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[14] G. Maynard, W. Andre, M. Chabot, C. Deutsch, C. Fleurier, et al., Charge evolution of swift heavy ions in fusion plasmas, Nuo. Cim. 106A (1993) 1825-1993.

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[18] G. Maynard, C. Deutsch, P. Fromy, K. Katsonis, Atomic physics for inertial fusion using average correlated hydrogenic atom model, Laser Part. Beams 13 (1995) 271-279.

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[21] M.H. Chen, Relativistic intermediate-coupling calculations of dielectronic-recombination coefficients for the Li isoelectronic sequence, Phys. Rev. A44 (1991) 4215-4223.

[22] Th Peter, R. Arnold, J. Meyer-Ter-Vehn, Private Communication, 1985.

[23] C.L. Pekeris, 11S and 23S states of helium, Phys. Rev. 115 (1959) 1216-1221.

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[29] X. Garbet, C. Deutsch, G. Maynard, Mean excitation energies for ions in gases and plasmas, J. Appl. Phys. 61 (1987) 907-916.

[30] J.H. Peek, L.C. Pitchford, E.J. Shipsey,Methods for predicting stopping and straggling mean excitation energies, Phys. Rev. A29 (1984) 1096-1102.

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[32] B.F. Rozsnayi, Relativistic Hartree-Fock-Slater calculations for arbitrary temperature and matter density, Phys. Rev. A5 (1972) 1137-1149.

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[35] R.E. Johnson, M. Inokuti, The local plasma approximation to the oscillation strength spectrum: How good is it and why Comm. At. Mol. Phys. 14 (1983) 19-31.

[36] T.A. Mehlhorn, A finite material temperature model for ion energy deposition in ion-driven inertial confinement fusion targets, J. Appl. Phys. 52 (1981) 65226532.

[37] C. Deutsch, G. Maynard, H. Minoo, Ion stopping in dense plasmas, Las. Int. Rel. Plasma P. H. 6 (1984) 1029e1048; C. Deutsch, Inertial confinement fusion driven by intense ion Beams, Ann. Phys. Fr. 11 (1986) 1-111.

[38] F.I. McGuire, J.M. Peek, C.L. Pitchford, Proton stopping power of aluminium ions, Phys. Rev. A26 (1982) 1318-1325.

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[41] G. Maynard, C. Deutsch, The Barkas effect or Z3P -contributions to stopping of swift charged particles, J. Phys. (Paris) 43 L (1982) 223-227.

[42] J.D. Jackson, R.L. McCarthy, Z3P connection to energy loss and range, Phys. Rev. B6 (1972) 4131-4141; J.C. Ashley, R.H. Ritchie, W. Brandt, Z3P effect is stopping power of matter for charged particles, Phys. Rev. B5 (1972), 2393-2347; K.W. Hill, E. Merzbacher, Z3P effect in stopping power of matter for charged particles, Phys. Rev. A9 (1974) 156-165.

[43] C. Deutsch, S. Klarsfeld, Quadrupole electron broadening of neutral lines in a plasma, Phys. Rev. A7 (1973) 2081-2086.

[44] J. Lindhard, The Barkas effect or Z3P Z4P corrections to stopping of swift charged, Nucl. Instr. Meth. 132 (1976) 1-5.

[45] J. Lindhard, M. Scharff, H.E. Schioett, Range concepts and heavy ion ranges. Notes on atomic collisions II, Kgl. Dan. Vidensk. Selbsh. Mat. Fys. Medd. 33 (39) (1963) 1-42.

[46] X. Garbet, Charged Particle Stopping by Bound Electrons in a Plasma, Report L.P. N vol. 209, Universit e Paris XI, Orsay, 1984.

[47] H.H. Andersen, J.F. Ziegler, Stopping and Ranges of Ions in Matter, Pergamon, New-York, 1977.

[48] B. Tashev, F. Baimbetov, C. Deutsch, P. Fromy, Low velocity ion stopping in binary mixtures, Phys. Plasmas 15 (102701) (2008) 1-10.

[49] See for instance A. Ortner, A. Franck, A. Blazevic, M. Roth, Role of charge transfer in heavy-ion-beam-plasma interactions at intermediate energies, Phys. Rev. E91 (23104) (2015) 1-7.

[50] C. Deutsch, R. Popoff, Low ion-velocity slowing down in a strongly magnatized plasma target, Phys. Rev. E78 (56405) (2008) 1-8.

[51] C. Deutsch, N.A. Tahir, Fragmentation and stopping of heavy cluster ions in a lithium target-Application to target implosion, Phys. Fluids B4 (1992) 3735-3746; N.A. Tahir, H.J. Lutz, O. Geb, J.A. Maruhn, C. Deutsch, et al., Inertial confinement fusion using hohlramm radiation generated by heavy ion cluster, Phys. Plasmas 4 (3) (1997) 796-816.

[52] Z. Wang, Bin He, Z.G. Fu, P. Zhang, Energy relaxation of multi-MeV protons travelling in compressed DT t Be plasmas, Phys. Plasmas 21 (72703) (2014) 1-4.

[53] H.B. Nersisyan, C. Deutsch, Stopping of ions in a plasma irradiated by an intense laser field, Laser Part. Beams 29 (2011) 389-397.

[54] B. Yu Sharkov, D.H.H. Hoffmann, A.A. Golubev, Y.T. Zhao, High energy density physics with intense ion beams, Matter Radiat. Extrem. 1 (2016) 28-47.

[55] J.A. Frenje, P.E. Grabowski, C.K. Li, F.H. Seguin, A.B. Zylstra, et al., Measurements of ion stopping around the Bragg peak in high-energydensity plasmas, Phys. Rev. Lett 115 (2015) 205001-205005.

[56] A.B. Zylstra, J.A. Frenje, P.E. Grabowski, C.K. Li, G.W. Collins, et al., Measurement of charged-particle stopping in warm dense plasma, Phys. Rev. Lett 114 (2015) 215002-215006.

[57] G. Maynard, C. Deutsch, Energy loss and straggling at any velocity of swift ions in dense matter, Phys. Rev. A26 (1982) 665e668; Born RPA approximation for ion stopping in arbitrary degenerate electron fluid, J. de Physique 46 (1985) 1113-1123.

[58] S.N. Chen, C. Deutsch, S. Atzeni, M. Gauthier, J. Fuchs, EPS e 2015 Lisboa and to be published.