EP4154062A1 - Device for spectral broadening of a laser pulse, and laser system - Google Patents

Abstract

The present invention relates to a device (100) for spectral broadening of a laser pulse. The device (100) comprises a multipass assembly (120) having a convex mirror (122) and a concave mirror (121), the convex mirror (122) and the concave mirror (121) being situated relative to one another such that a laser pulse coupled into the multipass assembly (120) is reflected at least once by the concave mirror (121) to the convex mirror (122) and at least once by the convex mirror (122) to the concave mirror (121). The device (100) also comprises a non-linear optical medium (130) which is situated at least partly within the multipass assembly (120) such that the laser pulse coupled into the multipass assembly (120) passes through the non-linear optical medium (130) multiple times. The invention also relates to a laser system (200) which comprises a device according to the invention for spectral broadening of a laser pulse.

Description

DEVICE FOR THE SPECTRAL EXPANSION OF A

LASER IMPULSES AND LASER SYSTEM

The present invention relates to a device for the spectral broadening of a laser pulse, a laser system and a use of a multipass arrangement for the spectral broadening of a laser pulse. The invention is therefore particularly in the field of laser technology.

Multipass arrangements are devices in which a laser beam or laser pulse is propagated a predetermined number of revolutions and then decoupled. Multipass arrangements are often used in the application of non-linear optical processes, such as in the application of non-linear optical spectral broadening of laser pulses, in which a non-linear optical medium is arranged in solid form and / or in gas form in the multipass arrangement and during the propagation of the laser pulse or laser beam in the multipass arrangement is traversed several times by this. In multipass arrangements, the laser beam propagates through the free space without being guided, i.e. there is no guided propagation of the beam, as is the case, for example, in optical fibers. Multipass arrangements can also be used for other non-linear optical processes, such as for example for self-frequency shifting and self-compression.

Nonlinear pulse compression by means of spectral broadening using self-phase modulation (SPM) and a subsequent temporal compression of the laser pulses, for example by means of dispersive mirrors or grating compressors, is a known technology and is often used in femtosecond laser systems. Often the Kerr nonlinearity of solid-state nonlinear optical media is used, which denotes an intensity dependency of the refractive index of the nonlinear optical medium. The refractive index n can be expressed mathematically as follows: n = n ₀ + n ₂ I.

No denotes the intensity-independent refractive index, r \ ₂ the non-linear refractive index and I the intensity of the laser pulse. The Kerr non-linearity, which occurs when a laser pulse is propagated with a high Peak intensity occurs through the nonlinear medium, causing a rapid modulation of the temporal phase O (t), which can be expressed as follows:

O (t) = k _n AnL = fc _n n ₂ / (t) L

Here, k _n indicates the wave number and L the propagation length of the laser pulse in the non-linear medium. This time phase can also be referred to as the longitudinal time phase in order to express its dependence on the propagation length L. The rapid modulation of the temporal phase leads to the creation of new spectral components in the frequency spectrum of the laser pulse, since the frequency represents the temporal derivative of the temporal phase. This is mathematically represented by w = d / d (t) <P (t), where w denotes the angular frequency. In general, the intensity of a laser pulse depends on the radial position in the beam (denoted as r), which leads to a radial or spatial dependence of the optical path length OPL (t, r) = (no + ri2l (t, r)) d . In most solid-state nonlinear media, this, together with a customary intensity profile of the laser pulse according to a Gaussian radial intensity distribution, leads to the laser beam being self-focusing at sufficiently high intensities, which can lead to a deterioration in the laser beam profile. Due to the temporal and spatial dependence of the intensity of the laser pulse, the spectral distribution of the frequencies of the laser pulse after the SPM can also have an undesirable radial location dependency. However, in 1994 it was experimentally shown that by means of a multipass propagation of the laser pulse in a regenerative amplifier cavity, the undesired self-focusing or the radial, spatial accumulation of the SPM can be suppressed, while the desired longitudinal phase of the SPM can be increased ( Li Yan, Yuan-Qun Liu, and CH Lee, “Pulse temporal and spatial chirping by a bulk Kerr medium in a regenerative amplifier,” IEEE J. Quantum Electron., Vol. 30, no. 9, pp. 2194-2202, 1994). Pulse compression using unguided propagation of the laser pulse is typically carried out in multipass arrangements which are designed as Herriott cells (HC), a non-linear optical medium being arranged in the HC.

The strength of non-linear effects and / or accumulated phase shifts are typically characterized or specified in terms of their strength by the so-called B integral. The B integral becomes typically only given for the position of the laser pulse on the optical axis, i.e. in the center of the pulse at r = 0, and is expressed mathematically as follows:

B - fn ₂ I (z) dz

L indicates the central wavelength of the laser pulse. The B-integral is essentially proportional to the intensity of the laser pulse and to the propagation distance in the non-linear medium. A high B integral is desirable for a desired strong spectral broadening and a high degree of pulse compression.

However, strongly pronounced non-linear effects also have other undesirable side effects which cannot always be avoided and which can lead to various problems. For example, the presence of high peak intensities in the laser pulse or high peak intensities in the propagation through the non-linear medium can reach or exceed the threshold of critical self-focusing, at which self-focusing occurs due to the Kerr non-linearity and focuses the laser pulse in the non-linear medium in such a way that the non-linear medium is damaged and destroyed. This can take place, for example, by destroying a solid, nonlinear medium and / or by ionizing a gaseous nonlinear medium. For example, the ionization threshold for argon is around 10 ¹⁴ W / cm ² . Other gases also have similar ionization thresholds. If the intensity of the laser pulse in such a non-linear medium exceeds this ionization threshold, the non-linear medium is ionized, as a result of which the laser pulse is at least partially dissipated and the beam profile of the laser pulse is dramatically impaired. The destruction of a solid-body non-linear medium can be present, for example, in the form of cloudiness or even mechanical destruction of the non-linear medium. Therefore, the spectral broadening through continuous propagation of the laser beam through the nonlinear optical medium is not accessible for such peak powers of laser pulses at which the damage threshold is reached or the damage threshold would be expected through critical self-focusing. In order to at least partially circumvent or reduce at least the limitations caused by the critical self-focusing in the spectral broadening of laser pulses, an approach is known in the prior art in which the spectral broadening takes place through several propagations of the laser pulse through a short, non-linear optical medium ( see DE 102014007 159 A1). The non-linear medium is kept so short that the laser pulse leaves it again before a considerable self-focusing and in particular a critical self-focusing occurs. In order to still obtain a B integral that is sufficient for the spectral broadening, the laser pulse is propagated several times, ie in several passes, through the nonlinear optical medium. Since after each passage of the laser pulse through the nonlinear optical medium, the laser pulse is refocused by a concave mirror, the effect of the self-focusing can be at least partially reduced or eliminated.

