RU182596U1 - Multichannel sequential pulse generator with adjustable time delay and spectral addition of the output beam (MGPI) - Google Patents

Abstract

The utility model relates to laser technology. The multi-channel sequential pulse generator contains a rear mirror, an active solid-state element, a passive shutter for generating giant pulses, a spectral element similar to a group velocity dispersion compensator and diaphragmed with a soft spatial selector made of a saturable absorber, an output mirror, diode modules with a fiber output, and a lens that displays output ends of diode modules with fiber output into the volume of the active element. Several closely spaced generation channels are formed in the active element. The size of the pump channels in the active element should be smaller than the constriction of the main Gaussian mode (w), which is characteristic of the resonator at the central generation wavelength. To ensure the necessary delay between the generation pulses, the pump intensities and the distance between the centers of the pump channels (d) are selected in the range [2w <d <3wg]. The technical result is the ability to simplify the process of generating lasing pulses with a fixed time delay and the ability to combine the radiation of several spatially separated lasing channels. 1 ill.

Description

The utility model relates to optical instrumentation, in particular to laser resonator devices, and can be used to create directional radiation sources with an adjustable temporal intensity distribution. Known two-channel laser with a smoothly tunable delay between the generation channels [1], which is the closest in technical essence and the achieved result and selected as a prototype. In this device, the resonator of the two-channel laser was formed by one common flat wedge-shaped mirror and two identical spherical mirrors. To obtain two generation channels and their spatial diversity in the active element, a birefringent plate was used that divided the beam into two beams having mutually orthogonal polarizations and propagating parallel to each other. Further channel spacing in space was carried out by the Glan-Foucault prism. Obtaining the Q-switched mode, as well as to control the moment of the start of generation in the channels, was carried out using two electro-optical gates.

Such a device makes it possible to obtain an output beam that is uniform in space and divergence, consisting of two lasing pulses with a fixed time delay between them, however, it requires the use of a separate high-voltage electro-optical shutter for each channel and limits the maximum number of channels to two, since there are only two orthogonal polarizations of light .

The principle of obtaining several lasing pulses within the same pump channel is also known [2]. In this case, the subsequent generation pulse corresponds to a transverse mode of a higher order laser cavity. Different time delays between pulses correspond to different mode composition of the generated radiation. With this method, a smooth adjustment of the delay time between the generation pulses is not carried out, the output energy is scaled over a wide range, and the quality of the output laser beam deteriorates.

In a utility model, to improve the quality of the beam, the method of spectral addition of co-directional lasers with low radiation divergence is used using a spectral element similar to the group velocity dispersion compensator. The possibility of such devices is shown, for example, the device described in the source [3]. The method assumes that the centers of several parallel laser beams of the same size but with a different spectrum are located along one line perpendicular to the lines of the diffraction gratings. Falling on it, the beams due to diffraction acquire different angles of reflection and begin to converge. At the point of convergence, the second diffraction grating is placed symmetrically to the first, so that when reflected from it, the beams due to diffraction reflection are combined into one output beam with a composite spectrum and the same direction and size. The source indicates the application of this principle for the spectral addition of fiber lasers, in our case it is used for intracavity conversion of radiation within a single solid-state active element.

The objectives of the utility model are to simplify the method of generating lasing pulses with a fixed time delay between them and combining the radiation of several spatially separated lasing channels.

The essence of the utility model is that in a laser resonator consisting of a rear mirror, an active solid-state element, a passive shutter for generating giant pulses, a spectral element similar to a group velocity dispersion compensator and, outputted from a saturable absorber made of a saturable absorber, an output mirror is formed , by modulating the gain distribution in the active element, several closely spaced generation channels, each of which in The process of establishing the radiation distribution during diffraction propagation under conditions of inhomogeneous amplification accelerates generation in the adjacent channel and sets a fixed time delay between them, also each channel spatially spaced in the volume of the active element, having a different spectral distribution, when a spectral element passes similar to the group velocity dispersion compensator, decreases on the diaphragmed output mirror and, combined with other channels, forms a single in space and output beam divergences, with a time distribution of the intensity of all the generation channels. In contrast to the prototype, the utility model allows the generation of more than two consecutive lasing pulses with an adjustable time delay, this is achieved by synchronizing nearby lasing channels due to the partial overlap of the lasing modes of the laser channels during their diffraction propagation under conditions of inhomogeneous amplification during laser pregeneration with passive Q-switching and using a spectral element similar to the group velocity dispersion compensator to combine radiation from several spatially separated generation channels.

