Your search keyword '"Ratakhin, N. A."' showing total 261 results

1. Implosion of heavy metal liners driven by megaampere current pulses.

Author

Oreshkin, V. I., Baksht, R. B., Chaikovsky, S. A., Cherdizov, R. K., Kokshenev, V. A., Kurmaev, N. E., Mesyats, G. A., Oreshkin, E. V., Ratakhin, N. A., Rousskikh, A. G., Zherlitsyn, A. A., and Zhigalin, A. S.

Subjects

SKIN effect, COPPER, HEAVY metals, ELECTRIC potential measurement, TUBES

Abstract

This paper describes a theoretical and experimental study of the implosion of heavy copper liners shaped as hollow cylindrical tubes having an outer diameter of 3 and 4 mm and a wall thickness of 500 μm; the tube linear mass was 0.35 and 0.5 g/cm, respectively. The experiment was carried out on the GIT-12 pulsed-power generator (5 MA, 2 μs). Under these experimental conditions, a skin effect occurred in an imploding tube. The implosion process was numerically simulated based on a radiative magnetohydrodynamic model. Both the experiment and the simulation have shown a fluctuating voltage across the tube. According to the simulation, the first fluctuation peak, followed by a sharp decrease in voltage, is associated with the "collapse" of the tube on the axis and the formation of a strong shock wave. The times at which first voltage peaks were detected in the experiment and the first peak occurrence times obtained in the simulation coincided to within 5–10%, and the experimentally obtained and the calculated voltage amplitudes differed by about 20–30%. Thus, the results of the experiment suggest that using oscilloscopic measurements of the voltage across a heavy metal tube, it is possible to detect the shock wave generated in the conductive material of the tube and to determine the collapse time. [ABSTRACT FROM AUTHOR]

Published

2024

2. Effect of the geometrical parameters of an X-pinch on the characteristics of the soft x-ray source.

Author

Artyomov, A. P., Oreshkin, V. I., Rousskikh, A. G., Rybka, D. V., Fedyunin, A. V., Chaikovsky, S. A., and Ratakhin, N. A.

Subjects

PULSE generators, X-rays, ANGLES, ELECTRODES, NECK, SOFT X rays

Abstract

It was studied how the geometrical parameters of an X-pinch (the angle of inclination of the wires to the X-pinch vertical axis and the length of the electrode gap) affected the number of hot spots, formed in the region of the X-pinch neck, and the x-ray yield. The experiment was performed on the XPG-3 compact current pulse generator (180 kA, 180 ns). The highest values of the x-ray energy per pulse were observed when the angle of inclination of the wires to the X-pinch load vertical axis (z-axis) was 40°–45° at an electrode gap length of 6–7 mm. In these cases, the energy of the x-ray pulse in the spectral range hν = 1.5–5 keV was 1.1 ± 0.4 J. The angle of inclination of the X-pinch wires to the z-axis equal to 45° was a threshold above which the conditions for the formation of a hot spot changed significantly. It was observed that, regardless of the wire inclination angle, two hot spots formed with a high degree of probability in the neck region at the final stage of implosion. [ABSTRACT FROM AUTHOR]

Published

2024

3. On the Size of the Soft X-Ray Radiation Source Based on an X-Pinch

Author

Artyomov, A. P., Chaikovsky, S. A., Oreshkin, V. I., Fedunin, A. V., Rousskikh, A. G., and Ratakhin, N. A.

Published

2020

4. A Pulsed Electron Beam Accelerator

Author

Vasilev, K. Yu., Kachalkov, A. A., Petin, V. K., Ratakhin, N. A., Serebryannikov, M. E., and Erfort, A. A.

Published

2020

5. Filamentation of the surface plasma layer during the electrical explosion of conductors in strong magnetic fields.

Author

Oreshkin, V. I., Chaikovsky, S. A., Datsko, I. M., Labetskaya, N. A., Oreshkin, E. V., Ratakhin, N. A., Rousskikh, A. G., Vankevich, V. A., and Chuvatin, A. S.

