Valery Bychenkov

Главная - Valery Bychenkov - Publications 2016-2021

Publications 2016-2021

295. O.E.Vais, S.G.Bochkarev, and V.Yu.Bychenkov, On the Theory of Nonlinear Thomson
Scattering of a Highly Focused Laser Pulse. Bull. Lebedev Phys. Inst., 2016, 43, N1, 16-19.

296. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Nonlinear Plasma Resonance in Inhomogeneous
Relativistic Plasma. Bull. Lebedev Phys. Inst., 2016, 43, N1, 12-15.

297. S.I.Glazyrin, A.S.Kuratov, and V.Yu.Bychenkov, Separation of Ions on the Front of a
Shock Wave in a Multicomponent Plasma. JETP Lett., 2016, 103, N4, 238-243.

298. I.N.Tsymbalov, K.A.Ivanov, R.V.Volkov, A.B.Saveliev, L.S.Novikov, L.I.Galanina, N.P.Chirskaya,
V.Yu.Bychenkov, A.I.Chumakov, Laser-plasma sources of ionizing radiation for simulation
of radiation eects in microelectronic materials and components. Physics and
Chemistry of Materials Treatment, 2016, N1, 25-30 (In Rus.).

299. W.Rozmus, T.Chapman, A.Brantov, B.J.Winjum, R.L.Berger, S.Brunner, V.Yu.Bychenkov,
A.Tableman, M.Tzoufras, and S.Glenzer, Resonance between heat-carrying electrons
and Langmuir waves in inertial confinement fusion plasmas. Phys. Plasmas, 2016, 23,
N1, 012707(1-11).

300. V.Yu.Bychenkov, A.V.Brantov, and E.A.Govras, Comparative study of ion acceleration
by linearly polarized laser pulses from optimized targets of solid and near-critical
density. Plasma Phys. Contr. Fus. Special Issue, 2016, 58, N3, 034022(1 -5).

301. A.V.Brantov, E.A.Govras, V.F.Kovalev, and V.Yu.Bychenkov, Synchronized ion acceleration
by ultraintense slow light. Phys. Rev. Lett., 2016, 116, 085004(1-5).

302. A.V.Brantov, D.V.Romanov, and V.Yu.Bychenkov, Optimization of a laser-based proton
source and a new mechanism of ion acceleration. IEEE Trans. Plasma Sci., 2016,
44, N4, 364 - 368.

303. A.V.Brantov, M.G.Lobok, and V.Yu.Bychenkov, Target optimisation for the yield of
X-rays of desired hardness under femtosecond pulse irradiation. Quantum Electronics,
2016, 46, N4, 342-346.

304. E.I.Ageev, V.Yu.Bychenkov, V.P.Veiko, A.A.Ionin, S. I. Kudryashov, A.A.Petrov, and
A.A.Samokhvalov, Two-pulse femtosecond laser ablation of steel surface with variable
interpulse delay. JETP Lett., 2016, 104, N6, 421-424.

305. E.I.Ageev, V.Yu.Bychenkov, A.A.Ionin, S.I.Kudryashov, A.A.Petrov, A.A.Samokhvalov,
and V.P.Veiko, Double-pulse femtosecond laser peening of aluminum alloy AA5038:
Effect of inter-pulse delay on transient optical plume emission and final surface microhardness.
Appl. Phys. Lett., 2016, 109, N21, 211902(1-4).

306. V.Yu.Bychenkov, A.V.Brantov, and E.A.Govras, Acceleration of ions by "slow" intense
laser light in low-density targets. JETP Lett., 2016, 104, N9, 618-623.

307. O.E.Vais, S.G.Bochkarev, and V.Yu.Bychenkov, Nonlinear Thomson scattering of a
relativistically strong tightly focused ultrashort laser pulse, Plasma Phys. Rep., 2016,
42, N9, 818-833.

308. A.S.Kuratov, A.V.Brantov, Yu.M.Aliev, and V.Yu.Bychenkov, Terahertz emission from
laser-induced charge separation in irradiating plasma target. Quantum Electronics,
2016, 46, N11 1023-1030.

309. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Renormgroup algorithm for the theory
of the relativistic plasma resonance, J. Phys. Conf. Ser., 2016, 769, 012083(1-6).

310. V.Yu.Bychenkov and W.Rozmus, A model of anomalous absorption of laser light on
ion acoustic turbulence. Phys. Plasmas, 2017, 24, N1, 012701(1-8).

311. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Nonlinear relativistic plasma resonance:
renormalization group approach. Plasma Phys. Rep., 2017, 43, N2, 175-190.

312. A.V.Brantov and V.Yu.Bychenkov, Synchronized ion acceleration by ultraintense slow
light and electron source for X-ray production from low-density targets. Plasma Phys.
Contr. Fus. Special Issue, 2017, 59, N3, 034009(1-3).

313. O.E.Vais, S.G.Bochkarev, S. Ter-Avetisyan, and V.Yu.Bychenkov, Angular distribution
of electrons directly accelerated by an intense tightly focused laser pulse. Quantum
Electronics, 2017, 47, N1, 38-41.

314. A.V.Brantov, M.G.Lobok, and V.Yu.Bychenkov, Increase in the yield of hot electrons
and gamma radiation by selecting the thickness of a pre-plasma target irradiated by a
short laser pulse. Quantum Electronics, 2017, 47, N3, 232-235.

315. V.Yu.Bychenkov, P.K.Singh, H.Ahmed, K.F.Kakolee, C.Scullion, T.W.Jeong, P.Hadjisolomou,
A.Alejo, S.Kar, M.Borghesi, and S.Ter-Avetisyan, Ion acceleration in electrostatic field
of charged cavity created by ultra-short laser pulses of 10201021 W/cm2. Phys. Plasmas,
2017, 24, N1, 010704(1-6).

316. A.V.Brantov, E.A.Obraztsova, A.L.Chuvilin, E.D.Obraztsova, and V.Yu.Bychenkov,
Laser-triggered proton acceleration from hydrogenated low-density targets. Phys. Rev.
AB, 2017, 20, N6, 061301(1-6).

317. N.Tsymbalov, K.A.Ivanov, R.V.Volkov, A.B.Savelev, L.S.Novikov, L.I.Galanina, N.P.Chirskaya,
V.Yu. Bychenkov, A.I.Chumakov, Laser-plasma sources of ionizing radiation for simulation
of radiation effects in microelectronic materials and components. Inorganic
Materials: Applied Research, 2017, 8, N3, 359-363.

318. K.A.Ivanov, I.N.Tsymbalov, S.A.Shulyapov, D.A.Krestovskikh, A.V.Brantov, V.Yu.Bychenkov,
R.V.Volkov, and A.B.Savelev, Prepulse controlled electron acceleration from solids by
a femtosecond laser pulse in the slightly relativistic regime. Phys. Plasmas, 2017, 24,
N6, 063109(1-10).

319. K.Ivanov, D.Gozhev, S.Rodichkina, S.V.Makarov, S.S.Makarov, M.Dubatkov, S. Pikuz,
D.Presnov, A.Paskhalov, N.Eremin, A.Brantov, V.Bychenkov, R.Volkov, V.Timoshenko,
S.Kudryashov, and A.Savel'ev, Nanostructured plasmas for enhanced gamma emission
at relativistic laser interaction with solids. Appl. Phys. B, 2017, 123, N 10, 252(1-9).

320. W.Rozmus, A.Brantov, C.Fortmann-Grote, V.Yu.Bychenkov, and S.Glenzer, Electrostatic
uctuations in collisional plasmas. Phys. Rev. E, 2017, 96, 043207(1-15).

321. V.F.Kovalev, S.G.Bochkarev, and V.Yu.Bychenkov, Radial acceleration of ions during
adiabatic expansion of a multicomponent cylindrical plasma, Quantum Electronics,
2017, 47, N11, 1023-1030.

322. A.Brantov, P.A.Ksenofontov, and V.Yu.Bychenkov, Comparison of optimized ion acceleration
from thin foils and low-density targets for linearly and circularly polarized
laser pulses. Phys. Plasmas, 2017, 24, N11, 113102(1-8).

323. W.Rozmus, A.Brantov, M.Sherlock, V.Yu.Bychenkov, Return current instability driven
by a temperature gradient in ICF plasmas. Plasma Phys. Contr. Fus., 2018, 60, N1,
014004(1-6).

324. N.Naseri, S.G.Bochkarev, P.Ruran, and V.Yu.Bychenkov, V.Khudik, and G.Shvets,
Growth and propagation of self-generated magnetic dipole vortices in collisionless
shocks produced by interpenetrating plasmas. Phys. Plasmas, 2018, 25, N1, 012118(1-7).