Another limitation in the use of non-linear effects in general and non-linear spectral broadening and pulse compression in particular, however, lies in the damage threshold of the optical elements used. Typically, two opposing concave mirrors are used in HC, by means of which a multipass arrangement is generated between the mirrors by means of multiple reflections of the laser pulses. The laser pulse or laser beam is focused by the concave mirror so that very high intensities can occur in the areas with a smaller beam diameter and especially in the focus, which can clearly exceed the damage threshold of the optics used. For this reason, in such multipass arrangements which use two concave mirrors, it must always be ensured that the beam diameter is sufficiently large and, accordingly, the intensity is sufficiently small at the points where the laser pulse hits the optical elements, so that the To avoid the damage threshold and the associated destruction of the optical elements. In order to spectrally broaden pulses with high pulse energy with such an arrangement, a corresponding upscaling is therefore required, ie that the optical path lengths and the diameter of the optical elements used must be selected so large that sufficiently large beam diameters can be used to achieve and Avoid exceeding the damage threshold. For example, an HC with two concave mirrors is known in the prior art, which for the compression of laser pulses with a pulse energy of 40 mJ has a considerable length of 8 m (published in M. Kaumanns et al., Eds., Multipass spectral broadening with tens of millijoule pulse energy. Optical Society of America, 2019). To make matters worse, the damage threshold of dielectric mirrors, which are preferably used as dispersive optical elements for dispersion control, is in some cases a factor of 2 to 3 lower than the damage threshold of metallic, highly reflective mirrors. Therefore, with the intended use of such dielectric mirrors, the maximum pulse energy should be selected to be even smaller and / or the diameter of the optics and the optical path lengths to be chosen to be even greater. A folding of the multipass arrangement, in which a concave mirror is used together with a flat mirror, has the disadvantage that significantly higher intensities are to be expected on the flat mirror due to a smaller beam diameter and therefore the limitation for the pulse energy or Peak intensity would prohibit use with high intensity laser pulses.

It is therefore the object of the present invention to provide a device for the spectral broadening of a laser pulse which is suitable for laser pulses with high peak intensity.

According to the invention, this object is achieved by a device, a laser system and a use having the features of the respective independent claims. Optional configurations are specified in the subclaims and in the description.

In a first aspect, the invention relates to a device for the spectral broadening of a laser pulse. The device has a multipass arrangement with a convex mirror and a concave mirror, wherein the convex mirror and the concave mirror are arranged to one another in such a way that a laser pulse coupled into the multipass arrangement at least once from the concave mirror to the convex mirror and is reflected from the convex mirror to the concave mirror at least once. In addition, the device has a non-linear optical medium which is arranged at least partially within the multipass arrangement in such a way that the non-linear optical medium is traversed several times by the laser pulse coupled into the multipass arrangement. In a further aspect, the invention relates to a laser system with a device according to the invention for the spectral broadening of a laser pulse.

In a further aspect, the invention relates to a use of a multipass arrangement with a convex mirror and a concave mirror for the spectral broadening of a laser pulse, in which the convex mirror and the concave mirror are arranged to one another in such a way that a laser pulse coupled into the multipass arrangement is reflected at least once from the concave mirror to the convex mirror and at least once from the convex mirror to the concave mirror and the laser pulse propagates through a nonlinear optical medium arranged in the multipass arrangement for spectral broadening.

The terms laser beam and laser pulse are used as synonyms, since pulsed laser radiation in the form of a laser beam can also be described with regard to the optical path. The terms laser pulse and laser pulse are also used as synonyms.

A multipass arrangement is an arrangement of optical elements which deflects a laser pulse or laser beam coupled into the multipass arrangement in such a way that it propagates several rounds in the multipass arrangement before the laser pulse or laser beam leaves the multipass arrangement again is decoupled. The deflection of the laser beam takes place optionally by reflections of the laser beam or laser pulse, so that the laser beam or laser pulse changes its direction of propagation in the multipass arrangement. In contrast to arrangements which guide the beam by means of optical fibers through total internal reflection, in the multipass arrangement the laser beam is propagated in free space without the beam mode being affected by an optical at every point along the optical path of the laser beam or laser pulse Fiber is restricted.

A concave mirror is a curved mirror whose reflective surface is curved inward, ie the center of the concave mirror is arranged further back than the edges of the mirror. The concave mirror can optionally have a spherical or aspherical curvature exhibit. An aspherical curvature can, for example, be designed as a parabolic curvature, other curvature shapes also being possible. The concave mirror is designed in such a way that a collimated laser beam striking the concave mirror is focused by the concave mirror. In this description, the radius of curvature of a concave mirror is typically given with a negative value, although the sign of the curvature value makes no statement about the direction of the curvature. A concave mirror is also a concave mirror if its radius of curvature is given with a positive or unsigned sign.

A convex mirror is a curved mirror whose reflective surface is curved outwards, i.e. the edges of the concave mirror are set back further than the center of the mirror. The convex mirror can optionally have a spherical or aspherical curvature. An aspherical curvature can, for example, be designed as a parabolic curvature, other curvature shapes also being possible. The convex mirror is designed in such a way that a collimated laser beam striking the concave mirror is widened or scattered by the convex mirror. In this description, the radius of curvature of a convex mirror is typically given with a positive value, although the sign or the lack of a sign of the curvature value makes no statement about the direction of the curvature. A convex mirror is also a convex mirror if its radius of curvature is given with a negative sign.

The fact that the nonlinear optical medium, which is referred to in the present invention by the synonym “nonlinear medium”, is at least partially arranged within the multipass arrangement means that at least part of the nonlinear medium is arranged within the multipass arrangement. Optionally, the non-linear medium is arranged completely within the multipass arrangement. However, particularly when using a gaseous non-linear medium, a part of the gaseous non-linear medium can also be arranged outside the multipass arrangement. For the spectral broadening of a laser pulse, however, it is necessary for the laser pulse to pass or propagate through the non-linear medium. The non-linear medium is therefore to be arranged in the multipass arrangement in such a way that that such a propagation of the laser pulse in the non-linear medium is made possible at least partially during the revolutions in the multipass arrangement.

The fact that the multi-pass arrangement is traversed several times by the laser pulse means that the laser pulse propagates several rounds in the multi-pass arrangement. One cycle can optionally be implemented by reflecting the laser pulse twice in the multipass arrangement, so that the laser pulse changes its direction of propagation twice and, after two reflections, propagates again in approximately the same direction as before the double reflection.

Coupling a laser pulse into the multipass arrangement means that a laser pulse or laser beam coming from outside the multipass arrangement is fed to the multipass arrangement and is then deflected several times by the multipass arrangement in order to make several revolutions in the multipass arrangement propagate. Decoupling the laser pulse from the multipass arrangement means that the laser pulse leaves the multipass arrangement again after propagating several rounds through the multipass arrangement.

The invention offers the advantage that a device for the spectral broadening of laser pulses can be provided in which the laser beam does not necessarily have to be focused. Because the multipass arrangement essentially has a convex and a concave mirror, it is not necessary to focus the laser beam between the two mirrors, as is the case in particular with conventional Herriott cells with two concave mirrors. As a result, small beam diameters and correspondingly high intensities can be avoided in the device or in the multipass arrangement. This in turn offers the advantage that disadvantageous effects can be avoided, which are typically associated with small beam diameters, such as damage to optical elements by exceeding the (laser-induced) damage threshold (LIDT) and / or the undesired occurrence of self-focusing, for example in a gaseous non-linear optical medium, and / or the undesired Occurrence of ionization of a gas medium in the multipass arrangement, such as air and / or a gaseous non-linear optical medium.