Subjects

MAGNETIC fields, FILAMENTATION instability, THERMAL instability, ELECTRON temperature, METALLIC surfaces

Abstract

A model has been considered to describe the development of a surface discharge over a conductor electrically exploding in a strong magnetic field. A simulation performed using this model has shown that in the initial stage of the conductor explosion, a plasma layer of several tens of micrometers thick with an electron temperature of several electronvolts is formed on the metal surface. Based on the theory of small perturbations, the development of thermal filamentation instabilities that form in the surface plasma layer has been analyzed. The characteristic growth rates and wavelengths of these instabilities have been determined. The theoretical results were compared with the results of experiments performed on the ZEBRA generator (providing load currents of amplitude about 1 MA and rise time about 100 ns) and on the MIG generator (providing load currents of amplitude about 2 MA and rise time about 100 ns). For the conditions implemented with these generators, the filamentation model gives rise times of thermal filamentation instabilities of tens of nanoseconds at characteristic wavelengths of the order of 100 μm. These values are in good agreement with experimental data, which indicates the adequacy of both the surface discharge development model and the filamentation model. [ABSTRACT FROM AUTHOR]

Published

2022

6. Peculiarities of an Electrical Explosion of Flat Conductors in the Current Skinning Mode

Author

Chaikovskii, S. A., Oreshkin, V. I., Labetskaya, N. A., Datsko, I. M., Rybka, D. V., Vankevich, V. A., and Ratakhin, N. A.

Published

2019

7. Generation of magnetosonic waves by electrical explosion of conductors driven by mega-ampere current pulses.

Author

Oreshkin, V. I., Baksht, R. B., Chaikovsky, S. A., Cherdizov, R. K., Kokshenev, V. A., Kurmaev, N. E., Mesyats, G. A., Oreshkin, E. V., Ratakhin, N. A., Rousskikh, A. G., Zherlitsyn, A. A., and Zhigalin, A. S.

Subjects

ELECTRICAL conductors, PULSE generators, COPPER, ELECTRIC impedance, OSCILLATIONS

Abstract

An experimental study of the explosion of cylindrical copper rods in the current skinning mode was performed using the GIT-12 high-current pulse generator with currents of amplitude up to 5 MA and rise time about 2 μs. It was observed that the waveforms of the electrical impedance of the exploded rods exhibited low-frequency oscillations with a period of several hundreds of nanoseconds. The results of the experiment with exploded solid copper rods carried out on the GIT-12 facility were interpreted by performing a series of magnetohydrodynamic calculations. It was shown that the experimentally observed low-frequency oscillations of the rod impedance were associated with a fast magnetosonic wave excited in the material of the rod. [ABSTRACT FROM AUTHOR]

Published

2023

8. Small-Size High-Current Generators for X-Ray Backlighting

Author

Chaikovsky, S. A., Artyomov, A. P., Zharova, N. V., Zhigalin, A. S., Lavrinovich, I. V., Oreshkin, V. I., Ratakhin, N. A., Rousskikh, A. G., Fedunin, A. V., Fedushchak, V. F., and Erfort, A. A.

Published

2017

9. THL-100 Multi-Terawatt Laser System of Visible Range

Author

Alekseev, S. V., Ivanov, M. V., Ivanov, N. G., Losev, V. F., Mesyats, G. A., Mikheev, L. D., Panchenko, Yu. N., Ratakhin, N. A., and Yastremskii, A. G.

Published

2017

10. Foil explosion in megagauss magnetic fields: Non-uniform expansion and instabilities

Author

Chaikovsky, S. A., primary, Datsko, I. M., additional, Labetskaya, N. A., additional, Oreshkin, E. V., additional, Oreshkin, V. I., additional, Ratakhin, N. A., additional, Rousskikh, A. G., additional, Vankevich, V. A., additional, Zhigalin, A. S., additional, and Baksht, R. B., additional

Published

2022

11. Parameters of the THL-100 Hybrid Femtosecond Laser System After Modernization

Author

Alekseev, S. V., Ivanov, M. V., Ivanov, N. G., Losev, V. F., Mesyats, G. A., Panchenko, Yu. N., and Ratakhin, N. A.