325. V.F.Kovalev and V.Yu.Bychenkov, Self-focusing of a light beam in a medium with
relativistic nonlinearity: new analytical solutions. JETP Lett., 2018, 107, N8, 458-463.

326. M.G.Lobok, A.V.Brantov, D.A.Gozhev, and V. Yu. Bychenkov, Optimization of electron
acceleration by short laser pulses from low-density targets. Plasma Phys. Contr.
Fus. Special Issue, 2018, 60, N8, 084010(1-5).

327. A.S.Kuratov, A.V.Brantov, Yu.M.Aliev, and V.Yu.Bychenkov, Laser-induced thermoelectric
current as a source of generation of THz surface electromagnetic waves. Quantum
Electronics, 2018, 48, N7, 653-657.

328. S.Ter-Avetisyan, P.K.Singh, K.F.Kakolee, H.Ahmed, T.W.Jeong, C.Scullion, P.Hadjisolomou,
M.Borghesi, and V.Yu.Bychenkov, Ultrashort PW laser pulse interaction with target
and ion acceleration. Nucl. Instrum. Methods Phys. Res. A, 2018, 909, 156-159.

329. S.G.Bochkarev, A.Faenov, T.Pikuz, A.V.Brantov, V.F.Kovalev, I.Skobelev, S.Pikuz,
R.Kodama, K.I.Popov, and V.Yu.Bychenkov, Ion energy spectra directly measured in
the interaction volume of intense laser pulses with clustered plasma. Sci. Rep., 2018,
8, 9404(1-8).

330. V.Yu.Bychenkov, Ion acoustic turbulence driven by return current leads to hot electrons
in laser-produced plasma. Phys. Plasmas, 2018, 25, N10, 102706(1-5).

331. O.E.Vais and V.Yu.Bychenkov, Direct electron acceleration for diagnostics of a laser
pulse focused by an o-axis parabolic mirror. Appl. Phys. B 124, N11, 211(1 -13).

332. K.A.Ivanov, I.N.Tsymbalov, O.E. Vais, S.G.Bochkarev, V.Yu.Bychenkov, and A.B.Savelev,
Accelerated electrons for in-situ peak intensity monitoring of tightly focused femtosecond
laser radiation at high intensities. Plasma Phys. Contr. Fus., 2018, 60, N10, 105011(1-8).

333. A.V.Brantov, A.S.Kuratov, A.Maksimchuk, Yu.M.Aliev, and V.Yu.Bychenkov, Laser
induced THz Sommerfeld waves along metal wire. EPJWeb. Conf., 2018, 195, 03002(1-2).

334. A.S.Kuratov, A.V.Brantov, and V.Yu.Bychenkov, Modeling of laser generation and
propagation of electron bunch along thin irradiated wire. Bull. Lebedev Phys. Inst.,
2018, 45, N11, 346-349.

335. E.A.Govras and V.Yu.Bychenkov, Spectral-dynamic model of expansion of the hot
plasma slab. JETP, 2019, 128, N1, 133-157.

336. S.G.Bochkarev, E.D'Humires, V.T.Tikhonchuk, Ph.Korneev, and V.Yu.Bychenkov,
Stochastic electron heating in an interference field of several laser pulses of a picosecond
duration. Plasma Phys. Contr. Fus., 2019, 61, N2, 025015(1-12).

337. V.F.Kovalev and V.Yu.Bychenkov, Analytical theory of relativistic self-focusing for
Gaussian light beam entering a plasma: renormalization-group approach. Phys. Rev.
E, 2019, 99, N4, 043201(1-12).

338. I.N.Tsymbalov, D.A.Gorlova, V.Yu.Bychenkov, and A.B.Savelev, Electron parametric
instabilities in nonuniform plasma with a strong density gradient excited by femtosecond
laser pulses of subrelativistic intensity. Quantum Electronics, 2019, 49, N4, 386-390.

339. A.V.Brantov, Ph.Korneev, and V.Yu.Bychenkov, Magnetic field generation from a coilshaped
foil by a laser-triggered hot-electron current. Laser Physics Letters, 2019, 16, N6, 066006 (1-5).

340. I.Tsymbalov, D.Gorlova, S.Shulyapov, V.Prokudin, A.Zavorotny, K.Ivanov, R.Volkov,
V.Bychenkov, V.Nedorezov, A.Paskhalov, N.Eremin, and A.Savel'ev, Well collimated
MeV electron beam generation in the plasma channel from relativistic laser-solid interaction.
Plasma Phys. Contr. Fus., 2019, 61, N7, 075016(1 -17).

341. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Higher-order harmonic generation of
laser radiation due to relativistic plasma resonance. Phys. Plasmas, 2019, 26, N11,
113113(1-15).

342. V.Yu.Bychenkov, M.G.Lobok, V.F.Kovalev, and A.V.Brantov, Generation of highcharge
electron beam in a subcritical-density plasma through laser pulse self-trapping.
Plasma Phys. Contr. Fus., 2019, 61, N12, 124004(1-6).

343. M.G.Lobok, A.V.Brantov, and V.Yu.Bychenkov, Effective production of gammas, positrons,
and photonuclear particles from optimized electron acceleration by short laser pulses
in low-density targets. Phys. Plasmas, 2019, 26, N12, 123107(1-11).

344. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Harmonic generation by relativistic
plasma resonance. J. Russian Laser Research, 2019, 40, N5, 429-434.

345. O.E.Vais, A.G.R.Thomas, A.Maksimchuk, K.Krushelnick, and V.Yu.Bychenkov. Characterizing
extreme laser intensities by ponderomotive acceleration of protons from rarified gas. New J. Phys., 2020, 22

Publications 2016-2021

295. O.E.Vais, S.G.Bochkarev, and V.Yu.Bychenkov, On the Theory of Nonlinear ThomsonScattering of a Highly Focused Laser Pulse. Bull. Lebedev Phys. Inst., 2016, 43, N1, 16-19.

296. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Nonlinear Plasma Resonance in InhomogeneousRelativistic Plasma. Bull. Lebedev Phys. Inst., 2016, 43, N1, 12-15.

299. W.Rozmus, T.Chapman, A.Brantov, B.J.Winjum, R.L.Berger, S.Brunner, V.Yu.Bychenkov,A.Tableman, M.Tzoufras, and S.Glenzer, Resonance between heat-carrying electronsand Langmuir waves in inertial con finement fusion plasmas. Phys. Plasmas, 2016, 23,N1, 012707(1-11).

300. V.Yu.Bychenkov, A.V.Brantov, and E.A.Govras, Comparative study of ion accelerationby linearly polarized laser pulses from optimized targets of solid and near-criticaldensity. Plasma Phys. Contr. Fus. Special Issue, 2016, 58, N3, 034022(1 -5).

301. A.V.Brantov, E.A.Govras, V.F.Kovalev, and V.Yu.Bychenkov, Synchronized ion accelerationby ultraintense slow light. Phys. Rev. Lett., 2016, 116, 085004(1-5).

302. A.V.Brantov, D.V.Romanov, and V.Yu.Bychenkov, Optimization of a laser-based protonsource and a new mechanism of ion acceleration. IEEE Trans. Plasma Sci., 2016,44, N4, 364 - 368.

303. A.V.Brantov, M.G.Lobok, and V.Yu.Bychenkov, Target optimisation for the yield ofX-rays of desired hardness under femtosecond pulse irradiation. Quantum Electronics,2016, 46, N4, 342-346.

304. E.I.Ageev, V.Yu.Bychenkov, V.P.Veiko, A.A.Ionin, S. I. Kudryashov, A.A.Petrov, andA.A.Samokhvalov, Two-pulse femtosecond laser ablation of steel surface with variableinterpulse delay. JETP Lett., 2016, 104, N6, 421-424.

306. V.Yu.Bychenkov, A.V.Brantov, and E.A.Govras, Acceleration of ions by "slow" intenselaser light in low-density targets. JETP Lett., 2016, 104, N9, 618-623.

307. O.E.Vais, S.G.Bochkarev, and V.Yu.Bychenkov, Nonlinear Thomson scattering of arelativistically strong tightly focused ultrashort laser pulse, Plasma Phys. Rep., 2016,42, N9, 818-833.

308. A.S.Kuratov, A.V.Brantov, Yu.M.Aliev, and V.Yu.Bychenkov, Terahertz emission fromlaser-induced charge separation in irradiating plasma target. Quantum Electronics,2016, 46, N11 1023-1030.

309. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Renormgroup algorithm for the theoryof the relativistic plasma resonance, J. Phys. Conf. Ser., 2016, 769, 012083(1-6).

312. A.V.Brantov and V.Yu.Bychenkov, Synchronized ion acceleration by ultraintense slowlight and electron source for X-ray production from low-density targets. Plasma Phys.Contr. Fus. Special Issue, 2017, 59, N3, 034009(1-3).

