Wave-particle duality in multi-path interferometers: General concepts and three-path interferometers

Abstract

For two-path interferometers, the which-path predictability P and the fringe visibility V are familiar quantities that are much used to talk about wave-particle duality in a quantitative way. We discuss several candidates that suggest themselves as generalizations P of mathcalP for multi-path interferometers, and treat the case of three paths in considerable detail. To each choice for the path knowledge P, the interference strength V -- the corresponding generalization of V -- is found by a natural, operational procedure. In experimental terms it amounts to finding those equal-weight superpositions of the path amplitudes which maximize P for the emerging intensities. Mathematically speaking, one needs to identify a certain optimal one among the Fourier transforms of the state of the interfering quantum object. Wave-particle duality is manifest, inasmuch as P=1 implies V=0 and V=1 implies P=0, whatever definition is chosen. The possible values of the pair (P,V) are restricted to an area with corners at (P,V)=(0,0), (P,V)=(1,0), and (P,V)=(0,1), with the shape of the border line from (1,0) to (0,1) depending on the particular choice for P and the induced definition of V.