Published

2015

12. A synchronized X-pinch driver

Author

Artyomov, A. P., Zhigalin, A. S., Lavrinovich, I. V., Oreshkin, V. I., Ratakhin, N. A., Rousskikh, A. G., Fedyunin, A. V., Chaikovsky, S. A., Erfort, A. A., Mitrofanov, K. N., Grabovski, E. V., Alexandrov, V. V., and Smirnov, V. P.

Published

2014

13. A compact pulsed X-ray source for high-speed radiography

Author

Lavrinovich, I. V., Zharova, N. V., Petin, V. K., Ratakhin, N. A., Fedushchak, V. F., Shlyakhtun, S. V., and Erfort, A. A.

Published

2013

14. A double-frame nanosecond soft X-ray backlighting system based on X-pinches

Author

Artyomov, A. P., Fedyunin, A. V., Chaikovsky, S. A., Zhigalin, A. S., Oreshkin, V. I., Ratakhin, N. A., and Rousskikh, A. G.

Published

2013

15. Determining thermodynamic parameters of aluminum X-pinch plasma

Author

Artyomov, A. P., Fedyunin, A. V., Chaikovsky, S. A., Oreshkin, V. I., Lavrinovich, I. V., and Ratakhin, N. A.

Published

2013

16. X-pinch source of subnanosecond soft X-ray pulses based on small-sized low-inductance current generator

Author

Mesyats, G. A., Shelkovenko, T. A., Ivanenkov, G. V., Agafonov, A. V., Savinov, S. Yu., Pikuz, S. A., Tilikin, I. N., Tkachenko, S. I., Chaikovskii, S. A., Ratakhin, N. A., Fedushchak, V. F., Oreshkin, V. I., Fedyunin, A. V., Russkikh, A. G., Labetskaya, N. A., Artemov, A. P., Hammer, D. A., and Sinars, D. B.

Published

2010

17. X-ray source for irradiation of large-area objects

Author

Petin, V. K., Shljakhtun, S. V., Oreshkin, V. I., and Ratakhin, N. A.

Published

2008

18. Mapping of azimuthal B-fields in Z-pinch plasmas using Z-pinch-driven ion deflectometry

Author

Munzar, V., primary, Klir, D., additional, Cikhardt, J., additional, Kravarik, J., additional, Kubes, P., additional, Malir, J., additional, Novotny, J., additional, Rezac, K., additional, Shishlov, A. V., additional, Kokshenev, V. A., additional, Cherdizov, R. K., additional, and Ratakhin, N. A., additional

Published

2021

19. K-shell radiation and neutron emission from z-pinch plasmas generated by hybrid gas-puff implosions onto on-axis wires

Author

Klir, D., primary, Shishlov, A. V., additional, Kokshenev, V. A., additional, Cherdizov, R. K., additional, Cikhardt, J., additional, Fursov, F. I., additional, Kravarik, J., additional, Kubes, P., additional, Kurmaev, N. E., additional, Malir, J., additional, Munzar, V., additional, Novotny, J., additional, Ratakhin, N. A., additional, and Rezac, K., additional

Published

2021

20. A compact pulse generator for radiographic source supply

Author

Ratakhin, N. A., Fedushchak, V. F., Erfort, A. A., Zharova, N. V., Zhidkova, N. A., Chaikovskii, S. A., and Oreshkin, V. I.

Published

2007

21. A small low-inductance capacitor charged with 200-kV pulses

Author

Saushkin, A. V., Zharova, N. V., Kim, A. A., Ratakhin, N. A., and Fedushchak, V. F.