The invention also offers the advantage that the device and in particular the multipass arrangement can be constructed in a particularly compact manner, ie that the spatial dimensions of the device or the multipass arrangement can be selected to be particularly small, in contrast to conventional Herriott cells which based on two concave mirrors. Because the laser beam does not necessarily have to be focused in a device and multipass arrangement according to the invention, it is also not necessary to consider the beam diameter size when choosing the distance between the two mirrors of the multipass arrangement in order to avoid destruction or damage to the mirror to avoid. Due to the fact that, according to the invention, there is not necessarily a focus in the multipass arrangement, the beam diameter at each point along the optical path in the multipass arrangement can be selected to be so large that the expected intensity of a coupled laser beam or a laser pulse (clearly) is below the damage threshold of the optical elements, in particular the convex and concave game gel. The invention thus offers the advantage that various laser systems can be equipped with a compact device for the spectral broadening of a laser pulse.

The invention also offers the advantage that a multipass arrangement according to the invention can optionally be folded, ie that the beam path of the laser beam in the multipass arrangement can be deflected by one or more deflection mirrors and the spatial dimensions can be reduced even further in this way. This represents a further advantage over conventional Herriott cells based on two concave mirrors, since in these, the introduction of a deflecting mirror between the two concave mirrors would inevitably mean that the deflecting mirror would be in an area with smaller beam diameters (compared to the concave mirrors) should be arranged and accordingly either the maximum pulse energy or peak intensity of laser pulses, which can be coupled non-destructively into the multipass arrangement, would be significantly reduced, or the intensity of the laser pulses at the location of the deflection mirror would exceed its damage threshold. ok

The invention also offers the advantage that, due to the possibility of the compact construction of the multipass arrangement, the optical path length of the laser pulses in the multipass arrangement can be kept short compared to conventional Herriott cells. This is particularly advantageous in that the time delay which the laser pulses accumulate during propagation through the multipass arrangement can be kept low and in this way simplifies an optionally required compensation of this time delay for a split-off laser pulse, for example for pump-probe applications can be.

Furthermore, the invention offers the advantage that the volume of a multipass arrangement and device according to the invention can be kept small. This can offer advantages in particular in that the provision of a high-pressure atmosphere in the multipass arrangement is simplified or made possible. Correspondingly, this can enable or simplify the use of a gaseous non-linear medium. Due to the smaller spatial dimensions made possible by a multipass arrangement according to the invention, the provision of a sealed volume which can withstand high pressure differences can be considerably simplified.

In addition, the invention offers the surprising effect that when using a multipass arrangement with a concave and a convex mirror for the spectral broadening of laser pulses, a beam quality that is sufficient and suitable for further use of the laser pulses can be maintained, as in the following explanation of the optional embodiments and examples is shown. In particular, the beam quality is to be assessed as equivalent to the beam quality when using a conventional HC. This contradicts the prevailing opinion among experts that multipass arrangements with a concave and a convex mirror have a negative influence on the spectral homogeneity of the laser pulses and on the beam profile and are therefore not suitable for use as a multipass arrangement for the spectral broadening of Laser pulses are suitable (see M. Hanna et al., “Nonlinear temporal compression in multipass cells: theory,” J. Opt. Soc.

At the. B, vol. 34, no.7, p. 1340, 2017). Contrary to this view established in the specialist world, the inventors were able to show, however, that a beneficial use of a multipass arrangement with a concave and a convex mirror for the spectral broadening of laser pulses is possible and advantageous. The non-linear optical element is optionally designed to be passive. This means that the nonlinear optical medium is not designed to actively amplify a laser pulse passing through it. Accordingly, the non-linear optical medium is designed not to be pumped and / or to have no laser activity. Optionally, the non-linear optical element is designed to bring about one or more non-linear optical effects when a laser pulse passes through, solely on the basis of the non-linear refractive index, which effects lead or are suitable for the spectral broadening of the laser pulse. In particular, the nonlinear optical medium can differ from an active laser medium in that the nonlinear optical medium does not have an active element which is suitable and / or designed to bring about a population inversion for a laser activity.

The entire device is optionally designed to be passive. In other words, the device has no active element and / or active laser medium. In other words, the device is designed in such a way that the nonlinear optical element is passive and the device also has no other active element or active laser medium.

Optionally, the multipass arrangement is designed such that the laser pulse coupled into the multipass arrangement several times, optionally more than ten times, from the concave mirror to the convex mirror and several times, optionally more than ten times, from the convex mirror to the concave Mirror is reflected. This offers the advantage that the coupled-in laser pulse can pass through the non-linear optical medium arranged in the multipass arrangement several times.

Optionally, the multipass arrangement is designed such that the laser pulse coupled into the multipass arrangement is reflected from the concave mirror directly to the convex mirror and from the convex mirror directly to the concave mirror. In other words, no further deflection mirror is optionally arranged in the multipass arrangement between the concave mirror and the convex mirror. This offers the advantage that a particularly simple construction of the multipass arrangement is made possible and any negative effects on the beam profile can be avoided. Optionally, the multipass arrangement also has one or more deflection mirrors. This offers the advantage that a beam folding can be achieved in the multipass arrangement and, as a result, the multipass arrangement can be constructed in a particularly compact manner.

Optionally, the nonlinear optical medium has a medium in the form of a solid. This offers the advantage that the non-linear optical medium can be arranged at a defined position in the multipass arrangement and, in addition, a defined propagation length of the laser pulse through the non-linear optical medium can be established. This also offers the advantage that the solid-state, non-linear optical medium can have a strongly pronounced non-linear refractive index. In addition, a solid, non-linear medium is mostly not subject to any or only very minor dependencies on the ambient pressure and only very minor changes in the event of temperature fluctuations. Optionally, the solid-state, nonlinear optical medium is formed at least partially from sapphire and / or SiC and / or diamond and / or quartz glass (fused silica). These have a strongly pronounced non-linear refractive index and a comparatively high damage threshold. Alternatively or additionally, a non-linear medium can have ZnS and / or ZnSe or consist of them, which is advantageous for wavelengths in the mid-infrared. As an alternative or in addition, the non-linear optical medium can comprise YAG and / or noble gases and / or Raman-active gases such as H2, N2, O2 and / or CO2, and / or fluoride glasses such as MgF and / or CaF. Optionally, other not explicitly mentioned materials can also be used for the nonlinear medium, which have a pronounced nonlinear refractive index and optionally a high damage threshold.

Optionally, the non-linear medium has a gaseous medium or is designed as such. This enables particularly long propagation lengths of the laser pulse through the non-linear optical medium, since the multipass arrangement can optionally be completely filled with the gaseous non-linear medium. Furthermore, a non-linear optical medium offers degrees of freedom with regard to the prevailing non-linearity due to the adjustability of the gas pressure. Furthermore, a gaseous non-linear medium offers the advantage that the ionization threshold is typically higher than the damage threshold of solid-state non-linear optical media and accordingly laser pulses withstands higher intensity than solid-state nonlinear media.

The device is optionally arranged in a pressure chamber and / or designed as a pressure chamber, the gaseous medium being provided in the pressure chamber. This simplifies the provision of the gaseous non-linear medium in the multipass arrangement.

