Abstract
Interference patterns provide direct measurement of coherent propagation of matter waves in quantum systems. Superfluidity in Bose–Einstein condensates of excitons can enable long-range ballistic exciton propagation and can lead to emerging long-scale interference patterns. Indirect excitons (IXs) are formed by electrons and holes in separated layers. The theory predicts that the reduced IX recombination enables IX superfluid propagation over macroscopic distances. Here, we present dislocation-like phase singularities in interference patterns produced by condensate of IXs. We analyze how exciton vortices and skyrmions should appear in the interference experiments and show that the observed interference dislocations are not associated with these phase defects. We show that the observed interference dislocations originate from the moiré effect in combined interference patterns of propagating condensate matter waves. The interference dislocations are formed by the IX matter waves ballistically propagating over macroscopic distances. The long-range ballistic IX propagation is the evidence for IX condensate superfluidity.
Highlights
Interference patterns provide direct measurement of coherent propagation of matter waves in quantum systems
We present the origin of these singularities in condensate interference patterns: The observed interference dislocations originate from the moiré effect in the combined interference patterns of ballistically propagating condensate matter waves
A cold gas of Indirect excitons (IXs) is realized in regions of external ring and localized bright spot (LBS) rings in IX emission
Summary
Interference patterns provide direct measurement of coherent propagation of matter waves in quantum systems. These two images are shifted relative to each other in x-direction so that the measured interference pattern is produced by the interference between the emission of IXs separated by the shift δx in CQW plane.
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