Open microcavities represent a versatile cavity design that allows the external control of internal properties such as cavity thickness and mode detuning without changing the key parameters of the cavity itself, rendering them particularly interesting for light–matter interaction experiments. Here, we demonstrate the tunability of an open microcavity with an embedded active organic layer providing parallel alignment of molecular transition dipole moments as well as strong self-absorption inside the cavity. By decreasing the cavity thickness, we observe a transition from the weak coupling regime into the strong coupling regime evidenced by the onset of avoided crossing behavior between involved modes. This change of coupling mechanism is shown for 2D (planar) as well as 0D (hemispherical) cavities.
%0 Journal Article
%1 Betzold_2017
%A Betzold, Simon
%A Herbst, Stefanie
%A Trichet, Aurelien A. P.
%A Smith, Jason M.
%A Würthner, Frank
%A Höfling, Sven
%A Dietrich, Christof P.
%D 2018
%I American Chemical Society (ACS)
%J ACS Photonics
%K exciton−polaritons microcavity myown open organic semiconductors
%N 1
%P 90--94
%R 10.1021/acsphotonics.7b00552
%T Tunable Light-Matter Hybridization in Open Organic Microcavities
%U https://doi.org/10.1021%2Facsphotonics.7b00552
%V 5
%X Open microcavities represent a versatile cavity design that allows the external control of internal properties such as cavity thickness and mode detuning without changing the key parameters of the cavity itself, rendering them particularly interesting for light–matter interaction experiments. Here, we demonstrate the tunability of an open microcavity with an embedded active organic layer providing parallel alignment of molecular transition dipole moments as well as strong self-absorption inside the cavity. By decreasing the cavity thickness, we observe a transition from the weak coupling regime into the strong coupling regime evidenced by the onset of avoided crossing behavior between involved modes. This change of coupling mechanism is shown for 2D (planar) as well as 0D (hemispherical) cavities.
@article{Betzold_2017,
abstract = {Open microcavities represent a versatile cavity design that allows the external control of internal properties such as cavity thickness and mode detuning without changing the key parameters of the cavity itself, rendering them particularly interesting for light–matter interaction experiments. Here, we demonstrate the tunability of an open microcavity with an embedded active organic layer providing parallel alignment of molecular transition dipole moments as well as strong self-absorption inside the cavity. By decreasing the cavity thickness, we observe a transition from the weak coupling regime into the strong coupling regime evidenced by the onset of avoided crossing behavior between involved modes. This change of coupling mechanism is shown for 2D (planar) as well as 0D (hemispherical) cavities.},
added-at = {2018-01-26T12:11:27.000+0100},
author = {Betzold, Simon and Herbst, Stefanie and Trichet, Aurelien A. P. and Smith, Jason M. and Würthner, Frank and Höfling, Sven and Dietrich, Christof P.},
biburl = {https://www.bibsonomy.org/bibtex/2306a1073144f9bc55f9a1e01c92dc654/wuerthner_group},
doi = {10.1021/acsphotonics.7b00552},
interhash = {f28ee43bdb29de104796a7e162eb84f7},
intrahash = {306a1073144f9bc55f9a1e01c92dc654},
journal = {ACS Photonics},
keywords = {exciton−polaritons microcavity myown open organic semiconductors},
month = jan,
number = 1,
pages = {90--94},
publisher = {American Chemical Society (ACS)},
timestamp = {2019-03-11T13:30:32.000+0100},
title = {Tunable Light-Matter Hybridization in Open Organic Microcavities},
url = {https://doi.org/10.1021%2Facsphotonics.7b00552},
volume = 5,
year = 2018
}