Optionally, the device and / or the multipass arrangement has at least one dispersive optical element which is designed to at least partially compensate and / or overcompensate for a spectral dispersion caused in the nonlinear optical medium. For the compression of laser pulses, in addition to spectral broadening, dispersion control is typically also decisive in order to obtain a short laser pulse, ideally close to the Fourier limit. It is therefore advantageous if the dispersion control already takes place at least partially in the multipass arrangement, which can be achieved by means of corresponding dispersive optical elements in the multipass arrangement. In addition, an at least partial dispersion control within the multipass arrangement offers the advantage that the laser pulse changes its intensity profile only slightly, as a result of which a high degree of efficiency and effectiveness of the broadening can be achieved.

The dispersive optical element is preferably designed as a dispersive coating of the concave mirror and / or the convex mirror, which is designed to at least partially compensate or overcompensate for a spectral dispersion caused in the nonlinear optical medium. This offers the advantage that no further optical elements have to be provided and the structure of the device and / or the laser system can be simplified accordingly and / or further power losses due to additional reflections on any additional dispersive optical elements can be avoided. The dispersive optical elements and / or coatings can in particular be designed to reduce the second-order dispersion (Group Delay Dispersion, GDD) and / or the third-order dispersion (TOD), which is caused by the Propagation through the non-linear medium act on the laser pulse, at least partially to compensate for it.

Optionally, the concave mirror and / or the convex mirror have a recess for coupling the laser pulse into the multipass arrangement and / or for decoupling the laser pulse from the multipass arrangement. This enables a simple coupling and decoupling of laser pulses into and out of the multipass arrangement.

The multipass arrangement optionally has a Herriott cell or is designed as such. This offers the advantage that the advantages of a Herriott cell and the advantages of the multipass arrangement based on a convex and a concave mirror can be combined.

Optionally, the nonlinear phase, which a laser pulse collects per revolution in the multipass arrangement, when using a nonlinear optical medium in solid form, can be in a range of approximately 0.2 rad to 2 rad, optionally in a range of approximately 0.2 rad up to 0.6 rad. When using a gaseous nonlinear medium, the collected nonlinear phase per revolution can optionally be in a range from about 0.2 rad to 6.0 rad, optionally from about 0.2 rad to 3.0 rad. When choosing the non-linear phase to be collected, the desired spectral broadening can optionally be taken into account, which requires a pronounced non-linear phase, and on the other hand the resulting beam quality of the spectrally broadened laser pulse, for which an excessive amount of non-linear phase can be disadvantageous if the intended one Application of the laser pulses places certain requirements on the beam profile.

The number of revolutions of a laser pulse in the multipass arrangement is optionally in a range from 2 to 100, optionally in a range from 10 to 29. The upper limit of the number of revolutions can be determined, for example, from the spatial size of the multipass arrangement required for this and the manufacturing costs result, since larger mirrors typically have to be used for a larger number of revolutions.

The features and embodiments mentioned above and explained below are not only to be viewed as disclosed in the combinations explicitly mentioned in each case, but are also included in the disclosure content in other technically meaningful combinations and embodiments. Further details and advantages of the invention will now be explained in more detail on the basis of the following examples and preferred embodiments with reference to the figures.

Brief description of the figures:

1 shows, in a schematic representation, a conventional device for the spectral broadening of a laser pulse with a conventional multipass arrangement 20 according to the prior art.

FIG. 2 shows, in a schematic representation, a device for the spectral broadening of a laser pulse according to an optional embodiment of the invention.

FIG. 3 shows, in a schematic representation, a multipass arrangement according to a further optional embodiment.

FIG. 4A shows a schematic explanation of the stability criteria of a concave-convex multipass arrangement.

FIGS. 4B to 4E show exemplary courses of reflection point courses on a mirror surface for different values of parameters.

FIG. 5 shows in a diagram the course of the beam radius along the propagation length through the Herriott cell or multipass arrangement.

FIG. 6 shows a graph of the beam radius and the cumulative B integral versus the propagation length through the multipass arrangement.

FIG. 7 shows the power curve over time of the simulated laser pulse after spectral broadening and compression and the simulated spectrum after spectral broadening and compression.

FIG. 8 shows the measured spectrum and the output spectrum determined by means of an FROG measurement after the spectral broadening with the concavo-convex device according to the optional embodiment.

FIG. 9 shows the measured spectrum and the output spectrum determined by means of an FROG measurement after the spectral broadening with a conventional concave-concave Herriott cell.

FIG. 10 shows the calculated spectral overlap for both axes after broadening with the concavo-convex device according to the optional embodiment.

FIG. 11 shows the calculated spectral overlap for both axes after broadening with the conventional concave-concave Herriott cell.

FIG. 12 shows, in a schematic representation, a laser system 200 according to an optional embodiment.

In the following figures, the same or similar elements in the various embodiments are denoted by the same reference symbols for the sake of simplicity. The terms laser beam and laser pulse are used as synonyms, since pulsed laser radiation in the form of a laser beam can also be described with regard to the optical path.

1 shows a schematic representation of a conventional device 10 for the spectral broadening of a laser pulse with a conventional concave-concave multipass arrangement 20 according to the prior art, which is designed as a Herriott cell (HC). This conventional multipass arrangement 20 has two concave mirrors 21 and 22, which are arranged with respect to one another in such a way that a coupled-in laser beam is reflected between the two concave mirrors 21 and 22. Due to the concave shape of the reflection surfaces of the mirrors 21 and 22, the laser beam is focused, the focal plane being arranged in the middle between the two mirrors 21 and 22. Accordingly, the laser beam 40 has the largest beam diameter on the reflection surfaces of the mirrors 21 and 22 and the smallest beam diameter in the focal plane. Furthermore, the device 10 has a non-linear optical medium 30 which is designed in the form of a solid. The nonlinear medium 30 is arranged in the focal plane, since there the smallest beam diameter and therefore the greatest intensity of the laser pulses prevails, which is decisive for the nonlinear optical effects and in particular for the spectral broadening.

In addition, the device 10 has a coupling-in and coupling-out mirror 23, by means of which a laser beam 40 can be coupled into the multipass arrangement 20 and can be decoupled from the multipass arrangement 20.

The optical path of the laser beam 40 is shown by way of example by means of a line and shows that the laser beam 40 after coupling into the multipass arrangement 20 circulates several times in the multipass arrangement 20 before the laser beam 40 passes through the coupling-in and coupling-out mirror 23 is decoupled again. After each reflection at mirrors 21 and 22, i.e. twice per complete revolution, the laser pulse passes through nonlinear medium 30 in the focal plane, in which the desired nonlinear optical processes for spectral broadening take place.

While high intensities are required in the focal plane in the nonlinear optical medium 30, the intensity of the laser pulses on the reflection surfaces of the mirrors 21 and 22 must be significantly lower in order to ensure that the damage threshold of the mirrors 21 and 22 is not exceeded. For this purpose, the laser beam must have a sufficiently large beam diameter on the reflection surfaces of the mirrors 21 and 22, which is achieved by a sufficiently large distance between the mirrors and the focal plane and a correspondingly large focal length of the mirrors 21 and 22. This goes hand in hand with the fact that the diameter of the concave mirrors 21 and 22 must also be selected to be correspondingly large. In the illustration shown, the mirror spacing do corresponds to the sum of the focal lengths of the mirrors 21 and 22, which in the example shown is in each case do / 2.

