interest for frequency conversion, in which ultraviolet laser radiation is generated.

The conversion efficiency in a nonlinear-optical process increases with the interaction length and with the intensity of the beam of the primary light source, provided that the primary beam and the generated radiation are optimally in phase ("internal phase adjustment"). To achieve the highest possible degree of conversion, the beam of the primary light source according to that described by Boyd et al. in the publication "Parametric interaction of focused Gaussian Hght beams" (J. of Appl. Phys. 39 (8), 3597 (1968)) can be optimally focused in the nonlinear optical material. With optimal focusing, the efficiency of frequency conversion increases in proportion to the length. Accordingly, the maximum achievable efficiency per unit length is a constant dependent on the nonlinear optical material used and can no longer be increased in the single pass device through the nonlinear optical material. To further increase efficiency, special devices must be used.

Fluck et al. have shown in the publication "Efficient second-harmonic generation by lens wave-guiding in KNbθ ₃ crystals" (Optics Communications 147, 305 (1998)) that by combining a series of nonlinear optical crystals and a series of lenses between the crystals, the Efficiency of frequency doubling increases in proportion to the square of the number of nonlinear optical crystals. This device has the advantage that the efficiency increases quadratically with the total length and therefore, in contrast to the device with a single pass, the efficiency per unit length increases linearly with the length. However, this quadratic increase is only achieved if the field amplitudes of the light generated in the individual passes are superimposed with the same phase, that is, constructively. If the field amplitudes are out of phase, destructive interference occurs and the resulting performance may even disappear entirely. However, this device with the lens and crystal series has the disadvantage that a large number of nonlinear optical crystals and achromatic lenses are required, all of which have to be positioned and temperature-stabilized and have to be provided with an anti-reflective coating.

Kozlovsky et al. have shown in the publication "Blue Hght generation by resonator-enhanced frequency doubling of an extended-cavity diode laser" (Appl. Phys. Lett. 65 (5), 525 (1994)) that a device in which the nonlinear optical crystal is placed in an external optical resonator, the Possibility to achieve very high degrees of conversion. Zimmermann et al. have shown in the publication "All solid state laser source for tunable blue and ultraviolet radiation" (Appl. Phys. Lett. 66 (18), 2318 (1995)) that laser diodes can be efficiently frequency-doubled in an external optical resonator. However, these external optical resonators have disadvantages which prevent their use in many practical applications. In an external optical resonator, the frequency spectrum of the primary light source must be very narrow-band and must be coupled to the resonator in order to guarantee stable and efficient frequency doubling. You therefore need various piezoelectric elements in order to keep both the resonator length and the phase of the light reflected back into the laser diode as optical feedback constant within a fraction of a wavelength (typically 50 to 100 nm), an active electronic locking circuit ), and typically an optical isolator.

The above statements underline the importance of special devices for efficient frequency conversion in nonlinear optical materials.

It is an object of the invention to provide a method and an apparatus for frequency conversion in a nonlinear optical material, for example a ferroelectric oxide or a borate crystal, which makes it possible to increase the efficiency of the conversion in a single crystal and at the same time to disadvantageous ones To avoid the effects of conventional devices, as shown at the beginning. The object of the invention is then to demonstrate the use of this device for efficient frequency conversion of semiconductor diode lasers, solid-state lasers, waveguide lasers and fiber lasers. Furthermore, it is an object of the invention to provide a light source in which light emitted by one or more primary light sources using the inventive according to the device is efficiently frequency converted. The object is achieved by the method, the device, its use and the light source as defined in the independent patent claims.

The basic idea of the invention is that by suitable positioning of deflecting means such as, for example, mirroring, the beam of the primary light source after a first pass through the nonlinear optical material is deflected together with the secondary beams of other wavelengths generated in the first pass, and possibly refocused in such a way that the Rays make another pass through the nonlinear optical material. This deflection and traversing of a nonlinear optical material can be continued in an analog manner, thus creating a scalable, multi-pass device. The method according to the invention and the device according to the invention make it possible, by using a number N (N = 2, 3, 4, etc.) of passes through the nonlinear optical material, to increase the efficiency for frequency conversion by a factor NxN (NxN = 4, 9 , 16, etc.). The reason that the efficiency in this case increases quadratically with the total length of action in the crystal is due to the fact that the amplitudes of the light components generated in each individual pass are constructively added to a total field with correct phase adjustment and the optical power is scaled proportionally to the square of the field amplitude. The frequency conversion efficiency that can be achieved in a double-pass arrangement is thus four times higher than the efficiency of the single-pass arrangement through the same nonlinear optical crystal and is the same as when two single crystals of the same length are used in a lens array arrangement.