Published

2006

22. Fast energy output from a high-current pulsed capacitor by using a pseudospark gap

Author

Zharova, N. V., Ratakhin, N. A., Saushkin, A. V., Fedushchak, V. F., and Erfort, A. A.

Published

2006

23. Formation of tight plasma pinches and generation of high-power soft x-ray radiation pulses in fast Z-pinch implosions

Author

Shishlov, A. V., Baksht, R. B., Chaikovsky, S. A., Fedunin, A. V., Fursov, F. I., Kokshenev, V. A., Kurmaev, N. E., Labetsky, A. Yu., Oreshkin, V. I., Ratakhin, N. A., Russkikh, A. G., and Shlykhtun, S. V.

Published

2006

24. Study of the pd reaction at ultralow energies using hydrogen liner plasma

Author

Bystritsky, V. M., Bystritskii, Vit. M., Dudkin, G. N., Gerasimov, V. V., Krylov, A. R., Mesyats, G. A., Nechaev, B. A., Padalko, V. M., Parzhitsky, S. S., Pen’kov, F. M., Ratakhin, N. A., and Wozniak, J.

Published

2005

25. Studies on the implosion of pinches with tailored density profiles

Author

Oreshkin, V I, primary, Baksht, R B, additional, Cherdizov, R K, additional, Oreshkin, E V, additional, Ratakhin, N A, additional, Rousskikh, A G, additional, Shishlov, A V, additional, Vankevich, V A, additional, and Zhigalin, A S, additional

Published

2021

26. Measurement of the astrophysical S factor for dd interaction at ultralow deuteron-collision energies using the inverse Z pinch

Author

Bystritsky, Vyach. M., Gerasimov, V. V., Krylov, A. R., Parzhitski, S. S., Pen’kov, F. M., Shvyryaev, O. M., Stolupin, V. A., Dudkin, G. N., Nechaev, B. A., Padalko, V. M., Wozniak, J., Mesyats, G. A., Bystritskii, Vit. M., Makhrin, V. I., and Ratakhin, N. A.

Published

2003

27. Deuterium liner and multiparametric studies of the formation of an inverse Z-pinch

Author

Bystritskii, Vit. M., Bystritsky, Vyach. M., Wozniak, J., Grebenyuk, V. M., Gula, E., Dudkin, G. N., Mesyats, G. A., Nechaev, B. A., Padalko, V. N., Parzhitski, S. S., Pen’kov, F. M., Ratakhin, N. A., Sorokin, S. A., and Stolupin, V. A.

Published

2002

28. Astrophysical S factor for dd interaction at ultralow energies

Author

Bystritskii, Vit. M., Bystritsky, V. M., Chaikovsky, S. A., Filipowicz, M., Grebenyuk, V. M., Guła, E., Makhrin, V. I., Mesyats, G. A., Parzhitski, S. S., Pen’kov, F. M., Ratakhin, N. A., Sinebryukhov, V. A., Sorokin, S. A., Stolupin, V. A., Volkov, E. N., and Woźniak, J.

Published

2001

29. High-voltage insulation of a high-power pulse transformer

Author

Ratakhin, N. A. and Fedushchak, V. F.

Published

1999

30. Generation of hard breaking radiation on the MIG system with a plasma opening switch

Author

Kablambaev, B. A., Ratakhin, N. A., and Shlyakhtun, S. V.