The utility model is illustrated in the figure.

The figure shows a diagram of a multi-channel sequential pulse generator with an adjustable time delay and spectral addition of the output beam (MGPI).

A multi-channel sequential pulse generator with an adjustable time delay and spectral addition of the output beam (MGPI) includes a rear mirror of a laser resonator 1, a laser active element 2, a first passive shutter made of a saturable absorber 3, a spectral element similar to a group velocity dispersion compensator 4, and a second passive shutter made from a saturable absorber 5 and a front (output) mirror 6.

To confirm the operability of the utility model, an experimental-computational scheme with the specification of the elements described above was considered. The rear mirror 1 was dichroic and had a reflection coefficient for the generation wavelengths of the order of 1, and for the pump wavelength near 0. It was sprayed onto one of the ends of the active element.

8×2 мм и

8×0,5 мм. При этом элементы 3 и 5 имели начальное пропускание порядка 80% и 95%, соответственно.As the active element 2, we used a Cr: LiCaF crystal with a diameter of 6.2 mm and a length of 20 mm with a dichroic coating on the second face with a reflection of ~ 100% for pump radiation and antireflection for the lasing wavelength. In it, during end-pumping, several channels were formed in which generation occurs. To do this, we used the mapping of the output ends of the diode modules with a fiber output using a lens into the volume of the active element. The size of the pump channels in the active element should be slightly smaller than the constriction of the main Gaussian mode (w _g ) characteristic of such a resonator at the central generation wavelength. The distance between the centers of the pump channels is selected for the specific required delay, but to be in the range from [2w _g <d <3w _g ]. In the utility model, w _g = 730 μm were considered. The pump intensities are also selected to provide the necessary delay, so as to provide close gain in the medium at the time of joint generation for different channels with an accuracy of several percent, taking into account the inhomogeneous gain line in the active element for different wavelengths. As saturable absorbers 3 and 5, Cr: YAG crystals with various thicknesses were used,

8 × 2 mm and

8 × 0.5 mm. Moreover, elements 3 and 5 had an initial transmission of about 80% and 95%, respectively.

All elements are mounted coaxially as shown in figure 1.

The spectral element for the spectral addition of laser channels 4 was realized using two identical diffraction gratings. Lattice constant 1200 lines / mm. Gloss angle 36.5 degrees. The gratings (4a and 4b) are arranged symmetrically to each other at a distance of 185 mm and at an angle to the axis of the other elements of 21.4 degrees. The angles are selected depending on the specific diffraction gratings and the required wavelengths. For Cr: LiCaF, the central wavelength is near 780. And the distance between the gratings is set so as to ensure the coincidence of the generation beams of different channels on the grating 4b. So in different channels set different wavelengths λ ₁ ; λ _... λ _n .

The output mirror, to perform a utility model on the active element Cr: LiCaF, must be spherical to compensate for the negative thermal lens. Radius of curvature ~ 1000 mm, reflection coefficient 75%.

To obtain the necessary effect of the formation of generation channels and their synchronization, it is important to use a saturable absorber, since this effect is associated with tying the modes of neighboring channels in the pre-generation mode. The use of a rigid diaphragm (holes as diaphragms) is also unacceptable. Its use prevents the appearance of higher-order modes. And the use of a saturable absorber as a spatial filter makes it possible to introduce higher losses into the resonator for higher modes after its clarification, this is explained by the large transverse dimensions of higher order modes and the associated large volume of saturable absorber. The ratio between the initial gate transmittances must be tied to the number of generation channels so that the saturable absorber 5 has an absorption lower than the total absorption for all generation channels on element 3.

A multi-channel sequential pulse generator with an adjustable time delay and spectral addition of the output beam (MGPI) works as follows.