In the method according to the invention for optical frequency conversion, primary light of a first spectral composition is coupled into at least one optically nonlinear medium, so that it is optically nonlinear Medium propagates, with a part of the primary light is converted into secondary light of a second spectral composition. After crossing at least part of the optically nonlinear medium, both the primary light and the secondary light are deflected in such a way that they in turn spread over the other in the optically nonlinear medium.

The inventive device for optical frequency conversion includes at least one optically non-linear medium and optical deflection means, which are arranged with respect to the optically non-linear medium in such a way that light propagating in the optically non-linear medium can be deflected essentially completely into the optically non-linear medium by the deflection means.

The light emitted by the primary light source is preferably coupled directly or through an optical system into the device with two or more passes through the frequency converter. In order to keep the reflection losses on the first and second end faces of the frequency converter as small as possible, both end faces of the frequency converter are preferably provided with an anti-reflective coating. After the first passage through the frequency converter, the beam of the primary light source is combined with the light generated by the frequency conversion deflected by an optical system, preferably one or more mirrors, and focused again in the frequency converter. By using a concave mirror, it can be achieved that the beams diverging after the first pass are in turn focused for the second pass in such a way that optimal frequency conversion takes place. An important advantage of this device with concave mirrors is that no lenses have to be used for collimating and focusing the beams (in contrast to the device with a row of lenses), which cause an undesirable phase difference between the primary beam and generated beams of other wavelengths by the dispersion of their refractive index and thereby the optimal phase relationship to destroy. In the device according to the invention, the medium which is located between the crystal and the mirror is the only dispersive medium in the beam path from the end of the first pass to the start of the second pass. Advantageously, a gas, e.g. As air or nitrogen, the dispersion of which is several orders of magnitude smaller than the dispersion of the refractive index of a typical glass lens, so that the tolerance of the system to possible disturbances in the optimal phase relationship between the primary beam and the generated beams is improved by orders of magnitude.

The second end face of the frequency converter can also be provided with a reflective coating, so that the light focused by the primary light source in the first pass into the frequency converter is reflected together with the light generated by the frequency conversion directly on the second end face of the frequency converter and the frequency converter in another Crossed direction again in a second pass. This means that an "external phase adjustment" only has to be guaranteed on one side of the nonlinear optical material, and half of the deflection mirrors can be dispensed with at the same time. ("External phase adjustment" in this document describes the maintenance of the optimal phase relationship between the primary light and understood the secondary light outside the optically non-linear medium.)

The beam deflection is preferably carried out in such a way that the beams have a different direction from the previous pass in the subsequent passage through the nonlinear optical material. This is to prevent the primary beam or a fraction of it from getting back into the primary light source and interfering with its emission properties, in particular the power and the frequency spectrum. In the case of the optical resonator, the primary beam must be guided in a closed path, so that an uncontrolled interference of the Primary light source can be prevented. On the other hand, the beam deflection for multiple passes should also take place at an angle close to 180 °, because otherwise the ideally Gaussian-shaped beams are imprinted with an undesirable astigmatism after the deflection at concave mirrors, which makes optimal focusing in a subsequent pass impossible.

Many of the known nonlinear optical crystals are highly birefringent, which is why it is advantageous to use these crystals in a so-called non-critical orientation, i.e. H. with beam propagation along the main axes ("no walk-off ', ie without the primary beam and the generated beams diverging) for frequency conversion. This condition can be approximately met at deflection angles close to 180 °. Typically deflection angles between 160 ° and an angle of less than 180 °, preferably between 170 ° and 179 °, but smaller or larger deflection angles, which, however, have the disadvantages mentioned above, can also be used .. Preferably, the directions of successive beam paths are chosen so that they are at least With three or more passes, the deflection is preferably carried out in such a way that the rays on the different passages come to lie in one plane. This plane can correspond to a plane spanned by two main axes of the crystal.