Published

1999

31. Production of energetic protons, deuterons, and neutrons up to 60 MeV via disruption of a current-carrying plasma column at 3 MA

Author

Klir, D, primary, Shishlov, A V, additional, Kokshenev, V A, additional, Jackson, S L, additional, Rezac, K, additional, Cherdizov, R K, additional, Cikhardt, J, additional, Dudkin, G N, additional, Fursov, F I, additional, Krasa, J, additional, Kravarik, J, additional, Kubes, P, additional, Kurmaev, N E, additional, Munzar, V, additional, Ratakhin, N A, additional, Turek, K, additional, and Varlachev, V A, additional

Published

2020

32. Neutron fluence distribution in experiments with 3 MA deuterium gas-puff z-pinch

Author

Cikhardt, J., primary, Klir, D., additional, Shishlov, A. V., additional, Kokshenev, V. A., additional, Rezac, K., additional, Cherdizov, R. K., additional, Dudkin, G. N., additional, Fursov, F. I., additional, Kravarik, J., additional, Kubes, P., additional, Kurmaev, N. E., additional, Munzar, V., additional, Novotny, J., additional, Ratakhin, N. A., additional, Turek, K., additional, and Varlachev, V. A., additional

Published

2020

33. Ion acceleration and neutron production in hybrid gas-puff z-pinches on the GIT-12 and HAWK generators

Author

Klir, D., primary, Jackson, S. L., additional, Shishlov, A. V., additional, Kokshenev, V. A., additional, Rezac, K., additional, Beresnyak, A. R., additional, Cherdizov, R. K., additional, Cikhardt, J., additional, Cikhardtova, B., additional, Dudkin, G. N., additional, Engelbrecht, J. T., additional, Fursov, F. I., additional, Krasa, J., additional, Kravarik, J., additional, Kubes, P., additional, Kurmaev, N. E., additional, Munzar, V., additional, Ratakhin, N. A., additional, Turek, K., additional, and Varlachev, V. A., additional

Published

2020

34. Spatial distribution of ion emission in gas-puff z-pinches and dense plasma foci

Author

Klir, D, primary, Shishlov, A V, additional, Jackson, S L, additional, Kokshenev, V A, additional, Kubes, P, additional, Rezac, K, additional, Beresnyak, A R, additional, Cherdizov, R K, additional, Cikhardt, J, additional, Cikhardtova, B, additional, Dudkin, G N, additional, Engelbrecht, J T, additional, Fursov, F I, additional, Kaufman, J, additional, Krasa, J, additional, Kravarik, J, additional, Kurmaev, N E, additional, Munzar, V, additional, Ratakhin, N A, additional, Turek, K, additional, and Varlachev, V A, additional

Published

2020

35. High-voltage generator with inductive energy store and plasma-based microsecond current interrupter

Author

Kablambaev, B. A. and Ratakhin, N. A.

Published

1997

36. Multipurpose transformer-type pulse generator

Author

Luchinskii, A. V., Ratakhin, N. A., Fedushchak, V. F., and Shepelev, A. N.

Published

1997

37. Generation of powerful X-rays in the range 7–20 keV

Author

Ratakhin, N. A.

Published

1997

38. Recombination X-ray radiation from plasma liners

Author

Oreshkin, V. I., Baksht, R. B., Labetskii, A. Yu., Ratakhin, N. A., Russkikh, A. G., Chaikovsky, S. A., Fedyunin, A. V., and Shishlov, A. V.

Published

2005

39. Peskar' — An electron beam generator for industrial applications

Author

Ratakhin, N. A., Fedushchak, V. F., and Shepelev, A. N.

Published

1995

40. X-radiation from a SNOP-1 unit

Author

Bespalov, V. I., Buryak, I. A., Petin, V. K., Ratakhin, N. A., Ryzhov, V. V., and Turchanovskii, I. Yu.

Published

1995

41. Powerful pulsed electrophysical transformers from the Institute of High-Current Electronics, Siberian Branch of the Russian Academy of Sciences

Author

Luchinskii, A. V., Ratakhin, N. A., Fedushchak, V. F., and Shepelev, A. N.

Published

1995

42. Operation of a plasma-filled diode

Author

Baksht, R. B., Buryak, I. A., Petin, V. K., Ratakhin, N. A., Fedyunin, A. V., and Shishlov, A. V.

Published

1995

43. High-powered generator with high-voltage forming-line charging by electroexplosion of conductors

Author

Luchinskii, A. V., Makhrin, V. I., Ratakhin, N. A., and Chertov, A. A.

