Spatial adiabatic passage as a quantum wire

Author

Greentree, Andrew D. ; Jong, Lenneke M. ; Van Donkelaar, Jessica A. ; Devitt, Simon J. ; Cole, Jared H. ; Stephens, Ashley M. ; Jamieson, David N. ; Hollenberg, Lloyd C L

Author_Institution

Centre for Quantum Comput. Technol., Melbourne Univ., Melbourne, VIC

fYear

2008

fDate

25-29 Feb. 2008

Firstpage

156

Lastpage

159

Abstract

Qubit transport has been identified as vital in improving quantum error correction thresholds in scalable quantum computer architectures. Introducing practical transport in the solid-state is problematic, but in phosphorus in silicon implementations we have shown an interesting adiabatic protocol for qubit transfer, coherent tunneling adiabatic passage (CTAP). Here we review the role of CTAP as a quantum wire, highlighting the protocol and the temporal scaling as the length of the transport chain is increased. We also highlight an extension of CTAP to generate spatial superposition states which demonstrates some of the flexibility of quantum electronic structures over quantum optical systems.

Keywords

elemental semiconductors; error correction; phosphorus; quantum computing; semiconductor quantum wires; silicon; tunnelling; Si:P; coherent tunneling adiabatic passage; quantum computer architectures; quantum computing; quantum electronic structures; quantum error correction; quantum wire; qubit transport; spatial adiabatic passage; Computer architecture; Error correction; Physics; Quantum computing; Quantum entanglement; Silicon; Solid state circuits; Transport protocols; Tunneling; Wire; Adiabatic Passage; phosphorus in silicon quantum computers; quantum computing;

fLanguage

English

Publisher

ieee

Conference_Titel

Nanoscience and Nanotechnology, 2008. ICONN 2008. International Conference on

Conference_Location

Melbourne, Vic.

Print_ISBN

978-1-4244-1503-8

Electronic_ISBN

978-1-4244-1504-5

Type

conf

DOI

10.1109/ICONN.2008.4639270

Filename

4639270