Mirrors with a metallic or dielectric coating are suitable as deflection mirrors, which reflect the primary beam as well as the generated beams of other wavelengths as completely as possible. The radii of curvature and positions of the deflecting mirrors are chosen such that the constrictions of the primary beam and the generated beams come to lie within the nonlinear optical material or on one of the two end faces of the material. The device according to the invention has significant advantages over an optical resonator, which will be shown below. Only special frequencies can exist in an optical resonator, the so-called longitudinal (resonator) modes, which have a fixed frequency range that is dependent on the excessive power in the resonator. In order to be able to couple a primary light source efficiently into the optical resonator, the frequency spectrum of this source must necessarily be narrower than this frequency range, ie the primary light source must be specially matched to the resonator. For example, in a 10 cm long resonator at a wavelength of the primary light source of 1 μm with a power increase of 10, the frequency spectrum of the primary light source must be narrower than 300 MHz. At the same time, the optical length of the resonator must be precisely controlled to better than 50 nm and the frequency of the primary light source must be kept stable to better than 300 MHz, which can only be achieved with special and complex measures. The device according to the invention with multiple passage, on the other hand, does not use a closed path for the primary beam, ie there is no phase condition, which is determined by the length of the resonator, which must be complied with and thereby imposes the above-mentioned restrictive requirements on the frequency spectrum of the primary light source. The only condition that must be met for efficient frequency conversion in the multiple pass is the phase adaptation between the primary light and the generated light along the entire beam path. Typically, the acceptance range for efficient frequency doubling in the known nonlinear optical crystals is approximately 10 GHz for a crystal length of 1 cm, ie the requirement for the width and the stability of the frequency spectrum of the primary light source is compared to one or two orders of magnitude weaker in the multi-pass device with optical resonators. This greater tolerance is of particular importance in the direct frequency conversion of laser diodes, which typically have a frequency range of a few GHz. The use of the device according to the invention also makes it possible to directly modulate the generated beams of other wavelengths by means of amplitude modulation of the primary light source, the modulation frequencies that can be achieved being several orders of magnitude higher than when using electronically stabilized resonators, which typically allow modulation frequencies of a few 100 kHz. In particular, the direct modulation of laser diodes as a primary light source is extremely attractive because these diodes allow modulation frequencies of up to a few GHz directly via current modulation.

The device according to the invention also enables the remaining primary beam to be spatially superimposed together with the generated beams of a different wavelength and to be emitted in the same direction. Such a light source with two or three wavelengths in the output beam can be used, for example, for precise trigonometric leveling systems and for precise interferometric distance measurement.

The device according to the invention can be used in optical frequency converters and for optical parametric amplification. In particular, the device according to the invention is used in combination with a diode laser or a solid-state laser for optical frequency multiplication, sum or difference frequency generation and optical-parameteric amplification. For example, by combining a KNbθ3 crystal in the device according to the invention with an AlGaAs or InGaAs diode laser, light in the spectral range between 430 and 670 nm can be generated efficiently. Other possible primary light sources in addition to semiconductor diode lasers are solid-state lasers, previously Nd and Cr doped grenades, such as. B. YAG (Y3AI5O12), GGG (Gd ₃ Ga ₅ Oi2), YSAG (Y3SC2AI3O12), GSAG (Gd ₃ Sc2Al3θi2), GSGG (Gd ₃ Sc2Ga3θi2), as well as YVO4, LiSAF, LiCAF and Ti: Al2θ3. As another For example, by using a diode laser, e.g. AlGalnP, and the device according to the invention with a borate crystal, ultraviolet laser radiation in the wavelength range between 180 and 430 nm can be generated by frequency doubling. In addition to diode lasers, frequency-doubled solid-state lasers, waveguide lasers and fiber lasers are also suitable. Other possible primary light sources are borate crystals for higher-order nonlinear-optical processes, e.g. third or fourth harmonic generation, which use, for example, the solid-state lasers mentioned as the primary light source. In addition, two or more light beams, which originate from two different primary light sources, can be used to efficiently generate sum or difference frequency generation using the device according to the invention As a further application, the device according to the invention for optical parametric amplification can be used

