41.75.Jv Laser-driven acceleration 52.38.Kd Laser-plasma acceleration of electrons and ions 87.50.−a Effects of electromagnetic and acoustic fields on biological systems 87.53.Jw Therapeutic applications, including brachytherapy 87.55.−x Treatment strategy 87.56.−v Radiation therapy equipment

A.A. Soloviev, K.F. Burdonov et al “Research in plasma physics and particle acceleration using the PEARL petawatt laser” 67 293–313 (2024)
42.55.f, 52.30.q, 52.38.r, 52.38.Kd
S.V. Popruzhenko, A.M. Fedotov “Dynamics and radiation of charged particles in ultra-intense laser fields” 66 460–493 (2023)
41.75.Jv, 52.38.−r, 52.40.Mj (all)
A.B. Dyachkov, A.A. Gorkunov et al “Isotopically selective photoionization for the production of the medical radioisotope ¹⁷⁷Lu” 66 518–533 (2023)
28.60.+s, 42.62.−b, 87.56.−v (all)
A.A. Ivanov, A.N. Smirnov et al “Accelerator-based neutron source for boron neutron capture therapy” 65 834–851 (2022)
29.20.−c, 29.25.Dz, 87.19.xj, 87.53.−j, 87.55.−x (all)
G.N. Makarov “Control of the parameters and composition of molecular and cluster beams by means of IR lasers” 61 617–644 (2018)
06.30.−k, 07.77.Gx, 33.80.−b, 36.40.−c, 41.75.Jv, 42.62.Fi, 82.50.Hp (all)
G.I. Klenov, V.S. Khoroshkov “Hadron therapy: history, status, prospects” 59 807–825 (2016)
87.19.xj, 87.55.−x, 87.56.−v (all)
B.L. Zhuikov “Success and problems in development of medical radioisotope production in Russia” 59 481–486 (2016)
28.65.+s, 87.53.−j, 87.56.−v (all)
T.K. Breus, V.N. Binhi, A.A. Petrukovich “Magnetic factor of the solar terrestrial relations and its impact on the human body: physical problems and prospects for research” 59 502–510 (2016)
87.10.−e, 87.18.Yt, 87.50.−a, 94.30.Va (all)
E.A. Krasavin “Radiobiological research at JINR's accelerators” 59 411–418 (2016)
87.53.−j, 87.56.−v (all)
V.Yu. Bychenkov, A.V. Brantov et al “Laser acceleration of ions: recent results and prospects for applications” 58 71–81 (2015)
52.38.Kd, 52.50.Jm, 52.65.Rr, 87.57.uh (all)
I.Yu. Kostyukov, A.M. Pukhov “Plasma-based methods for electron acceleration: current status and prospects” 58 81–88 (2015)
41.75.Jv, 52.35.−g, 52.38.Kd (all)
S.V. Bulanov, Ja.J. Wilkens et al “Laser ion acceleration for hadron therapy” 57 1149–1179 (2014)
41.75.Jv, 52.38.Kd, 87.50.−a, 87.53.Jw, 87.55.−x, 87.56.−v (all)
S.V. Akulinichev “Promising nuclear medicine research in the Institute of Nuclear Research, Russian Academy of Sciences” 57 1239–1243 (2014)
87.19.xj, 87.53.Jw, 87.56.−v (all)
V.P. Milant’ev “Cyclotron autoresonance — 50 years since discovery” 56 823–832 (2013)
01.65.+g, 41.75.Jv, 76.40.+b (all)
V.D. Shiltsev “High energy particle colliders: past 20 years, next 20 years and beyond” 55 965–976 (2012)
29.20.−c, 29.20.Ej, 29.27.−a, 41.75.Jv, 52.27.Lw, 52.38.Kd (all)
A.V. Korzhimanov, A.A. Gonoskov et al “Horizons of petawatt laser technology” 54 9–28 (2011)
41.75.Jv, 42.55.−f, 42.62.Be, 42.65.Yj, 52.38.Kd, 52.38.Ph (all)
L.V. Kravchuk “Development of nuclear physics medicine at the Institute for Nuclear Research, RAS” 53 635–639 (2010)
29.20.−c, 42.62.−b, 87.56.−v (all)
V.S. Belyaev, V.P. Krainov et al “Generation of fast charged particles and superstrong magnetic fields in the interaction of ultrashort high-intensity laser pulses with solid targets” 51 793–814 (2008)
41.75.Jv, 52.38.−r, 79.20.Ds (all)
V.M. Byakov, S.V. Stepanov “The mechanism for the primary biological effects of ionizing radiation” 49 469–487 (2006)
82.39.−k, 87.50.−a, 87.50.Gi, 87.54.Br (all)
V.N. Bingi, A.V. Savin “Reply to A Yu Grosberg’s letter to the Physics-Uspekhi Editorial Board” 48 537–538 (2005)
87.50.−a
E.N. Ragozin, I.I. Sobel’man “Free-electron laser: advancement into the X-ray region” 47 195–196 (2004)
41.60.Cr, 41.75.Jv, 42.55.−f (all)
N.G. Ptitsyna, G. Villoresi et al “Natural and man-made low-frequency magnetic fields as a potential health hazard” 41 687–709 (1998)
87.40.+w, 87.50.−a
V.V. Tuchin “Light scattering study of tissues” 40 495–515 (1997)
42.66.−p, 87.56.−v, 87.80.+s (all)

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