Title :
Scalable routes to single and entangled photon pair sources: Site-controlled InAs/InP quantum dots in photonic crystal microcavities
Author :
Dalacu, D. ; Mnaymneh, K. ; Frederick, S. ; Lapointe, J. ; Poole, P.J. ; Aers, G. ; Cheriton, R. ; Williams, R.L.
Author_Institution :
Inst. for Microstruct. Sci., Nat. Res. Council of Canada, Ottawa, ON, Canada
Abstract :
Self-assembled semiconductor quantum dots show great potential as efficient semiconductor-based non-classical light sources. However, due to the very nature of the self-assembled growth process, the characteristics of individual dots can vary widely and their spatial location is generally uncontrolled. Using a directed self-assembly process, the nucleation site of single quantum dots are designed through lithography. The site-control is used to facilitate the spatial alignment of single quantum dots to high finesse optical microcavities. The single dot-cavity device is a unique system to study the dot-cavity coupling where the presence of background emitters can be unambiguously ruled out.
Keywords :
III-V semiconductors; electron beam lithography; indium compounds; integrated optics; micro-optics; microcavities; nucleation; photonic crystals; quantum entanglement; self-assembly; semiconductor quantum dots; InAs-InP; background emitters; dot-cavity coupling; entangled photon pair; lithography; nucleation site; photonic crystal microcavities; self-assembled semiconductor quantum dots; self-assembly growth process; semiconductor-based non-classical light sources; single dot-cavity device; single photon pair; site-controlled quantum dots; spatial alignment; Cavity resonators; Indium phosphide; Optical fibers; Photonic crystals; Quantum dots; Self-assembly;
Conference_Titel :
Information Photonics (IP), 2011 ICO International Conference on
Conference_Location :
Ottawa, ON
Print_ISBN :
978-1-61284-315-5
DOI :
10.1109/ICO-IP.2011.5953726