Since a large focus is typically desired in the focal plane in order to be able to spectrally broaden high-intensity laser pulses, concave mirrors with a long focal length are required. Smaller focal lengths would result in a smaller mode size in the focus, creating undesirable effects in the nonlinear optical medium 30 would increase. The large focal lengths to be selected accordingly mean that the distance do must be selected to be correspondingly large in order to ensure a sufficient beam diameter on the reflection surfaces of the mirrors 21 and 22. This has the disadvantage that the multipass arrangements 20 according to the prior art mostly have very large spatial dimensions, in particular a great length, which is not infrequently several meters. For use and laser systems, in particular for industry, this can represent a major challenge in terms of the space required by the laser system.

FIG. 2 shows, in a schematic representation, a device 100 for the spectral broadening of a laser pulse according to an optional embodiment of the invention. The device 100 has a multipass arrangement 120 which comprises a concave mirror 121 and a convex mirror 122. The concave and convex mirrors 121, 122 are arranged relative to one another in such a way that a laser beam 140 coupled into the multipass arrangement 120 is reflected several times between the two mirrors 121, 122 before the laser beam is coupled out of the multipass arrangement 120 again . To couple the laser beam 140 in and out of the multipass arrangement 120, the concave mirror 121 has an in and out opening 123 through which the laser beam 140 can pass when it is coupled in and out to correspondingly enter the multipass arrangement 120 to enter or leave them.

In addition, the device 100 has a non-linear optical medium 130 which is arranged in the multipass arrangement 120. The nonlinear optical element is arranged away from the center of the multipass arrangement 120 and is located close to the convex mirror 122, since the laser beam 140 has a smaller diameter there than at other positions in the multipass arrangement 120, which are closer to the concave mirror 121 lie. The nonlinear optical medium 130 is arranged and designed in such a way that the laser beam 140 passes through the nonlinear optical medium 130 after each reflection, ie twice per revolution in the multipass arrangement 120. For this purpose, it can be advantageous if the nonlinear medium 130 has approximately a similar lateral extent to the convex mirror 122 in order to ensure that the laser beam passes through the nonlinear optical medium 130 on all revolutions. According to the embodiment shown, this is non-linear Medium 130 formed in solid form. According to other embodiments, the device 100 can additionally or alternatively have a gaseous non-linear medium. For this purpose, for example, the multipass arrangement 120 or the device 100 can be designed as a pressure chamber which can be filled with a suitable gas at the desired pressure.

As can be seen in FIG. 1, the distance do between the two mirrors 121 and 122 deviates from the focal length f1 of at least the concave mirror 121 and optionally also from the focal length f2 (see FIG. 4A) of the convex mirror 122.

The focal length f1 of the concave mirror 121 is longer than the distance between the concave mirror 121 and the convex mirror, so that the focal plane F1 of the concave mirror 121 lies outside the multipass arrangement 120. Since the convex mirror 122 is a divergent mirror, its focal plane or focus (not shown) lies outside the multipass arrangement 120 the exceeding of the damage threshold of the mirrors 121 and 122, the ionization of air or other gases in the multipass arrangement 120 and a critical self-focusing can be avoided in a simple manner. In order to still achieve a sufficiently high B integral and the associated desired spectral broadening of the laser pulse, the nonlinear optical medium 130 can be adapted with regard to its nonlinear refractive index and / or its thickness and / or the number of revolutions of the laser beam 140 in the multipass - Arrangement 120 compared to conventional concave-concave multipass arrangements 20 can be increased.

In order to control the dispersion of the laser pulse already in the multipass arrangement 120, the mirrors 121 and 122 can each be provided with an optional dispersive, dielectric coating 150 on their reflection surface. This can be designed in such a way that the dispersion which the laser pulse collects during propagation through the non-linear optical medium 130 is at least partially compensated for. Optionally, the dispersion can also be overcompensated in order, for example, to achieve self-compression of the laser pulse. For example, the dispersive coating 150 or the dispersive coatings 150 can be designed in such a way that at least the GDD and TOD which the laser pulse collects in the nonlinear optical medium 130 are at least partially compensated. In other Embodiments can also have only one of the two mirrors 121 and 122 such a dispersive coating 150. According to further embodiments, neither of the two mirrors 121 and 122 can have a dispersive coating. Optionally, the device 100 or a laser system that uses the device 100 can have dispersive optical elements (not shown), such as dispersive, dielectric mirrors, in order to control and / or compensate for the dispersion elsewhere.

FIG. 3 shows, in a schematic illustration, a multipass arrangement 120 according to a further optional embodiment. This multipass arrangement 120 differs from the multipass arrangement 120 shown in FIG. 2, inter alia, in that it has a deflecting mirror 124 in addition to the concave mirror 121 and the convex mirror 122. The multipass arrangement 120 is constructed in such a way that the laser beam 140 is reflected from the concave mirror 121 to the deflecting mirror 124 and via the deflecting mirror 124 to the convex mirror 122 a deflection by the deflecting mirror 124. According to the embodiment shown, the concave mirror has a significantly larger diameter than the convex mirror and also has a recess 125 through which the laser beam 140 can pass through the concave mirror 121. The convex mirror 122 is arranged behind the concave mirror 121 so that the laser beam 140 passing through the recess 125 hits the convex mirror and can be reflected back through the recess 125. According to other optional embodiments (not shown), the convex mirror can also be arranged in front of the concave mirror.

The multipass arrangement 120 according to this optional embodiment is designed similarly to a Cassegrain telescope. The structure of the multipass arrangement 120 shown offers the advantage that the deflection of the laser beam 140 can reduce the spatial extent of the multipass arrangement 120, in particular its length, and the multipass arrangement 120 can accordingly be designed in a space-saving manner. This can be particularly advantageous for use in laser systems which have a very limited amount of space. Furthermore, this offers the advantage that, despite the reduced spatial dimensions, the path length of the optical path of the laser beam in of the multipass arrangement 120 can be retained or even enlarged. In addition, the embodiment offers the advantage, especially compared to the concave-concave Herriott cells known from the prior art, that the beam diameter of the laser beam 140 at the deflection mirror is of sufficient size and in particular is larger than on the convex mirror 122 and therefore does not exceed the The deflection mirror's damage threshold is to be feared.

