Solitons are generated by injecting energy provided
by high power laser devices into a quiescent ICF plasma.
The data obtained by laser fusion show a change
δne in electronic density
profile focused by ponderomotive force of laser radiation
near the critical layer where wp
= w0, wp
being the plasma frequency and w0 the
laser frequency. This change that has a structure of soliton
type, becomes as a solution of a nonlinear Schrödinger
equation (NLS), solved as an inverse problem by means of the
inverse scattering transform with one eigenvalue invariant
in time, and representative of wave eigenvector. Electrical
currents are given in function of the above mentioned change
in the density profile of electrons and an average velocity
of such electrons corresponding to a nonmaxwellian electronic
velocity distribution. The z component of heat
flow is a consequence of electrical currents generated,
the generalized electrical field to classical transport,
and the generalized expression of vectorial heat flow developed
by Haines.