Standard
Quantum dots for single photon and photon pair technology. / Stevenson, R. Mark
; Young, Robert; Thompson, R. M. et al.
Quantum Computing in Solid State Systems. ed. / B. Ruggiero; P. Delsing ; C. Granata; Y. Pashkin; P. Silvestrini. New York: Springer, 2006. p. 288-297.
Research output: Contribution in Book/Report/Proceedings - With ISBN/ISSN › Chapter (peer-reviewed)
Harvard
Stevenson, RM
, Young, R, Thompson, RM, Yuan, Z, Kardynal, BE, Farrer, I, Ward, MB, Ritchie, DA & Shields, AJ 2006,
Quantum dots for single photon and photon pair technology. in B Ruggiero, P Delsing , C Granata, Y Pashkin & P Silvestrini (eds),
Quantum Computing in Solid State Systems. Springer, New York, pp. 288-297.
https://doi.org/10.1007/0-387-31143-2_35APA
Stevenson, R. M.
, Young, R., Thompson, R. M., Yuan, Z., Kardynal, B. E., Farrer, I., Ward, M. B., Ritchie, D. A., & Shields, A. J. (2006).
Quantum dots for single photon and photon pair technology. In B. Ruggiero, P. Delsing , C. Granata, Y. Pashkin, & P. Silvestrini (Eds.),
Quantum Computing in Solid State Systems (pp. 288-297). Springer.
https://doi.org/10.1007/0-387-31143-2_35Vancouver
Stevenson RM
, Young R, Thompson RM, Yuan Z, Kardynal BE, Farrer I et al.
Quantum dots for single photon and photon pair technology. In Ruggiero B, Delsing P, Granata C, Pashkin Y, Silvestrini P, editors, Quantum Computing in Solid State Systems. New York: Springer. 2006. p. 288-297 doi: 10.1007/0-387-31143-2_35
Author
Bibtex
@inbook{c366337e43694411a2d1f326f8b3f603,
title = "Quantum dots for single photon and photon pair technology",
abstract = "The excitation of a quantum dot from its ground state depends on the probabilistic nature of carrier capture, and thus radiative decay can occur via a multi photon cascade. It is also possible that non-radiative initial exciton states can be formed when the spins of the component electron and heavy hole have the same sign. Time integrated and time resolved micro-photoluminescence experiments are presented that reveal the broader properties of single photon and multi-photon emission from InAs quantum dots, including single photon emission, polarisation correlated photon emission, and dark state blocking, and their implications in terms of quantum information technology are discussed.",
author = "Stevenson, {R. Mark} and Robert Young and Thompson, {R. M.} and Zhillang Yuan and Kardynal, {B. E.} and I. Farrer and Ward, {M. B.} and Ritchie, {D. A.} and Shields, {A. J.}",
year = "2006",
doi = "10.1007/0-387-31143-2_35",
language = "English",
isbn = "978-0-387-26332-8",
pages = "288--297",
editor = "B. Ruggiero and {Delsing }, {P. } and C. Granata and Y. Pashkin and P. Silvestrini",
booktitle = "Quantum Computing in Solid State Systems",
publisher = "Springer",
}
RIS
TY - CHAP
T1 - Quantum dots for single photon and photon pair technology
AU - Stevenson, R. Mark
AU - Young, Robert
AU - Thompson, R. M.
AU - Yuan, Zhillang
AU - Kardynal, B. E.
AU - Farrer, I.
AU - Ward, M. B.
AU - Ritchie, D. A.
AU - Shields, A. J.
PY - 2006
Y1 - 2006
N2 - The excitation of a quantum dot from its ground state depends on the probabilistic nature of carrier capture, and thus radiative decay can occur via a multi photon cascade. It is also possible that non-radiative initial exciton states can be formed when the spins of the component electron and heavy hole have the same sign. Time integrated and time resolved micro-photoluminescence experiments are presented that reveal the broader properties of single photon and multi-photon emission from InAs quantum dots, including single photon emission, polarisation correlated photon emission, and dark state blocking, and their implications in terms of quantum information technology are discussed.
AB - The excitation of a quantum dot from its ground state depends on the probabilistic nature of carrier capture, and thus radiative decay can occur via a multi photon cascade. It is also possible that non-radiative initial exciton states can be formed when the spins of the component electron and heavy hole have the same sign. Time integrated and time resolved micro-photoluminescence experiments are presented that reveal the broader properties of single photon and multi-photon emission from InAs quantum dots, including single photon emission, polarisation correlated photon emission, and dark state blocking, and their implications in terms of quantum information technology are discussed.
U2 - 10.1007/0-387-31143-2_35
DO - 10.1007/0-387-31143-2_35
M3 - Chapter (peer-reviewed)
SN - 978-0-387-26332-8
SP - 288
EP - 297
BT - Quantum Computing in Solid State Systems
A2 - Ruggiero, B.
A2 - Delsing , P.
A2 - Granata, C.
A2 - Pashkin, Y.
A2 - Silvestrini, P.
PB - Springer
CY - New York
ER -
