Generation of "triggered single photons" from a coherently-pumped quantum dot

Abstract

A deterministic "on demand" source of single photons is a basic building block for linear quantum computation linear, quantum cryptography crypto, quantum teleportation teleport, and quantum networks network. In all these applications, quantum interference between two single-photon pulses on a symmetric beam splitter has been exploited review, which imposes stringent requirement for the implemented single photons to be indistinguishable in all degrees of freedom, including their frequencies, spectral widths, pulse shapes, and polarizations. To generate single photons one requires a pumping mechanism to excite a "two-level emitter" and an efficient channeling of the subsequently emitted photons. The efficiency of the source can be enhanced by coupling the emitter to the waveguide manga or a microcavity mode cklaw. However, hitherto the solid-state single photon sources realized by using a quantum dot coupled with a microcavity rely on incoherent pumping of excitons, which leads to problems with timing jitter kiraz, leading to a trade off between efficiency and indistinguishability. Here we introduce a means to realize a highly efficient solid state source of indistinguishable single photons using cavity-assisted adiabatic Raman passage in a single quantum dot - cavity system. We demonstrate pulse-triggered single photons with 100% efficiency and >90% indistinguishability using currently available experimental parameters.