The light source according to the invention contains at least one primary light source and at least one optical frequency converter into which light emitted by the at least one primary light source can be coupled in. The at least one frequency converter is a device for frequency conversion according to the invention. Semiconductor diode lasers (for example AlGaAs or InGaAs diode lasers) are preferably suitable, Solid-state lasers (eg Nd YAG, Nd YVO4, Cr LiCAF or Cr LiSAF), waveguide lasers or fiber lasers. The light sources which are based on optical frequency multiplication (eg frequency doubling) or optical parametric amplification preferably contain a primary light source and a frequency converter in the device according to the invention Device Light sources which are based on optical sum or difference frequency generation preferably contain two primary light sources and a frequency converter in the device according to the invention The invention and for comparison of the prior art are described in detail with reference to the figures. The following schematically show:

1 shows a device for frequency conversion in a nonlinear optical material with single passage of the focused primary light beam according to the prior art,

2 shows a device for frequency conversion in a series of nonlinear-optical crystals and lenses according to the prior art,

3 shows a device for frequency conversion in a resonator with a nonlinear optical material according to the prior art,

4 the device according to the invention for frequency conversion in a nonlinear optical material with double beam passage,

Fig. 5 shows the inventive device for frequency conversion in a nonlinear optical material with triple beam passage and

Fig. 6 shows the inventive device for frequency conversion in a nonlinear optical material with four times the beam passage.

For reasons of clarity, the proportions in the figures do not correspond to those in reality.

The prior art for frequency conversion in a single pass through a nonlinear optical material is shown schematically in FIG. 1. A light beam 2 from a primary light source 1 is focused by an optical system 3, whereby a focused beam 4 is created. The focused beam 4 penetrates into a nonlinear optical material 5. Frequency conversion becomes part of the Power of the focused primary beam 4 is converted to beams of other optical frequencies or wavelengths. The newly generated beams are collimated as diverging beams 6 with an optical system 7, preferably one or more lenses, to form an output beam 8

The prior art for frequency conversion in a single pass through a series of nonlinear optical crystals is shown in FIG. 2. A beam 2 from a primary light source 1 is coupled into an arrangement of nonlinear optical crystals 5, 12, and lenses 3, 10, (further nonlinear optical crystals and lenses could follow analogously). Frequency conversion converts part of the power of the focused primary beam 4 converted to beams of other frequencies. To maintain the phase adjustment in the subsequent nonlinear optical crystals 12. . phase plates 11, ... are introduced into the beam path. The generated beams 6, ..., 13 run spatially superimposed on the primary beam 4 and in the same direction as this and are collimated at the end with an optical system 14 to an output beam 15

The prior art for frequency conversion in a resonator containing a nonlinear optical material is shown in FIG. 3. A beam 2 from a primary light source 1 is coupled with an optical system 3 into a resonator consisting of at least two mirrors 24, 25. The primary light source 1 is connected with the aid of an optical isolator 22 from unwanted light 23, which is emitted from the resonator, protected If an attenuated optical feedback 20 is used to couple the primary light source 1 to the resonator, then the phase between the feedback light 20 and the Light of the primary beam 2 can be adapted. The resonator contains a nonlinear optical material 5 for frequency conversion. The resonator is characterized in that the coupled primary beam 4 is deflected by the mirrors 24, 25 in such a way that it travels a closed path with the help of a piezoelectric element 26, the phase position of the primary light is adapted to handling in the resonator. Rays 6 generated by frequency conversion in the nonlinear optical material 5 are collimated with an optical system 27 to form an output beam 28.

The device according to the invention is described in FIGS. 4 to 6. Figure 4 shows a first embodiment. A beam 2 from a primary light source 1 is focused with a first optical system 3, preferably one or more lenses, whereby a focused beam 32 is created. The primary light source 1 is preferably a coherent light source, for example a semiconductor diode laser, a solid-state laser, a waveguide laser or fiber laser with an emission wavelength between 260 nm and 2 μm. The focused beam 32 penetrates a nonlinear optical material 5. The nonlinear optical material 5 can, for example, be a KNbθ ₃ , LiNbO ₃ , KTiOPθ4 (KTP), BaB2θ4 (BBO), L1B3O5 (LBO), CSB3O5 (CBO), or CsLiBöOio (CLBO) crystal. Frequency conversion converts part of the power of the injected primary beam 32 to beams of other optical frequencies or wavelengths. After the first passage of the primary beam 32 through the nonlinear optical material 5, the newly generated beams are deflected and focused together with the rest of the primary beam using a second optical system 35, preferably a concave mirror.

