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Simulating the emission properties of luminescent dyes within one-dimensional uniaxial liquid crystal microcavities

Lieven Penninck UGent, Patrick De Visschere UGent, Jeroen Beeckman UGent and Kristiaan Neyts UGent (2012) MOLECULAR CRYSTALS AND LIQUID CRYSTALS. 560(SI). p.82-92
abstract
We have developed a simulation method which is capable of simulating the emissive properties of luminescent dyes inside uniaxial anistropic thin film microcavities[1]. The method uses plane wave decomposition of the electric field of a dipole antenna in a uniaxial medium and a scattering matrix formalism to account for interference and reflection from the various interfaces in the device. We apply this method to simulate the excitation of waveguide modes in a slab waveguide formed by reorientation of a liquid crystal. We investigate the emission both outside the device and into waveguided modes inside the liquid crystal device.
Please use this url to cite or link to this publication:
author
organization
year
type
journalArticle (original)
publication status
published
subject
keyword
liquid crystals, thin films, fluorescence, waveguides, Plane waves, MEDIA, RADIATION, THIN-LAYERS, LIGHT-EMISSION
journal title
MOLECULAR CRYSTALS AND LIQUID CRYSTALS
Mol. Cryst. Liquid Cryst.
volume
560
issue
SI
pages
82 - 92
Web of Science type
Article
Web of Science id
000304278300010
JCR category
CRYSTALLOGRAPHY
JCR impact factor
0.53 (2012)
JCR rank
18/23 (2012)
JCR quartile
4 (2012)
ISSN
1542-1406
DOI
10.1080/15421406.2012.663181
project
Center for nano- and biophotonics (NB-Photonics)
language
English
UGent publication?
yes
classification
A1
copyright statement
I have transferred the copyright for this publication to the publisher
id
3030264
handle
http://hdl.handle.net/1854/LU-3030264
date created
2012-10-17 10:52:14
date last changed
2014-05-26 09:46:33
@article{3030264,
  abstract     = {We have developed a simulation method which is capable of simulating the emissive properties of luminescent dyes inside uniaxial anistropic thin film microcavities[1]. The method uses plane wave decomposition of the electric field of a dipole antenna in a uniaxial medium and a scattering matrix formalism to account for interference and reflection from the various interfaces in the device. We apply this method to simulate the excitation of waveguide modes in a slab waveguide formed by reorientation of a liquid crystal. We investigate the emission both outside the device and into waveguided modes inside the liquid crystal device.},
  author       = {Penninck, Lieven and De Visschere, Patrick and Beeckman, Jeroen and Neyts, Kristiaan},
  issn         = {1542-1406},
  journal      = {MOLECULAR CRYSTALS AND LIQUID CRYSTALS},
  keyword      = {liquid crystals,thin films,fluorescence,waveguides,Plane waves,MEDIA,RADIATION,THIN-LAYERS,LIGHT-EMISSION},
  language     = {eng},
  number       = {SI},
  pages        = {82--92},
  title        = {Simulating the emission properties of luminescent dyes within one-dimensional uniaxial liquid crystal microcavities},
  url          = {http://dx.doi.org/10.1080/15421406.2012.663181},
  volume       = {560},
  year         = {2012},
}

Chicago
Penninck, Lieven, Patrick De Visschere, Jeroen Beeckman, and Kristiaan Neyts. 2012. “Simulating the Emission Properties of Luminescent Dyes Within One-dimensional Uniaxial Liquid Crystal Microcavities.” Molecular Crystals and Liquid Crystals 560 (SI): 82–92.
APA
Penninck, L., De Visschere, P., Beeckman, J., & Neyts, K. (2012). Simulating the emission properties of luminescent dyes within one-dimensional uniaxial liquid crystal microcavities. MOLECULAR CRYSTALS AND LIQUID CRYSTALS, 560(SI), 82–92.
Vancouver
1.
Penninck L, De Visschere P, Beeckman J, Neyts K. Simulating the emission properties of luminescent dyes within one-dimensional uniaxial liquid crystal microcavities. MOLECULAR CRYSTALS AND LIQUID CRYSTALS. 2012;560(SI):82–92.
MLA
Penninck, Lieven, Patrick De Visschere, Jeroen Beeckman, et al. “Simulating the Emission Properties of Luminescent Dyes Within One-dimensional Uniaxial Liquid Crystal Microcavities.” MOLECULAR CRYSTALS AND LIQUID CRYSTALS 560.SI (2012): 82–92. Print.