When end pumped through a dichroic mirror in the volume of the active element, several amplification channels are spatially separated from each other. Initially, since the absorption in the Cr: YAG crystals is not saturated, its effect on the generation modes is equivalent to uniform cavity losses. This leads to the fact that in all channels the development of generation at different wavelengths begins. Moreover, each generation channel, with its diffraction propagation under conditions of inhomogeneous amplification, seeks to impose coherently coupled radiation on the neighboring channel and form a supermode that has a larger transverse dimension than the generation mode of the channel itself (Hermite-Gaussian zero mode). By adjusting the pump power in the channels, it is possible to achieve that in the extreme channel, which has only one channel adjacent to it, generation develops faster than in the others (leading channel). The next generation in terms of speed of development should be neighboring (slave) with it, and so on. The leading channel, interacting with the neighboring one with a certain probability, depending on the distance between the channels and the gain difference in the channels, imposes coherent radiation from the same wavelength on it (forms a supermode). Such an interaction leads to unstable coherence of adjacent channels at time intervals of the order of the photon lifetime in the cavity. The resulting supermode has a characteristic size close to the distance between the channels, which accelerates the illumination of the gate 3, the area of the slave channel, and thereby accelerates the generation process in it, not only for the coherent supermode, but also for all other modes and wavelengths. Thus, it is possible to obtain a fixed time delay between pulses from adjacent channels determined by the probability of coherent addition of channels. A similar situation occurs between other channels. In the future, a partial bleaching of the saturable absorber 5 takes place, moreover, it does not bleach uniformly, but mainly in the region with the highest intensity of pregeneration radiation. This leads to a sharp change in the losses for modes of different transverse sizes and thereby accelerates the development of generation of Hermite-Gauss zero modes with different wavelengths for different channels. Thus, the generation of zero modes with such a spectrum is imposed on all channels that the combined radiation of all channels has minimal transverse dimensions. This corresponds to spectral addition with intracavity selection of the generation wavelengths. To confirm the operability of this utility model, a computational and experimental model for four generation channels was implemented. As a result, the wavelength difference between the generation channels was ~ 3.4 nm, and the time delay between the generation pulses was regulated in the range from 26 to 173 ns. The half-width of the lasing pulse was ~ 41 ns, and the total output energy was ~ 2.83 mJ.

Thus, the tasks of the utility model were realized, namely, the method for generating lasing pulses with a fixed time delay between them was simplified and the radiation from several spatially separated lasing channels was combined.

1. Vorobyov N.S., Konoplev O.A. A two-channel neodymium glass laser with a continuously tunable delay between the generation channels // Quantum Electronics. - 1991. - T. 18. - No. 3 .-- S. 292-294. - prototype

2. Arumov G.P. et al. Two-pulse YAG: Nd 3+ laser with a non-delay controlled in the range of 20-100 // Quantum Electronics. - 1988. - T. 15. - No. 9. - S. 1744-1750.

3. US patent No. 11342336. Publ. 04/03/07, H01S 3/23

Claims (2)

1. A multi-channel sequential pulse generator with an adjustable time delay and spectral addition of the output beam, consisting of a rear mirror, an active solid-state element, a passive shutter for generating giant pulses, a spectral element similar to a group velocity dispersion compensator and diaphragmed with a soft spatial selector made of a saturable absorber , an output mirror, characterized in that it contains diode modules with a fiber output, a lens, compressing the output ends of the diode modules with a fiber output into the volume of the active element in which several closely spaced lasing channels are formed, the size of the pump channels in the active element should be less than the waist of the main Gaussian mode (w _g ), which is characteristic of a resonator at a central lasing wavelength, for To ensure the necessary delay between the generation pulses, the pump intensities and the distance between the centers of the pump channels (d) are selected in the range [2w _g <d <3wg]. 2. A multi-channel sequential pulse generator with an adjustable time delay and spectral addition of the output beam according to claim 1, characterized in that it contains an active element, in the volume of which there are spatially separated channels with different spectral distributions in each, a spectral element similar to a group velocity dispersion compensator passing through which and reaching the output mirror that is diaphragmed by a saturable absorber, the radiation from spatially separated channels is combined and azuet uniform over space and divergence of the output beam from the temporal distribution of the intensities of all channels of generation.

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