Fig. 1. Schematic illustration of the formation of a strong self-consistent potential, accelerating ions to multi-MeV energies toward the center of the shell, heated by symmetrical irradiation with short intense laser pulses. The thicknesses of the shell and Debye layer are denoted by Δ and L_D, respectively.

Fig. 2. Irradiation scheme and early-time results of 2D PIC simulations for the implosion of a thin plastic shell according to the bold row in Table I. (a) Irradiation scheme showing the laser pulses by the absolute value of the electric field. (b) Initial electron density. (c) Absolute value of the electric field at 0.5 ps. (d) and (e) Electron effective temperature at 0.13 and 0.2 ps, respectively. (f) Ion kinetic energy at 0.2 ps. (g) and (h) Electron and ion densities, respectively, at 0.5 ps. (i) Ion effective temperature at 0.5 ps. Note that the square-fold symmetry evident in (d), (f), and (i) is the result of the fourfold radiation geometry, shown in (a).

Fig. 3. Results of 2D PIC simulations of the implosion following irradiation of a thin plastic shell according to the bold row in Table I. (a), (d), (g), and (j) Electron density at times 1, 2, 4, and 5.8 ps, respectively. (b), (e), (h), and (k) Ion density at times 1, 2, 4, and 5.8 ps, respectively. (c), (f), (j), and (l) Effective ion temperature at times 1, 2, 4, and 5.8 ps respectively. The fourfold symmetry evident in (c), (f), (i), and (l) is a consequence of the fourfold irradiation scheme, shown in Fig. 2(a).

Fig. 4. Proton energies just before collision [(a)–(c)] and effective temperatures just after collision [(d)–(f)] for the three cases in Table I: the first italicized row, with I_L = 10¹⁹ W cm⁻² [(a) and (d)]; the bold row, with I_L = 10²⁰ W cm⁻² [(b) and (e)]; and the second italicized row, with I_L = 10²¹ W cm⁻² [(c) and (f)]. After the collision, the energy is transformed to the effective temperature with approximately the same value.