Transport of electron beams and stability of optical windows 
in high-power e-beam-pumped krypton fluoride lasers

Зворыкин, В. Д.; Arlantsev, S V; Bakaev, Valerii G.; Rantsev, O. V.; Sergeev, P. B.; Sychugov, G. V.; Tserkovnikov, A.Yu.

doi:10.1017/s0263034601194085

Cited by 24 publications

(10 citation statements)

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“…Experiments are performed at Berdysh laser module [6], which is pumped by 80x1200-mm cross-section e-beam of 50-A/cm 2 peak current, 70-ns pulse duration, and ~250-350 keV average electron energy. Specific pumping power is of ~0.6-0.8 MW/cm 3 Fluorescence and absorption spectra are registered at pressures from 0.2 to 2.5 atm in the spectral range from 190 to 510 nm with the broadband spectrometer equipped with CCD-array.…”

Section: Methodsmentioning

confidence: 99%

Fluorescence and transient absorption spectra of excimer laser mixtures

2008

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Section: Methodsmentioning

confidence: 99%

Fluorescence and transient absorption spectra of excimer laser mixtures

2008

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“…Experiments were performed at "Berdysh" preamplifier module of GARPUN KrF laser facility [12]. A gas mixture Ar/Kr/F 2 = 0.3/8.9/91.8% at total pressure up to p = 1.8 atm was filling the laser chamber of 10*10 cm 2 cross-section and I I I I I I I I of 170-cm length.…”

Section: Methodsmentioning

confidence: 99%

Fluorescence and transient absorption spectra of Ar/Kr/F 2 mixtures excited by e-beam

Зворыкин

Kholin

Левченко

et al. 2006

XVI International Symposium on Gas Flow, Chemical Lasers, and High-Power Lasers

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Time-resolved fluorescence of Ar/Kr/F 2 mixtures and transient absorption spectra were measured at Berdysh preamplifier module of GARPUN KrF laser facility pumped by 50 A/cm 2 , 350 keV, 100 ns e-beam. The experiments pursued an aim to obtain additional data on KrF laser kinetics, in particular, on the formation of Kr 2 F molecules and their influence on the absorption and extraction of KrF laser radiation in large-scale amplifiers. A possibility of femtosecond laser pulses amplification at broad-band Kr 2 F (4 2 Γ→1,2 2 Γ) transition is discussed.

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“…laser-plasma interaction during the past two decades at 0.1-10.0 kJ-class single-shot KrF facilities AURORA (Los Alamos National Laboratory; LANL) (Rosocha et al, 1986(Rosocha et al, , 1987Harris et al, 1993), NIKE Naval Research Laboratory (NRL) (Obenschain et al, 1996;Pawley et al, 1997Pawley et al, , 1999Aglitskiy et al, 2002), SPRITE (RAL) National Institute of Advanced Industrial Science and Technology (Shaw et al, 1993(Shaw et al, , 1999Divall et al, 1996), ASHURA National Institute of Advanced Industrial Science and Technology (AIS & T) (Owadano et al, 1989(Owadano et al, , 1993(Owadano et al, , 1999(Owadano et al, , 2001 and GARPUN Lebedev Physical Institute (LPI) (Basov et al, 1993;Zvorykin & Lebo, 1999;Zvorykin et al, 2001Zvorykin et al, , 2004Zvorykin et al, , 2006aWang et al, 2002), and especially at rep-rate Electra laser (NRL) (Sethian et al, 1998Wolford et al, 2006) have proved that e-beam-pumped KrF laser might be the best challenge for direct-drive ICF power plant. To satisfy physical and economical requirements, they should be scaled to output energies of 30-60 kJ per one module, operating all together with the total laser energy of $2 MJ at rep-rate of 5 Hz and overall system efficiency of 7.5% (Svyatoslavsky et al, 1992;Von Rosenberg, 1992;McGeoch et al, 1997;Sethian et al, 2003).…”

Section: Krf Drivers In the Fast-ignition Icf Problemmentioning

confidence: 99%

GARPUN-MTW: A hybrid Ti:Sapphire/KrF laser facility for simultaneous amplification of subpicosecond/nanosecond pulses relevant to fast-ignition ICF concept

Зворыкин

Didenko²,

Ионин

et al. 2007

Laser Part. Beams

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The first stage of the petawatt excimer laser project started at the P.N. Lebedev Physical Institute, implements a development of multiterawatt hybrid GARPUN-MTW laser facility for generation of ultra-high intensity subpicosecond ultraviolet (UV) laser pulses. Under this project, a multi-stage e-beam-pumped 100-J, 100-ns GARPUN KrF laser was upgraded with a femtosecond Ti:Sapphire front-end, to produce combined subpicosecond/nanosecond laser pulses with variable time delay. Attractive possibility to amplify simultaneously short and long pulses in the same large-scale KrF amplifiers is analyzed with regard to the fast-ignition, inertial confinement fusion problem. Detailed description of hybrid laser system is presented with synchronized KrF and Ti:Sapphire master oscillators. Based on gain and absorption measurements at GARPUN amplifier and numerical simulations with a quasi-stationary code, we are predicting that 1.6 J can be obtained in a short pulse at hybrid GARPUN-MTW Ti:Sapphire/KrF laser facility, combined with several tens of joules in nanosecond pulse. Amplified spontaneous emission, which is responsible for the pre-pulse formation on a target, was also investigated: its acceptable level can be provided by properly choosing staged gain or loading the amplifiers by quasi-steady laser radiation. Fluorescence and transient absorption spectra of Ar/Kr/F 2 mixtures conventionally used in KrF amplifiers were recorded to find out the possibility for femtosecond pulse amplification at the broadband Kr 2 F (4 2 G ! 1,2 2 G) transition, which benefits in 100 times higher saturation energy density than for KrF (B ! X) transition.

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Transport of electron beams and stability of optical windows in high-power e-beam-pumped krypton fluoride lasers

Cited by 24 publications

References 0 publications

Fluorescence and transient absorption spectra of excimer laser mixtures

Fluorescence and transient absorption spectra of excimer laser mixtures

Fluorescence and transient absorption spectra of Ar/Kr/F 2 mixtures excited by e-beam

GARPUN-MTW: A hybrid Ti:Sapphire/KrF laser facility for simultaneous amplification of subpicosecond/nanosecond pulses relevant to fast-ignition ICF concept

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