Published

1995

44. The astrophysical S-factor for dd-reactions at keV-energy range

Author

Bystritskii, V., Bystritsky, V., Chaikovsky, S., Filipowicz, M., Grebenyuk, V., Gula, E., Makhrin, V., Mesyats, G., Parzhitski, S., Pen’kov, F., Ratakhin, N., Sinebryukhov, V., Sorokin, S., Stolupin, V., Volkov, E., and Woźniak, J.

Abstract

The experimental results of measurements of the astrophysical S-factor for dd-reaction at keV-energy range collision energies using liner plasma technique are presented. The experiments were carried out at the high current generator of the Institute of High-Current Electronics in Tomsk, Russia. The measured values of the S-factors for the deuteron collision energies 1.80, 2.06 and 227 keV are Sdd=(114±68),(64±30),(53±16)b⋅keV,${{S}_{dd}}=(114\pm 68),(64\pm 30),(53\pm 16)b\cdot keV,$respectively. The corresponding cross sections for dd-reactions, described as a product of the barrier factor and measured astrophysical S-factor, areσddn(Ecol=1.80keV)=(4.3±2.6).$\sigma _{dd}^{n}\left( {{E}_{col}}=1.80\text{keV} \right)=(4.3\pm 2.6).$10−33cm2;σddn(Ecol=2.06keV)=(9.8±4.6)⋅10−33cm2;σddn(Ecol=${{10}^{-33}}~c{{m}^{2}};\sigma _{dd}^{n}\left( {{E}_{col}}=2.06\text{keV} \right)=(9.8\pm 4.6)\cdot {{10}^{-33}}~c{{m}^{\text{2}}};\sigma _{dd}^{n}\left( {{E}_{col}}= \right.$

Published

2022

45. Acceleration of protons and deuterons up to 35 MeV and generation of 1013 neutrons in a megaampere deuterium gas-puff z-pinch

Author

Klir, D, primary, Shishlov, A V, additional, Kokshenev, V A, additional, Kubes, P, additional, Rezac, K, additional, Buryskova, S, additional, Cherdizov, R K, additional, Cikhardt, J, additional, Cikhardtova, B, additional, Dudkin, G N, additional, Engelbrecht, J T, additional, Fursov, F I, additional, Jackson, S L, additional, Krasa, J, additional, Kravarik, J, additional, Kurmaev, N E, additional, Munzar, V, additional, Padalko, V N, additional, Ratakhin, N A, additional, Sila, O, additional, Turek, K, additional, Varlachev, V A, additional, and Wagner, R, additional

Published

2018

46. Ion acceleration mechanism in mega-ampere gas-puff z-pinches

Author

Klir, D, primary, Shishlov, A V, additional, Kokshenev, V A, additional, Kubes, P, additional, Rezac, K, additional, Cherdizov, R K, additional, Cikhardt, J, additional, Cikhardtova, B, additional, Dudkin, G N, additional, Fursov, F I, additional, Hyhlik, T, additional, Kaufman, J, additional, Kovalchuk, B M, additional, Krasa, J, additional, Kravarik, J, additional, Kurmaev, N E, additional, Labetsky, A Yu, additional, Munzar, V, additional, Orcikova, H, additional, Padalko, V N, additional, Ratakhin, N A, additional, Sila, O, additional, Stodulka, J, additional, Turek, K, additional, Varlachev, V A, additional, and Wagner, R, additional

Published

2018

47. Hybrid THL-100 laser system: results and prospect.

Author

Losev, V. F., Alekseev, S. V., Ivanov, M. V., Ivanov, N. G., Mesyats, G. A., Mikheev, L. D., Panchenko, Yu. N., Ratakhin, N. A., and Yastremsky, A. G.

