Single- and Twin-Photons Emitted from Fiber-Coupled Quantum Dots in a Distributed Bragg Reflector Cavity

In this work, we develop single-mode fiber devices of an InAs/GaAs quantum dot (QD) by bonding a fiber array with large smooth facet, small core, and small numerical aperture to QDs in a distributed Bragg reflector planar cavity with vertical light extraction that prove mode overlap and efficient output for plug-and-play stable use and extensive study. Modulated Si doping as electron reservoir builds electric field and level tunnel coupling to reduce fine-structure splitting (FSS) and populate dominant XX and higher excitons XX(+) and XXX. Epoxy package thermal stress induces light hole (lh) with various behaviors related to the donor field: lh h(1) confined with more anisotropy shows an additional X(Z) line (its space to the traditional X lines reflects the field intensity) and larger FSS; lh h(2) delocalized to wetting layer shows a fast h(2)–h(1) decay; lh h(2) confined shows D(3h) symmetric higher excitons with slow h(2)–h(1) decay and more confined h(1) to raise h(1)–h(1) Coulomb interaction.