There are significant differences between the device according to the invention from FIG. 4 and the known arrangements from FIGS. 1-3, which will be discussed in the following. The device according to the invention differs from the resonator arrangement of FIG. 3 in that the reflected primary beam 33 does not make a further passage through the nonlinear optical material 5 at the same time as the direction of the incident beam 32, but at a small angle 34 and at the same time passes through the first pass generated rays of others Frequencies run in the direction of the deflected primary beam 33. Typical values for the angle 34 are greater than 0 ° and less than 20 ° and are preferably between 1 ° and 10 °, the deflection angle, ie the angle complementary to the angle 34, is therefore typically between 160 ° and an angle smaller than 180 ° or between 170 ° and 179 °. A significant difference between the inventive device and the arrangement with a number of crystals and lenses (FIG. 2) is that only a single nonlinear optical crystal 5 is used and that the Device according to the invention results in a much more compact arrangement

In the second pass 33 part of the light of the primary beam is in turn converted into light of other frequencies. The nonlinear optical material 5 is oriented in such a way that maximum frequency conversion takes place both on the first pass 32 and on the second pass 33. This so-called phase adaptation takes place within the non-linear Optical material (internal phase adjustment) is a necessary prerequisite for efficient frequency conversion to occur when the primary beam passes through the nonlinear optical material 5, so that the frequency-converted light in a first pass 32 and a second pass 33 becomes maximum power at the end of the double pass added, the phase between these light components 32, 33 must be set correctly. This phase adjustment outside the highly linear optical material 5 (external phase adjustment) must be in the medium 37, which is between the nonlinear optical material 5 and the optisc hen system 35 is introduced into the beam path of the primary light and the frequency-converted light, this medium 37 is preferably shielded from environmental influences and kept at a constant temperature. A closed temperature-controllable container 38, for example an oven, is particularly suitable for this purpose B glass, air, nitrogen or another transparent material. After the second passage 33 through the highly linear optical material 5, the frequency-converted beams and the rest of the primary steel are coated with a third optical system 39, preferably one or more lenses, collimated into an exit beam 36.

In a second embodiment, shown in FIG. 5, a beam 2 from a primary light source 1 with a first optical system 3, preferably one or more lenses, is focused into a nonlinear optical material 5. Frequency conversion converts part of the power of the injected primary beam to beams of other frequencies. After the first passage 42 through the nonlinear optical material 5, the newly generated beams are deflected and focused together with the rest of the primary beam using a second optical system 40, preferably a concave mirror. After the second passage 43 through the nonlinear optical material 5, the beams are again deflected with a third optical system 41, preferably a concave mirror, and focused into the nonlinear optical material 5 to form a third passage 44. After the third pass 44 through the nonlinear optical material 5, the frequency-converted beams and the rest of the primary steel are collimated with an fourth optical system 45 into an exit beam 46. A temperature-adjustable container 38 filled with a transparent medium 37 can in turn be used for external phase adjustment.

In a third embodiment, shown in FIG. 6, a beam 2 from a primary light source 1 with a first optical system 3 is focused on an end face 50 of a nonlinear optical material 5. The end face 50 is provided with a reflective coating, so that the remaining primary beam, together with the beams frequency-converted in the first passage 52 through the nonlinear optical material 5, makes a second passage 53 through the nonlinear optical material 5, without thereby closing the nonlinear optical material 5 leave. The reflective coating can, for example, at least one metal layer, at least one dielectric layer or a sequence of such Layers. The combination of direct deflection of the rays on one end face 50 of the nonlinear optical material 5 and deflection by an optical system 51 on the opposite side of the material results, for example, in a device with four passages 52, 53, 54, 55 through the nonlinear optical material 5. After the fourth pass 55 through the nonlinear optical material 5, the frequency-converted beams and the rest of the primary steel are collimated with an optical system 56 into an exit beam 57. A temperature-adjustable container 38 filled with a transparent medium 37 can in turn be used for external phase adjustment.

The embodiments of the invention explained here are only examples. With knowledge of the invention, it is possible for the person skilled in the art to design further embodiments of the invention.