FIG. 4A shows a schematic explanation of the stability criteria of a concave-convex multipass arrangement 120, as is known from geometrical optics. The multipass arrangement 120 shown in FIG. 4A has a concave mirror 121, the reflection surface of which has a radius of curvature Ri, which is shown by means of an arrow and a corresponding circumference 1001. Furthermore, the multipass arrangement 120 has a convex mirror 121, the reflection surface of which has a radius of curvature R2. Since the reflection surface of the convex mirror 122 is curved outwards, the center of the circle of the circumferential circle 1002 with the radius of curvature R2 is arranged behind the convex mirror 122. The concavo-convex multipass arrangement 120 is then considered to be stable, in the sense of a stable resonator, which allows a plurality of circulations of a laser beam between the mirrors before the laser beam is coupled out of the resonator or from the multipass arrangement 120, if the concave mirror 121 and the convex mirror 122 are spaced from one another in such a way that the circumferential circles 1001 and 1002 spanned by their radii of curvature Ri and R2 intersect and form an overlap. This is the case in the configuration shown because the two circumferential circles 1001 and 1002 intersect at points 1003. In a full three-dimensional view, these are not just points of intersection, but rather a corresponding circle of intersection, which, however, can only be seen as two points of intersection in the two-dimensional projection shown. The dashed line 1004 denotes the mode volume of the resonator or of the multipass arrangement 120 in which the beam courses resonant in the multipass arrangement 120 propagate. Beams located outside the mode volume leave the multipass arrangement 120 and therefore do not propagate resonantly in the multipass arrangement 120. In the following, specific examples of devices for spectral broadening of a laser pulse according to optional embodiments of the invention and in particular concave-convex multipass arrangements are explained, without the invention being restricted to these examples. The exemplary embodiments are also partially characterized and compared with a conventional concave-concave Herriott cell according to the prior art.

example 1

In the following, a specific example of a device 100 for the spectral broadening of a laser pulse with a multipass arrangement 120 according to a preferred embodiment is explained in detail and compared with a conventional Herriott cell according to the prior art.

For comparison with the prior art, a conventional Herriott cell is used, which is known and described in the prior art (M. Kaumanns et al., "Multipass spectral broadening of 18 mJ pulses compressible from 1.3 ps to 41 fe," Optics letters, vol. 43, no. 23, pp. 5877-5880, 2018, doi: 10.1364 / OL.43.005877) This has a multipass arrangement with two spherical concave mirrors, each with a radius of curvature of - 1.5 m and are arranged at a distance of do = 2.98 m from one another. This multipass arrangement is designed in such a way that an injected laser pulse N = 23 runs through full revolutions in the multipass arrangement, rather the laser beam is decoupled again from the multipass arrangement and thereby completed 45 passes through the non-linear optical medium. According to the example shown, the parameter M has the value M = 22.

The multipass arrangement is constructed in the manner of a Herriott cell, ie the reflection points at which the laser beam is reflected on the cell mirrors lie on a circle or an ellipse. For a given number N of reflections on the cell level, several different cell configurations are possible which differ in the order of the reflections. The parameter M-1 indicates how many neighboring reflection points lie between two temporally successive reflection points, ie how many reflection points are “skipped”. An alternative consideration is how many full circles / ellipses from the reflection point pattern to the Cell levels are described. The ratio of M and N indicates the stability and thus do as well as the mode size in the Herriott cell.

In FIGS. 4B to 4E, reflection patterns for different values of the parameters N and M on a mirror surface are shown by way of example and some angles of the reflection points are named. The curves of the reflection points for N = 6 and N = 7 are shown, the reflection patterns in Figures 4B to 4E differing in the values of the parameter M, which M = 1 (Figure 4B), M = 2 (Figure 4C) , M = 3 (FIG. 4D) or M = 4 (FIG. 4E). It can be seen that, despite the same number of revolutions (parameter N), the arrangement of the reflection points on the mirrors for various parameters M can differ significantly from one another. The dashed line represents the circular pattern for N = 6, while the solid line represents the circular pattern for N = 7. The angle specifications relate to a 0 ° position at the extreme right point at the 3 o'clock position.

This conventional device has as a limiting factor the damage threshold of the optical coating of the concave mirror, which was determined to be 0.25 J / cm ² . In order to ensure the reliable operation of this conventional device, the fluence for laser radiation was set at 66% of the damage threshold, ie at 0.17 J / cm ² . The eigenmode of the conventional Herriott cell has a diameter of 5.4 mm, which accordingly has a maximum pulse energy of E _max = (0.27 cm) ² n 1 = 18.6 mj allows.

Another limiting factor to be taken into account is gas ionization, which occurs with argon as the non-linear optical medium used at a gas pressure of 600 mbar with a pulse energy of approx. 18.3 mJ. With a pulse duration of 1.3 ps, this corresponds to an intensity in the focus of approx. 2

10 ¹³ The proportionality factor of the ionization threshold to the gas pressure was

_ determined by measurements to be about ~ p £ s, where p denotes the gas pressure of argon.

According to a first exemplary, optional embodiment of the invention, which is compared with the prior art, the multipass arrangement of the device has a spherical concave mirror with a radius of curvature of Ri = -11.0 m and a spherical convex mirror with a radius of curvature of R2 = 8.5 m, which are arranged at a distance of do = 3.07 m from one another. The multipass arrangement is designed in such a way that a coupled-in laser beam propagates N = 23 full revolutions in the multipass arrangement, rather the laser beam is coupled out again.

FIG. 5 shows in a diagram the course of the beam radius in mhi (vertical axis) along the propagation length through the conventional Herriott cell or multipass arrangement in mm (horizontal axis). The solid line represents the course for the conventional, concave-concave Herriott cell, while the dashed line shows the course of the beam radius for the concave-convex multipass arrangement according to the optional embodiment. It can be seen that only the conventional HC has a strongly focused eigenmode, which leads to a beam radius of less than 500 mΐti with a propagation length of around 1,500 mm. This can lead to undesired ionization of the existing gas atmosphere. In the concavo-convex multipass arrangement according to the optional embodiment, however, there is no strong focusing within the multipass arrangement, so that the course of the beam radius shown with the dashed line is always greater than 2,000 mhh and therefore no undesirable ionization is to be feared.

Although the concavo-convex multipass arrangement has approximately the same length as the conventional concavo-concave HC (the difference in length is only 3%) and has a beam diameter on the convex mirror that is about 15% smaller than on the concave one Mirror, which leads to a fluence increased by approx. 33%, an ionization of gas in the multipass arrangement is nevertheless completely prevented, since there is no focus of the laser beam in the multipass arrangement. The lower intensity of the laser beam in the concavo-convex multipass arrangement compared to the focus in the conventional concavo-concave HC offers the advantage that the concavo-convex device can be used for the spectral broadening and compression of laser pulses with significantly higher pulse energies, in particular for laser pulses of intensities which, due to the limitations described above, cannot be broadened and compressed in a conventional concave-concave HC. In order to achieve a corresponding B integral with a concave-convex multipass arrangement, which, as explained above, depends on the intensity of the laser pulse, more moderate can be used for laser pulses Energies are adapted to the nonlinear medium in order to have a correspondingly higher nonlinear refractive index. For this purpose, for example, when using a gaseous nonlinear optical medium such as argon, the gas pressure can be increased and additionally or alternatively a solid-state nonlinear optical medium with a significantly higher nonlinear refractive index can be used.

Example 2

In the following, a device according to a further embodiment of the invention is described, which is designed for the spectral broadening and compression of laser pulses with a pulse energy of 0.5 J and a pulse duration of 1.3 ps (FWHM).

Conventional concave-concave HCs are unsuitable for such an application per se, since a length scaling would have to be carried out for this, which would not make such an HC accessible for practical use because of the considerable spatial length.