313. O.E.Vais, S.G.Bochkarev, S. Ter-Avetisyan, and V.Yu.Bychenkov, Angular distributionof electrons directly accelerated by an intense tightly focused laser pulse. QuantumElectronics, 2017, 47, N1, 38-41.

314. A.V.Brantov, M.G.Lobok, and V.Yu.Bychenkov, Increase in the yield of hot electronsand gamma radiation by selecting the thickness of a pre-plasma target irradiated by ashort laser pulse. Quantum Electronics, 2017, 47, N3, 232-235.

315. V.Yu.Bychenkov, P.K.Singh, H.Ahmed, K.F.Kakolee, C.Scullion, T.W.Jeong, P.Hadjisolomou,A.Alejo, S.Kar, M.Borghesi, and S.Ter-Avetisyan, Ion acceleration in electrostatic fieldof charged cavity created by ultra-short laser pulses of 10201021 W/cm2. Phys. Plasmas,2017, 24, N1, 010704(1-6).

316. A.V.Brantov, E.A.Obraztsova, A.L.Chuvilin, E.D.Obraztsova, and V.Yu.Bychenkov,Laser-triggered proton acceleration from hydrogenated low-density targets. Phys. Rev.AB, 2017, 20, N6, 061301(1-6).

318. K.A.Ivanov, I.N.Tsymbalov, S.A.Shulyapov, D.A.Krestovskikh, A.V.Brantov, V.Yu.Bychenkov,R.V.Volkov, and A.B.Savelev, Prepulse controlled electron acceleration from solids bya femtosecond laser pulse in the slightly relativistic regime. Phys. Plasmas, 2017, 24,N6, 063109(1-10).

320. W.Rozmus, A.Brantov, C.Fortmann-Grote, V.Yu.Bychenkov, and S.Glenzer, Electrostatic uctuations in collisional plasmas. Phys. Rev. E, 2017, 96, 043207(1-15).

321. V.F.Kovalev, S.G.Bochkarev, and V.Yu.Bychenkov, Radial acceleration of ions duringadiabatic expansion of a multicomponent cylindrical plasma, Quantum Electronics,2017, 47, N11, 1023-1030.

324. N.Naseri, S.G.Bochkarev, P.Ruran, and V.Yu.Bychenkov, V.Khudik, and G.Shvets,Growth and propagation of self-generated magnetic dipole vortices in collisionlessshocks produced by interpenetrating plasmas. Phys. Plasmas, 2018, 25, N1, 012118(1-7).

325. V.F.Kovalev and V.Yu.Bychenkov, Self-focusing of a light beam in a medium withrelativistic nonlinearity: new analytical solutions. JETP Lett., 2018, 107, N8, 458-463.

326. M.G.Lobok, A.V.Brantov, D.A.Gozhev, and V. Yu. Bychenkov, Optimization of electronacceleration by short laser pulses from low-density targets. Plasma Phys. Contr.Fus. Special Issue, 2018, 60, N8, 084010(1-5).

327. A.S.Kuratov, A.V.Brantov, Yu.M.Aliev, and V.Yu.Bychenkov, Laser-induced thermoelectriccurrent as a source of generation of THz surface electromagnetic waves. QuantumElectronics, 2018, 48, N7, 653-657.

328. S.Ter-Avetisyan, P.K.Singh, K.F.Kakolee, H.Ahmed, T.W.Jeong, C.Scullion, P.Hadjisolomou,M.Borghesi, and V.Yu.Bychenkov, Ultrashort PW laser pulse interaction with targetand ion acceleration. Nucl. Instrum. Methods Phys. Res. A, 2018, 909, 156-159.

329. S.G.Bochkarev, A.Faenov, T.Pikuz, A.V.Brantov, V.F.Kovalev, I.Skobelev, S.Pikuz,R.Kodama, K.I.Popov, and V.Yu.Bychenkov, Ion energy spectra directly measured inthe interaction volume of intense laser pulses with clustered plasma. Sci. Rep., 2018,8, 9404(1-8).

330. V.Yu.Bychenkov, Ion acoustic turbulence driven by return current leads to hot electronsin laser-produced plasma. Phys. Plasmas, 2018, 25, N10, 102706(1-5).

331. O.E.Vais and V.Yu.Bychenkov, Direct electron acceleration for diagnostics of a laserpulse focused by an o -axis parabolic mirror. Appl. Phys. B 124, N11, 211(1 -13).

