Direct determination of the transition to localization of light in three dimensions

TL;DR

This paper provides direct experimental evidence of the transition to Anderson localization of light in three dimensions by measuring the time-dependent transverse width of transmitted waves, effectively distinguishing localization from absorption effects.

Contribution

It introduces a novel measurement method that directly determines the localization length of light in 3D media, confirming the existence of a localization transition.

Findings

Evidence of a localization transition in 3D light transport

Measurement of localization lengths in three dimensions

Method distinguishes localization effects from absorption

Abstract

In the diffusive transport of waves in three dimensional media, there should be a phase transition with increasing disorder to a state where no transport occurs. This transition was first discussed by Anderson in 1958 in the context of the metal insulator transition, but as was realized later it is generic for all waves . However, the quest for the experimental demonstration of "Anderson" or "strong" localization of waves in 3D has been a challenging task. For electrons and cold atoms, the challenge lies in the possibility of bound states in a disordered potential well. Therefore, electromagnetic and acoustic waves have been the prime candidates for the observation of Anderson localization. The main challenge using light lies in the distinction between effects of absorption and localization. Here we present measurements of the time-dependence of the transverse width of the intensity distribution of the transmitted waves, which provides a direct measure of the localization length and is independent of absorption. From this we find direct evidence for a localization transition in three dimensions and determine the corresponding localization lengths.