Abstract

An experimental and theoretical study of nonlinear acoustic propagation in a typical glass, fused silica, is presented, at frequencies near 1 GHz and temperatures below 1 K. The data are interpreted within a general framework of pulse propagation in an inhomogeneously broadened two-level absorber. Numerical solutions are compared with the temperature and pulse-width dependence of the critical saturation intensity, as well as with saturation recovery experiments. The data are described by a linewidth ${T}_{2}^{\ensuremath{-}1}$ of the intrinsic tunneling states that agrees with lifetimes obtained from phonon echo experiments. The distribution of relaxation times ${T}_{1}$ which emerges from the analysis of saturation recovery experiments is also understandable within the tunneling model. An improved estimate for the longitudinal deformation potential is ${\ensuremath{\gamma}}_{L}=2.0$ eV. For $T<0.1$ K, the behavior of the pulse velocity is indicative of a coherent propagating mode, i.e., self-induced transparency.