332. K.A.Ivanov, I.N.Tsymbalov, O.E. Vais, S.G.Bochkarev, V.Yu.Bychenkov, and A.B.Savelev,Accelerated electrons for in-situ peak intensity monitoring of tightly focused femtosecondlaser radiation at high intensities. Plasma Phys. Contr. Fus., 2018, 60, N10, 105011(1-8).

333. A.V.Brantov, A.S.Kuratov, A.Maksimchuk, Yu.M.Aliev, and V.Yu.Bychenkov, Laserinduced THz Sommerfeld waves along metal wire. EPJWeb. Conf., 2018, 195, 03002(1-2).

334. A.S.Kuratov, A.V.Brantov, and V.Yu.Bychenkov, Modeling of laser generation andpropagation of electron bunch along thin irradiated wire. Bull. Lebedev Phys. Inst.,2018, 45, N11, 346-349.

337. V.F.Kovalev and V.Yu.Bychenkov, Analytical theory of relativistic self-focusing forGaussian light beam entering a plasma: renormalization-group approach. Phys. Rev.E, 2019, 99, N4, 043201(1-12).

338. I.N.Tsymbalov, D.A.Gorlova, V.Yu.Bychenkov, and A.B.Savelev, Electron parametricinstabilities in nonuniform plasma with a strong density gradient excited by femtosecondlaser pulses of subrelativistic intensity. Quantum Electronics, 2019, 49, N4, 386-390.

339. A.V.Brantov, Ph.Korneev, and V.Yu.Bychenkov, Magnetic field generation from a coilshapedfoil by a laser-triggered hot-electron current. Laser Physics Letters, 2019, 16, N6, 066006 (1-5).

341. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Higher-order harmonic generation oflaser radiation due to relativistic plasma resonance. Phys. Plasmas, 2019, 26, N11,113113(1-15).

342. V.Yu.Bychenkov, M.G.Lobok, V.F.Kovalev, and A.V.Brantov, Generation of highchargeelectron beam in a subcritical-density plasma through laser pulse self-trapping.Plasma Phys. Contr. Fus., 2019, 61, N12, 124004(1-6).

343. M.G.Lobok, A.V.Brantov, and V.Yu.Bychenkov, Effective production of gammas, positrons,and photonuclear particles from optimized electron acceleration by short laser pulsesin low-density targets. Phys. Plasmas, 2019, 26, N12, 123107(1-11).

344. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Harmonic generation by relativisticplasma resonance. J. Russian Laser Research, 2019, 40, N5, 429-434.

345. O.E.Vais, A.G.R.Thomas, A.Maksimchuk, K.Krushelnick, and V.Yu.Bychenkov. Characterizingextreme laser intensities by ponderomotive acceleration of protons from rarifi ed gas. New J. Phys., 2020, 22

295. O.E.Vais, S.G.Bochkarev, and V.Yu.Bychenkov, On the Theory of Nonlinear Thomson
Scattering of a Highly Focused Laser Pulse. Bull. Lebedev Phys. Inst., 2016, 43, N1, 16-19.

296. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Nonlinear Plasma Resonance in Inhomogeneous
Relativistic Plasma. Bull. Lebedev Phys. Inst., 2016, 43, N1, 12-15.

299. W.Rozmus, T.Chapman, A.Brantov, B.J.Winjum, R.L.Berger, S.Brunner, V.Yu.Bychenkov,
A.Tableman, M.Tzoufras, and S.Glenzer, Resonance between heat-carrying electrons
and Langmuir waves in inertial confinement fusion plasmas. Phys. Plasmas, 2016, 23,
N1, 012707(1-11).

300. V.Yu.Bychenkov, A.V.Brantov, and E.A.Govras, Comparative study of ion acceleration
by linearly polarized laser pulses from optimized targets of solid and near-critical
density. Plasma Phys. Contr. Fus. Special Issue, 2016, 58, N3, 034022(1 -5).

301. A.V.Brantov, E.A.Govras, V.F.Kovalev, and V.Yu.Bychenkov, Synchronized ion acceleration
by ultraintense slow light. Phys. Rev. Lett., 2016, 116, 085004(1-5).

302. A.V.Brantov, D.V.Romanov, and V.Yu.Bychenkov, Optimization of a laser-based proton
source and a new mechanism of ion acceleration. IEEE Trans. Plasma Sci., 2016,
44, N4, 364 - 368.

303. A.V.Brantov, M.G.Lobok, and V.Yu.Bychenkov, Target optimisation for the yield of
X-rays of desired hardness under femtosecond pulse irradiation. Quantum Electronics,
2016, 46, N4, 342-346.