Claims

PATENT CLAIMS 1. Process for optical frequency conversion, in which primary light (2) a first spectral composition is coupled into at least one optically nonlinear medium (5), so that it propagates (32) in this optically nonlinear medium (5), with part of the primary light in Secondary light is converted to a second spectral composition, characterized in that after passing through at least part of the optically nonlinear medium (5), both the primary light and the secondary light are deflected in such a way that they are spatially superimposed and propagate in the optically nonlinear medium (5). (33). Method according to claim 1, characterized in that both the primary light and the secondary light are deflected several times in such a way that they propagate (43, 44, 53, 54, 55) in a spatially superimposed manner in the optically non-linear medium (5). 3. The method according to claim 1 or 2, characterized in that the light is deflected by a deflection angle between 160° and an angle smaller than 180°, in particular between 170° and 179°. 4. The method according to any one of claims 1-3, characterized in that the secondary light is spatially superimposed on the part of the primary light from the optically nonlinear medium that has not been converted into secondary light (5) is coupled out. 5. The method according to any one of claims 1-4, characterized in that the light is focused before being coupled into the optically non-linear medium and/or before being propagated again in the optically non-linear medium (5). 6. The method according to claim 5, characterized in that the light is focused in such a way that its constriction comes to rest within the optically nonlinear medium (5) or on an interface (50) of the optically nonlinear medium (5). 7. The method according to any one of claims 1-6, characterized in that Primary light (2) is coupled into the optically nonlinear medium (5) in such a way that internal phase matching is achieved, i.e. H. on all crossings (32, 33) of the optically nonlinear medium (5) maximum frequency conversion takes place. 8. The method according to any one of claims 1-7, characterized in that the light is coupled into the optically non-linear medium (5) and redirected and the optically non-linear medium (5) is converted into a transparent one Ambient medium (37) is embedded so that external phase matching is achieved, i.e. H. Secondary light is added to maximum power after two successive crossings (32, 33) of the optically nonlinear medium (5). 9. Device for optical frequency conversion, with at least one optically nonlinear medium (5), characterized by optical deflection means (35), which are arranged with respect to the optically nonlinear medium (5) in such a way that light (5) propagating in the optically nonlinear medium (5) 32) can be essentially completely redirected into the optically non-linear medium (5) by the deflection means (35). 10. The device according to claim 9, characterized in that the deflection means are designed as at least one planar and/or concave mirror (35, 40, 41, 51) and/or as an interface (50) of the optically non-linear medium (5). 11. Device according to claim 9 or 10, characterized in that at least one interface (30, 31, 50) of the optically nonlinear medium (5) is provided with a reflective or an anti-reflective coating. 12. Device according to one of claims 9-11, characterized in that the optically non-linear medium (5) is connected upstream of a focusing optical system (3) and/or a collimating optical system (39) is connected downstream. 13. Device according to one of claims 9-12, characterized in that the optically nonlinear medium (5) and the deflection means (35) are embedded in a transparent surrounding medium (37), in particular glass, air and/or nitrogen. 14. Device according to one of claims 9-13, characterized in that it is at least partially located in a temperature-stabilizable container (38). 15. Device according to one of claims 9-14, characterized in that the at least one optically nonlinear medium (5) is a KNbÜ ₃ , LiNbθ ₃ , KTiOPθ4 (KTP), BaB2θ4 (BBO), L1B3O5 (LBO), CSB3O5 (CBO) or CsLiBöOio (CLBO) crystal or a periodically poled ferroelectric crystal. 16. Use of the device according to one of claims 9-15 in optical frequency converters for frequency doubling, frequency multiplication, sum frequency generation, difference frequency generation or optical-parametric amplification. 17. Light source with at least one primary light source (1) and at least one optical frequency converter (5), into which light (2) emitted by the at least one primary light source (1) can be coupled, characterized in that the at least one frequency converter (5) is a device according to one of claims 9-15. 