Abstract

The feature of normal modes in one-dimensional isotopically disordered harmonic chain is investigated. It is proved for any frequency that the simultaneous difference equations for the displacement Un of the n-th atom, (-oo<n< oo), has a solution in which un grows exponentially with n with probability 1. In the low frequency limit the rate of exponential growth "' is explicitly calculated. A necessary and sufficient condition is obtained for there to exist a localized solution such that lim un=O. It n~oe~ is proved that any infinite disordered chain, except those with measure 0, can be made to have an exponentially localized solution for any til by modifying the mass of one atom mo to a suitable real value as a function of til. From this it does not logically follow that almost all normal modes of any given large but finite sample chain are localized in such a way as occurred in the above modified infinite chain. However, the theoretical estimate of the nature of normal modes and energy transport based on the above mentioned value of "/, agrees well with the result of computer experiments. As a by-product of our investigation, the exact expression of the thermal conductivity due to the Kubo formula for the isotopically disordered harmonic chain is obtained in a closed form.