The device according to the further embodiment has a concave-convex multipass arrangement with a spherical concave mirror with a radius of curvature Ri = -50.0 m, a convex mirror with a radius of curvature of R2 = 32 m and a mirror spacing of do = 18.35 m on. The multipass arrangement is designed in such a way that a coupled laser beam remains in the multipass arrangement for N = 49 revolutions and M = 1.

Since a concavo-convex multipass arrangement is used, the multipass arrangement or the optical path in the multipass arrangement can be folded by means of a deflecting mirror, as shown in FIG. 3, for example. The length of the multipass arrangement can thus be reduced to well below 8 m. The pulse energy of the laser pulses to be broadened is sufficiently high to use argon gas at a pressure of 1 bar as the non-linear optical medium for the broadening, which results in a cumulative B integral per passage through the non-linear optical medium of approx. 2.8 can be.

FIG. 6 shows in a graph with the solid line the jet radius in mhh (left vertical axis) and with the dashed line the cumulative B integral in any units (right vertical line) compared to the Propagation length due to the multipass arrangement. Since the multipass arrangement is completely filled with argon, the propagation length of the laser pulse through the multipass arrangement corresponds to the propagation length through the non-linear optical medium.

The calculated output pulses after the spectral broadening and compression in the device according to the second embodiment is shown in FIG. With the device according to the preferred embodiment, the spectrum of the pulse according to the calculations is limited to a bandwidth of approx.

60 nm (FWHM) can be widened, which can be compressed to a pulse duration of less than 50 fs by means of a compensation of the GDD in the amount of -35,000 fs ² . Non-dispersive optics in the multipass arrangement were assumed. The performance of the device can also be improved by compensating the GDD of 300 fs ² of argon per cycle. The peak intensity and the peak fluence in the device occur at the convex mirror with about 4-10 ¹¹ W / cm ² and 0.5 J / cm ^2, respectively. Both values are well below the damage threshold of the optical elements and the ionization threshold of argon.

In the upper graph, FIG. 7 shows the power curve over time of the simulated laser pulse after spectral broadening and compression, and in the lower graph the simulated spectrum after spectral broadening and compression.

Example 3

In the following, an example of a device for the spectral broadening of a laser pulse according to a further embodiment is explained and compared with a further conventional concave-concave system.

The device according to the embodiment has a concave-convex multipass arrangement with N = 19, M = 1, Ri = -0.5 m, R2 = 0.25 m and do = 0.26 m.

For comparison, a conventional Herriott cell with N = 19, M = 18, /? _! = -0.3 m, R ₂ = -0.3 m, d ₀ ~ 0.596 m used. When used for the spectral broadening of laser pulses of the commercially available laser system of the type PHAROS from the manufacturer LIGHT CONVERSION with a Output pulse energy of 200 J and a pulse duration of 270 fs, a quartz glass plate with a thickness of 6.35 mm as a nonlinear optical medium can be arranged about 50 mm from one of the mirrors to produce a B integral of about 0.6 for a To cause propagation through the quartz glass plate. The laser pulse has a sufficiently high peak power to cause significant non-linear effects in the ambient air. The B integral due to the propagation of the laser pulse through the air is therefore about 0.7.

In the proposed device according to the preferred embodiment, the 6.35 mm thick quartz glass plate can be arranged at a distance of 56 mm from the concave mirror, resulting in a B integral of 0.6. The B-integral due to the free propagation through air is, however, due to the shorter optical paths and the larger beam diameter, significantly smaller than with the conventional Herriott cell and is only 0.04.

Therefore, by means of a device according to the invention based on a concavo-convex multipass arrangement, the self-phase modulation in air can be dramatically reduced and almost completely avoided.

Example 4

In a further experimental comparison, the spectral broadening of laser pulses with a further device based on a concavo-convex multipass arrangement according to a further embodiment and a conventional concave-concave Herriott cell was shown.

Pulses from a commercially available laser system of the PHAROS type from the manufacturer LIGHT CONVERSION were spectrally broadened and compressed. The output pulses of the laser system mentioned before the spectral broadening and compression have an average pulse energy of 15 mϋ and a pulse duration (FWHM) of 266 fs with a resulting peak pulse power of 56.4 MW.

The device according to the preferred embodiment of the invention has a multipass arrangement 120 designed as a Herriott cell with a concave mirror 121 and a convex mirror 122 as shown in FIG. The concave mirror has a radius of curvature Ri = -250 mm and the convex mirror has a radius of curvature of R2 = 200 mm. The mirrors were coated in such a way that almost the entire GDD of the multipass arrangement is compensated. The convex mirror has a dispersive coating with an effect of -140 fs ² and the concave mirror only a highly reflective coating. The distance between the mirrors of the multipass arrangement is do = 114 mm and enables 19 reflections per mirror and correspondingly 38 propagations through the non-linear medium, which is formed by a 3 mm thick quartz glass plate with a diameter of 25.4 mm and an anti-reflective coating on both sides . The coupling and decoupling in the multipass arrangement takes place by means of a Scarper mirror. The mode adjustment is carried out by a Galilean beam expander. The eigenmode of the multipass arrangement is characterized by a Gaussian beam with a diameter of wi = 336 mhh on the concave mirror or W2 = 182 pm on the convex mirror. The non-linear optical medium is at a distance of d = 110 mm from the concave mirror, where the beam has a diameter of w = 193 mhi.

FIG. 8 shows the measured spectrum (gray) and the output spectrum determined by means of an FROG measurement (black line) after the spectral broadening with the concavo-convex device according to the optional embodiment, a pulse energy of 15 pJ being used for the FROG measurement. The error of the FROG measurement is 7 ^c 10 ³ on a 256 x 256 grid. In the lower graph, FIG. 8 shows the time profile determined from the FROG measurement (black line), the time phase profile (dashed) and, as a reference, the Fourier limit (FTL) (gray), as well as the integrated intensity in the main pulse (dotted).

The output spectrum accordingly has a bandwidth of more than 50 nm at 1 / e ^{2 of} the spectral beam power. The Fourier limit of the spectrum is approx. 49 fs. The pulse compression is carried out by means of six dispersive mirrors, each with -400 fs ² GDD. The transmission through the device and the compression level was determined to be 91%. A pulse shortening by a factor of 5 was determined, which results in a pulse duration of 53 fs (FWHM), as shown in FIG. The FROG measurements showed that 80% of the energy is contained in the main pulse. With this device, a non-linear phase of approximately 0.5 rad was also achieved, which leads to a high quality beam profile after passing through the device. To confirm this, the spectral homogeneity of the compressed beam was measured by means of scans over two axes of the beam. The sagittal and tangential spectrum were measured in 0.2 mm steps. For each recorded spectrum I _x (X), the overlapping portion with the central intensity _{spectrum / l} (L) was calculated according to the following formula:

The calculated spectral overlap is shown for both axes in FIG. To quantify the overall spectral homogeneity, a weighted overlap with the intensity was calculated using the formula which led to the values of V _x = 98.9% and V _y = 98.2%.

For comparison, the results of the equivalent measurements, which are shown for the concavo-convex device in FIGS. 8 and 10, are also shown for a conventional Herriott cell in FIGS. 9 and 11.