304. E.I.Ageev, V.Yu.Bychenkov, V.P.Veiko, A.A.Ionin, S. I. Kudryashov, A.A.Petrov, and
A.A.Samokhvalov, Two-pulse femtosecond laser ablation of steel surface with variable
interpulse delay. JETP Lett., 2016, 104, N6, 421-424.

306. V.Yu.Bychenkov, A.V.Brantov, and E.A.Govras, Acceleration of ions by "slow" intense
laser light in low-density targets. JETP Lett., 2016, 104, N9, 618-623.

307. O.E.Vais, S.G.Bochkarev, and V.Yu.Bychenkov, Nonlinear Thomson scattering of a
relativistically strong tightly focused ultrashort laser pulse, Plasma Phys. Rep., 2016,
42, N9, 818-833.

308. A.S.Kuratov, A.V.Brantov, Yu.M.Aliev, and V.Yu.Bychenkov, Terahertz emission from
laser-induced charge separation in irradiating plasma target. Quantum Electronics,
2016, 46, N11 1023-1030.

309. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Renormgroup algorithm for the theory
of the relativistic plasma resonance, J. Phys. Conf. Ser., 2016, 769, 012083(1-6).

312. A.V.Brantov and V.Yu.Bychenkov, Synchronized ion acceleration by ultraintense slow
light and electron source for X-ray production from low-density targets. Plasma Phys.
Contr. Fus. Special Issue, 2017, 59, N3, 034009(1-3).

313. O.E.Vais, S.G.Bochkarev, S. Ter-Avetisyan, and V.Yu.Bychenkov, Angular distribution
of electrons directly accelerated by an intense tightly focused laser pulse. Quantum
Electronics, 2017, 47, N1, 38-41.

314. A.V.Brantov, M.G.Lobok, and V.Yu.Bychenkov, Increase in the yield of hot electrons
and gamma radiation by selecting the thickness of a pre-plasma target irradiated by a
short laser pulse. Quantum Electronics, 2017, 47, N3, 232-235.

315. V.Yu.Bychenkov, P.K.Singh, H.Ahmed, K.F.Kakolee, C.Scullion, T.W.Jeong, P.Hadjisolomou,
A.Alejo, S.Kar, M.Borghesi, and S.Ter-Avetisyan, Ion acceleration in electrostatic field
of charged cavity created by ultra-short laser pulses of 10201021 W/cm2. Phys. Plasmas,
2017, 24, N1, 010704(1-6).

316. A.V.Brantov, E.A.Obraztsova, A.L.Chuvilin, E.D.Obraztsova, and V.Yu.Bychenkov,
Laser-triggered proton acceleration from hydrogenated low-density targets. Phys. Rev.
AB, 2017, 20, N6, 061301(1-6).

318. K.A.Ivanov, I.N.Tsymbalov, S.A.Shulyapov, D.A.Krestovskikh, A.V.Brantov, V.Yu.Bychenkov,
R.V.Volkov, and A.B.Savelev, Prepulse controlled electron acceleration from solids by
a femtosecond laser pulse in the slightly relativistic regime. Phys. Plasmas, 2017, 24,
N6, 063109(1-10).

320. W.Rozmus, A.Brantov, C.Fortmann-Grote, V.Yu.Bychenkov, and S.Glenzer, Electrostatic
uctuations in collisional plasmas. Phys. Rev. E, 2017, 96, 043207(1-15).

321. V.F.Kovalev, S.G.Bochkarev, and V.Yu.Bychenkov, Radial acceleration of ions during
adiabatic expansion of a multicomponent cylindrical plasma, Quantum Electronics,
2017, 47, N11, 1023-1030.

324. N.Naseri, S.G.Bochkarev, P.Ruran, and V.Yu.Bychenkov, V.Khudik, and G.Shvets,
Growth and propagation of self-generated magnetic dipole vortices in collisionless
shocks produced by interpenetrating plasmas. Phys. Plasmas, 2018, 25, N1, 012118(1-7).

325. V.F.Kovalev and V.Yu.Bychenkov, Self-focusing of a light beam in a medium with
relativistic nonlinearity: new analytical solutions. JETP Lett., 2018, 107, N8, 458-463.

326. M.G.Lobok, A.V.Brantov, D.A.Gozhev, and V. Yu. Bychenkov, Optimization of electron
acceleration by short laser pulses from low-density targets. Plasma Phys. Contr.
Fus. Special Issue, 2018, 60, N8, 084010(1-5).

