Single-Parameter Scaling and Maximum Entropy inside Disordered One-Dimensional Systems: Theory and Experiment

Abstract

The single-parameter scaling hypothesis relating the average and variance of the logarithm of the conductance is a pillar of the theory of electronic transport. We use a maximum-entropy ansatz to explore the logarithm of the energy density, W(x), at a depth x into a random one-dimensional system. Single-parameter scaling would be the special case in which x=L (the system length). We find the result, confirmed in microwave measurements and computer simulations, that the average of W(x) is independent of L and equal to -x/, with the mean free path. At the beginning of the sample, var[ W(x)] rises linearly with x and is also independent of L, with a sublinear increase near the sample output. At x=L we find a correction to the value of var[ T] predicted by single-parameter scaling.