The measured conventional concave-concave HC has a first concave mirror with a radius of curvature of -250 mm and a highly reflective coating. The second concave mirror has a radius of curvature of -200 mm and a dispersive coating with a GDD value of -140 fs ² . The two concave mirrors are spaced 378 mm apart and allow 19 reflections per mirror and 38 revolutions through the nonlinear optical medium, which is designed as a quartz glass plate with a thickness of 3 mm and an anti-reflective coating on both sides. The non-linear optical medium is arranged at a distance of 110 mm from the second concave mirror. The eigenmode of the HC is characterized by a Gaussian beam with a diameter of wi = 358 miti or W2 = 471 miti on the concave mirrors and w = 195 miti in the non-linear medium. FIG. 9 shows the measured spectrum (gray) and the output spectrum (black line) determined by means of a FROG measurement after the spectral broadening with the conventional concave-concave device according to the preferred embodiment, a pulse energy of 15 mϋ being used for the FROG measurement. The error of the FROG measurement is 6 * 10 ³ on a 256 * 256 grid. In the right graph, FIG. 9 shows the time profile determined from the FROG measurement (black line), the time phase profile (dashed) and, as a reference, the Fourier limit (FTL) (gray), as well as the integrated intensity in the main pulse (dotted). A spectral broadening of more than 50 nm at the 1 / e ² value of the spectral power was achieved. The corresponding Fourier transform time limit (FTL) of this spectrum is approximately 53 fs (FWHM). The pulse was compressed to a pulse duration of 57 fs (FWHM) using a compressor arrangement with an overall compensation of -2400 fs ² . The transmittance of the HC was determined to be 90%. A pulse shortening by a factor of 5 was achieved and confirmed with the FROG measurements shown in FIG.

The calculated spectral overlap is shown for both axes in FIG. 11 and shows that the values V _x = 99.1% and V _y = 98.9% were determined for the conventional concave-concave HC.

It can thus be established that the spectral broadening, as well as the compressibility and the spectral homogeneity of the spectrum broadened with a concavo-convex device are in no way inferior to a conventional concavo-concave HC. Contrary to the prevailing assumption in the specialist world that concavo-convex multipass arrangements are disadvantageous in these points, the inventors can thus refute them.

FIG. 12 shows, in a schematic representation, a laser system 200 according to an optional embodiment, which has a device 100 according to an optional embodiment of the invention for the spectral broadening of a laser pulse. The device 100 can be integrated into the laser system 200 or formed separately from it. The laser pulses provided by the laser system 200 can be fed to the device 100 before further use, in which they pass through the concavo-convex multipass arrangement and are spectrally broadened in this. In addition, in the device 100 or elsewhere in the Laser system, the laser pulse broadened by the device 100 can be compressed by means of one or more dispersive optics.

List of reference symbols

10 Device for spectral broadening according to the prior art

20 Multipass arrangement according to the state of the art

21 concave mirror

22 concave mirrors

23 Coupling and coupling mirrors

30 non-linear optical medium

40 laser beam

100 Device for spectral broadening

120 multipass arrangement

121 concave mirror

122 convex mirror

123 In and out coupling opening

124 deflection mirror

125 recess

130 non-linear optical medium

140 laser beam

150 dispersive coating

1001 circumference with radius of curvature R1

1002 circumference with radius of curvature R2

1003 points of intersection of the radii of curvature

1004 mode volume of the multipass arrangement do mirror spacing of the multipass arrangement fi focal length of the concave mirror

Fi focal plane of the concave mirror f2 focal length of the convex mirror

Ri radius of curvature of the first mirror

R2 radius of curvature of the second mirror

Claims

Claims

1. Device (100) for the spectral broadening of a laser pulse, the device comprising:

- A multipass arrangement (120) with a convex mirror (122) and a concave mirror (121), the convex mirror (122) and the concave mirror (121) being arranged with respect to one another in such a way that one in the multipass arrangement ( 120) coupled laser pulse is reflected at least once from the concave mirror (121) to the convex mirror (122) and at least once from the convex mirror (122) to the concave mirror (121);

- A non-linear optical medium (130) which is arranged at least partially within the multipass arrangement (120) in such a way that the non-linear optical medium (130) from the into the multipass arrangement

(120) coupled laser pulse is passed through several times.

2. Device (100) according to claim 1, wherein the nonlinear optical medium (130) is passive.

3. Device (100) according to claim 1 or 2, wherein the device (100) is passive.

4. Device (100) according to one of the preceding claims, wherein the multipass arrangement (120) is designed such that the laser pulse coupled into the multipass arrangement (120) several times, optionally more than ten times, from the concave mirror (121 ) is reflected to the convex mirror (122) and several times, optionally more than ten times, from the convex mirror (122) to the concave mirror (121).

5. Device (100) according to one of the preceding claims, wherein the multipass arrangement (120) is designed such that the laser pulse coupled into the multipass arrangement (120) from the concave mirror

(121) directly to the convex mirror (122) and from the convex mirror

(122) is reflected directly to the concave mirror (121). 6. Device (100) according to one of claims 1 to 4, wherein the multipass arrangement (120) further comprises one or more deflection mirrors (124).

7. Device (100) according to one of the preceding claims, wherein the nonlinear optical medium (130) comprises a solid-state medium and / or a gaseous medium.

8. The device (100) according to claim 7, wherein the solid-state nonlinear optical medium is at least partially formed from sapphire and / or SiC and / or quartz glass and / or diamond.

9. Device (100) according to claim 7 or 8, wherein the device (100) is arranged in a pressure chamber and / or is designed as a pressure chamber and wherein the gaseous medium (130) is provided in the pressure chamber.

10. The device (100) according to any one of the preceding claims, wherein the device (100) and / or the multipass arrangement (120) has at least one dispersive optical element which is designed to at least partially produce a spectral dispersion caused in the nonlinear optical medium to compensate or overcompensate.

11. The device (100) according to claim 10, wherein the dispersive optical element is designed as a dispersive coating (150) of the concave mirror (121) and / or of the convex mirror (122), which is designed to be a nonlinear optical medium (130) to at least partially compensate or overcompensate for the spectral dispersion caused.

12. Device (100) according to one of the preceding claims, wherein the concave mirror (121) and / or the convex mirror (122) has a recess (125) for coupling the laser pulse into the multipass arrangement (120) and / or for decoupling of the laser pulse from the multipass arrangement (120). 13. Device (100) according to one of the preceding claims, wherein the multipass arrangement (120) has a Herriott cell or is designed as such. 14. Laser system comprising a device (100) for the spectral broadening of a laser pulse according to one of claims 1 to 12.

15. Use of a multipass arrangement (120) with a convex mirror (122) and a concave mirror (121) for the spectral broadening of a laser pulse, in which the convex mirror (122) and the concave

Mirrors (121) are arranged to one another in such a way that a laser pulse coupled into the multipass arrangement (120) at least once from the concave mirror (121) to the convex mirror (122) and at least once from the convex mirror (122) to the concave Mirror (121) is reflected and the laser pulse propagates for spectral broadening through a non-linear optical medium (130) arranged in the multipass arrangement (120).