327. A.S.Kuratov, A.V.Brantov, Yu.M.Aliev, and V.Yu.Bychenkov, Laser-induced thermoelectric
current as a source of generation of THz surface electromagnetic waves. Quantum
Electronics, 2018, 48, N7, 653-657.

328. S.Ter-Avetisyan, P.K.Singh, K.F.Kakolee, H.Ahmed, T.W.Jeong, C.Scullion, P.Hadjisolomou,
M.Borghesi, and V.Yu.Bychenkov, Ultrashort PW laser pulse interaction with target
and ion acceleration. Nucl. Instrum. Methods Phys. Res. A, 2018, 909, 156-159.

329. S.G.Bochkarev, A.Faenov, T.Pikuz, A.V.Brantov, V.F.Kovalev, I.Skobelev, S.Pikuz,
R.Kodama, K.I.Popov, and V.Yu.Bychenkov, Ion energy spectra directly measured in
the interaction volume of intense laser pulses with clustered plasma. Sci. Rep., 2018,
8, 9404(1-8).

330. V.Yu.Bychenkov, Ion acoustic turbulence driven by return current leads to hot electrons
in laser-produced plasma. Phys. Plasmas, 2018, 25, N10, 102706(1-5).

331. O.E.Vais and V.Yu.Bychenkov, Direct electron acceleration for diagnostics of a laser
pulse focused by an o-axis parabolic mirror. Appl. Phys. B 124, N11, 211(1 -13).

332. K.A.Ivanov, I.N.Tsymbalov, O.E. Vais, S.G.Bochkarev, V.Yu.Bychenkov, and A.B.Savelev,
Accelerated electrons for in-situ peak intensity monitoring of tightly focused femtosecond
laser radiation at high intensities. Plasma Phys. Contr. Fus., 2018, 60, N10, 105011(1-8).

333. A.V.Brantov, A.S.Kuratov, A.Maksimchuk, Yu.M.Aliev, and V.Yu.Bychenkov, Laser
induced THz Sommerfeld waves along metal wire. EPJWeb. Conf., 2018, 195, 03002(1-2).

334. A.S.Kuratov, A.V.Brantov, and V.Yu.Bychenkov, Modeling of laser generation and
propagation of electron bunch along thin irradiated wire. Bull. Lebedev Phys. Inst.,
2018, 45, N11, 346-349.

337. V.F.Kovalev and V.Yu.Bychenkov, Analytical theory of relativistic self-focusing for
Gaussian light beam entering a plasma: renormalization-group approach. Phys. Rev.
E, 2019, 99, N4, 043201(1-12).

338. I.N.Tsymbalov, D.A.Gorlova, V.Yu.Bychenkov, and A.B.Savelev, Electron parametric
instabilities in nonuniform plasma with a strong density gradient excited by femtosecond
laser pulses of subrelativistic intensity. Quantum Electronics, 2019, 49, N4, 386-390.

339. A.V.Brantov, Ph.Korneev, and V.Yu.Bychenkov, Magnetic field generation from a coilshaped
foil by a laser-triggered hot-electron current. Laser Physics Letters, 2019, 16, N6, 066006 (1-5).

341. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Higher-order harmonic generation of
laser radiation due to relativistic plasma resonance. Phys. Plasmas, 2019, 26, N11,
113113(1-15).

342. V.Yu.Bychenkov, M.G.Lobok, V.F.Kovalev, and A.V.Brantov, Generation of highcharge
electron beam in a subcritical-density plasma through laser pulse self-trapping.
Plasma Phys. Contr. Fus., 2019, 61, N12, 124004(1-6).

343. M.G.Lobok, A.V.Brantov, and V.Yu.Bychenkov, Effective production of gammas, positrons,
and photonuclear particles from optimized electron acceleration by short laser pulses
in low-density targets. Phys. Plasmas, 2019, 26, N12, 123107(1-11).

344. I.I.Metelskii, V.F.Kovalev, and V.Yu.Bychenkov, Harmonic generation by relativistic
plasma resonance. J. Russian Laser Research, 2019, 40, N5, 429-434.

345. O.E.Vais, A.G.R.Thomas, A.Maksimchuk, K.Krushelnick, and V.Yu.Bychenkov. Characterizing
extreme laser intensities by ponderomotive acceleration of protons from rarified gas. New J. Phys., 2020, 22