Published

2019

48. Development of hybrid (solid/gas state) ultra-high power femtosecond laser system on the basis of XeF(C-A) amplifier

Author

Kovalchuk B Kovalchuk B, Yastremsky A Yastremsky A, Alekseev S Alekseev S, Panchenko Yu Panchenko Yu, Mesyats G Mesyats G, Mikheev L Mikheev L, Ratakhin N Ratakhin N, Puchikin A Puchikin A, Losev V Losev, and Ivanov N Ivanov N

Subjects

Materials science, business.industry, Amplifier, Pulse duration, Laser, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, law.invention, Capacitor, Optics, law, Femtosecond, Cathode ray, business, Diffraction grating, Diode

Abstract

A terawatt hybrid laser(THL-100) system on the basis of a starting complex and a final amplifier with gaseous optically driven active media on XeF(C-A) molecules is presented.The starting complex manufactured consists of a Ti: sapphire master oscillator pumped by femtosecond pulses from a continuous laser pumped by(Verdy-8) at a wavelength of 532 nm,a femtosecond pulse stretcher,regenerative and multipass amplifiers pumped by a pulsed laser at a wavelength of 532 nm,a diffraction grating compressor and a second harmonic generator(KDP).The complex has the following output parameters of the laser beam: pulse duration is 50 fs,the energy of radiation at the second harmonic(475 nm) is 5 mJ.The complex can operate in a single pulse mode and a frequency of 10 Hz. The XeF(C-A) amplifier consists of a two high-voltage pulsed generator(linear transformer),a vacuum diode with six cold explosive-emission cathodes,a electron beam injection system,a Xe filled gas chamber-converter and a laser cell.The high-voltage generator consists of 12 transformer stages,and each of them involves eight capacitors(one is C=40 nF) and spark gaps.The capacitors can be charged up to voltage of 100 kV.E-beam in vacuum diode has the parameters in total current of 300 kA,peak voltage of 550 kV,pulse duration of e-beam power about 150 ns(FWHM).The total energies of the six 100 cm ×12 cm e-beams which pass through the foil into the Xe converter are 6-7 kJ in the 150-160 ns pulse(FWHM).Pump energy cascade processes lead rapidly to the formation of Xe*2,which radiates a fraction of the deposited energy in the continuum at(172 ± 5) nm.This VUV radiation is transmitted through CaF2 windows into the laser cell containing the mixture of XeF2 vapour and N2 buffer gas.VUV radiation makes photolysis of XeF2 molecules form XeF* excimer molecules.The active medium of the amplifier pumped by VUV radiation has 24 cm aperture and 110 cm length.The results of numerical modeling of the output parameters and first experimental results are presented in this paper.According to the modeling of the XeF(C-A) amplifier parameters and the first measurement of gain,it is shown that the maxmum output energy is 2-3 J,which means that the peak power has been up to 40-60 TW in a 50 fs pulse.Furthermore,It is very important that this laser system can provide a high temporal contrast up to 109-1010.

Published

2011

49. Neutron Spectrum Measured by Activation Diagnostics in Deuterium Gas-Puff Experiments on the 3 MA GIT-12 Z-Pinch

Author

Cikhardt, J., primary, Klir, D., additional, Rezac, K., additional, Shishlov, A. V., additional, Cherdizov, R. K., additional, Cikhardtova, B., additional, Dudkin, G. N., additional, Fursov, F. I., additional, Kokshenev, V. A., additional, Kravarik, J., additional, Kubes, P., additional, Kurmaev, N. E., additional, Labetsky, A. Yu., additional, Padalko, V. N., additional, Ratakhin, N. A., additional, Sila, O., additional, Turek, K., additional, and Varlachev, V. A., additional

Published

2017

50. Conditions of the generation of subnanosecond pulses in a THL-100 laser system

Author

Ivanov, M. V., primary, Alekseev, S. V., additional, Ivanov, N. G., additional, Losev, V. F., additional, Ratakhin, N. A., additional, and Yastremskii, A. G., additional

Published

2017