Hybrid diamond-silicon carbide structures incorporating silicon-vacancies in diamond as quantum emitters

Author

Zhang, Jingyuan Linda ; Ishiwata, Hitoshi ; Radulaski, Marina ; Babinec, Thomas M. ; Muller, Kai ; Lagoudakis, Konstantinos G. ; Edgington, Robert ; Alassaad, Kassem ; Ferro, Gabriel ; Melosh, Nicholas A. ; Zhi-Xun Shen ; Vuckovic, Jelena

Author_Institution

E.L. Ginzton Lab., Stanford Univ., Stanford, CA, USA

fYear

2015

fDate

10-15 May 2015

Firstpage

1

Lastpage

2

Abstract

We demonstrate a novel materials technique for generating several hybrid solid state nano- and micro-photonic devices. Our approach combines the growth of nanoscale (~100 nm) and micron scale (~2 μm) diamonds on silicon carbide (3C and 4H polytype) substrate via chemical vapor deposition (CVD) from molecular diamond (`diamondoid´) seed with the use of these particles as a hard mask for pattern transfer into the substrate. Both diamond and silicon carbide are well known to possess optically active spins for applications in quantum information processing, metrology and sensing. In our case, diamond silicon vacancy centers are generated via plasma-assisted diffusion from the silicon carbide substrate.

Keywords

diamond; masks; micro-optics; microfabrication; nanofabrication; nanophotonics; optical design techniques; optical fabrication; optical materials; plasma CVD; quantum optics; silicon compounds; C-SiC; chemical vapor deposition; hybrid diamond-silicon carbide structures; hybrid solid state microphotonic devices; hybrid solid state nanophotonic devices; mask; plasma-assisted diffusion; quantum emitters; quantum information processing applications; quantum metrology applications; quantum sensing applications; Biomedical optical imaging; Diamonds; Nanoscale devices; Optical device fabrication; Silicon; Silicon carbide; Substrates;

fLanguage

English

Publisher

ieee

Conference_Titel

Lasers and Electro-Optics (CLEO), 2015 Conference on

Conference_Location

San Jose, CA

Type

conf

Filename

7183793