Title :
Polariton lattices for quantum simulation
Author_Institution :
Lab. de Photonique et Nanostruct., Marcoussis, France
Abstract :
Coupled micropillars etched in semiconductor microcavities are an excellent platform to engineer the properties of exciton-polaritons. Thanks to the direct optical access characteristic of polaritons, these etched structures can be used to simulate various solid-state hamiltonians. Here we will show a hexagonal structure in which we engineer a spin-orbit coupling for polaritons. The coupling is evidenced via the spontaneous formation of polarization vortices when polaritons condense. When extended to a honeycomb lattice we report the direct observation of Dirac cones and a non-dispersive band, i.e., a flatband. Our structure is thus very promising for the study of anomalous transport and disorder in massless particles, and the strongly correlated phases expected in flatbands.
Keywords :
excitons; microcavities; polaritons; Dirac cones; anomalous transport property; coupled micropillars; direct optical access characteristics; etched structure; exciton-polariton; hexagonal structure; honeycomb lattice; massless particle; nondispersive band; polariton lattice; polarization vortices; quantum simulation; semiconductor microcavities; solid-state hamiltonian model; spin-orbit coupling; strongly correlated phase; Couplings; Lattices; Microcavities; Optical coupling; Optical polarization; Optical vortices; Photonics;
Conference_Titel :
Lasers and Electro-Optics (CLEO), 2014 Conference on
Conference_Location :
San Jose, CA
