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 177 Lu ” 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 )