18. Light source according to claim 17, characterized in that the at least one primary light source (1) is a semiconductor diode laser, a solid-state laser, a waveguide laser and / or a fiber laser with an emission wavelength between 260 nm and 2 μm. CHANGED REQUIREMENTS [received by the International Bureau on November 26, 1999 (11/26/99); Original claims 1 and 5-18 replaced by new claims 1 and 5- all others Claims unchanged (5 rare)] 1 Method for optical frequency conversion, including the following procedural steps (a) coupling primary light (2) of a first spectral composition 5 into at least one optically nonlinear medium (5), so that the Primary light (2) propagates (32) in this optically nonlinear medium (5), (b) converting a portion of the primary light into secondary light of a second spectral composition; (c) after crossing at least part of the optically nonlinear 10 medium (5) deflection of both the primary light and the secondary light in such a way that they are spatially superimposed and spread out (33) in the optically non-linear medium (5), and that the primary light does not cover a closed path, characterized in that 15 the light (2, 32) with each traversal (32, 33) of the optically nonlinear Medium (5) is focused into the optically nonlinear medium (5). 2 Method according to claim 1, characterized in that both the primary light and the secondary light are redirected several times in such a way that they are spatially superimposed and in turn spread out in the optically non-linear medium 20 (5) (43, 44, 53, 54, 55) 3. The method according to claim 1 or 2, characterized in that the light is deflected by a deflection angle between 160° and an angle smaller than 180°, in particular between 170° and 179°. 4. The method according to any one of claims 1-3, characterized in that the secondary light is coupled out of the optically nonlinear medium (5) in a spatially superimposed manner with the part of the primary light that has not been converted into secondary light. 5. The method according to any one of claims 1-4, characterized in that the light is focused in such a way that its constriction comes to rest within the optically non-linear medium (5) or on an interface (50) of the optically non-linear medium (5). 6. Method according to one of claims 1-5, characterized in that the phases of the primary light and the secondary light are kept in that optimal relationship to one another in which maximum frequency conversion takes place. 7. The method according to any one of claims 1-6, characterized in that the light is coupled into the optically non-linear medium (5) and redirected and the optically non-linear medium (5) is embedded in a transparent surrounding medium (37) in such a way that external phase adjustment is achieved, i.e. H. secondary light after two consecutive Crossings (32, 33) of the optically nonlinear medium (5) are added to maximum power. 8. Device for optical frequency conversion, comprising at least one optically nonlinear medium (5) and optical deflection means (35), which are arranged with respect to the optically nonlinear medium (5) in such a way that light (32) propagating in the optically nonlinear medium (5) can be essentially completely redirected into the optically nonlinear medium (5) by the deflection means (35). is, but the light (32, 33) cannot be guided along a closed path, marked by Means (3, 35) for focusing light (2, 32) into the optically nonlinear medium (5) each time it passes through (32, 33) the optically nonlinear medium Medium (5). 9. Device according to claim 8, characterized in that the deflection means are designed as at least one planar and/or concave mirror (35, 40, 41, 51) and/or as an interface (50) of the optically non-linear medium (5). 10. Device according to claim 8 or 9, characterized in that at least one interface (30, 31, 50) of the optically nonlinear medium (5) is provided with a reflective or an anti-reflective coating. 11. Device according to one of claims 8-10, characterized in that the optically nonlinear medium (5) has a focusing optical system (3) AMENDED SHEET ARTICLE 19 upstream and / or a collimating optical system (39) is connected downstream. 12. Device according to one of claims 8-11, characterized in that the optically non-linear medium (5) and the deflection means (35) in a transparent surrounding medium (37), in particular glass, air and / or Nitrogen, are embedded. 13. Device according to one of claims 8-12, characterized in that it is at least partially located in a temperature-stabilizable container (38). 14. Device according to one of claims 8-13, characterized in that the at least one optically nonlinear medium (5) is a KNbθ3, LiNbθ3, KTiOPθ4 (KTP), BaB2θ4 (BBO), L1B3O5 (LBO), CSB3O5 (CBO) or CsLiBöOio (CLBO) crystal or a periodically poled ferroelectric crystal. 15. Use of the device according to one of claims 8-14 in optical frequency converters for frequency doubling, frequency multiplication, sum frequency generation, difference frequency generation or optical-parametric amplification. 16. Light source with at least one primary light source (1) and at least one optical frequency converter (5), in which of the at least one Primary light source (1) emitted light (2) can be coupled in, thereby characterized in that the at least one frequency converter (5) is a device according to one of claims 9-15. 17. Light source according to claim 16, characterized in that the at least one primary light source (1) is a semiconductor diode laser, a solid-state laser, a waveguide laser and / or a fiber laser with an emission wavelength between 260 nm and 2 μm. AMENDED SHEET ARTICLE 19