MODEL OF MECHANISM OF BRAKING LASER RADIATION ABSORPTION
Abstract
Theoretical and experimental work was carried out on establishing the parameters of the plasma with a nanosecond
duration of the laser pulse and the condition of the existence of the developed gas-dynamic movement of the plasma. The
authors obtained a solution to the problem of describing the absorption of laser radiation in a dense layer of hot plasma. The
authors have established analytical dependencies that correspond quite well to real conditions and determine the geometric
and analytical thickness of the plasma. These results cooperate with the rigorous solution of the gas-dynamic equations for
the evaporation process in the "self-consistent" regime. In real conditions, when the radiation is focused, the strong lateral
expansion of the plasma leads to the quasi-spherical nature of the spread and the plasma density decreases much faster than
in the one-dimensional case. The authors compared the expressions for the internal energy and estimated the transition time
of a planar flow into a two-dimensional one. This made it possible to discover that both in the case of a planar flow and in the
case of a two-dimensional flow, the internal energy of the plasma grows according to similar laws.