Flexible inverted top-illuminated polymer solar cells (IT-PSCs) are fabricated by wetting of polyelectrolyte and designing a microcavity structure by laying an indium-tin-oxide (ITO) interlayer on top of an Ag reflector. The ITO-coated Ag makes the surface hydrophilic, thereby improving wettability of polyethyleneimine (PEIE). This increased wettability of PEIE yields a reflective cathode with low work function of 3.73 eV. The ITO layer also tunes the light absorption spectrum in the active layer. Finite-domain time-difference simulation provides evidence that the ITO layer played a role in both the shift in resonant wavelength in the microcavity and confinement of the electric field to the active layer. Time-dependent simulation suggests that the time to reach steady-state light absorption is longer (6.6 fs) when a microcavity is present than when it is not present (3.8 fs); i.e., the microcavity increases light absorption in the active layer. The designed IT-PSCs show a maximum photo-conversion efficiency of 6.4% on plastic film and 6.1% on opaque copper foil; these are the highest values obtained by top-illuminated PSCs on a metallic substrate. The IT-PSCs have excellent mechanical flexibility and more stable in air than conventional normal structured devices.
Description
Dual Effect of ITO-Interlayer on Inverted Top-Illuminated Polymer Solar Cells: Wetting of Polyelectrolyte and Tuning of Cavity - Dong - 2016 - Advanced Functional Materials - Wiley Online Library
%0 Journal Article
%1 ADFM:ADFM201601764
%A Dong, Wan Jae
%A Park, Jae Yong
%A Ham, Juyoung
%A Jung, Gwan Ho
%A Lee, Illhwan
%A Lee, Jong-Lam
%D 2016
%J Advanced Functional Materials
%K Inverted Organic Polymer
%P n/a--n/a
%R 10.1002/adfm.201601764
%T Dual Effect of ITO-Interlayer on Inverted Top-Illuminated Polymer Solar Cells: Wetting of Polyelectrolyte and Tuning of Cavity
%U http://dx.doi.org/10.1002/adfm.201601764
%X Flexible inverted top-illuminated polymer solar cells (IT-PSCs) are fabricated by wetting of polyelectrolyte and designing a microcavity structure by laying an indium-tin-oxide (ITO) interlayer on top of an Ag reflector. The ITO-coated Ag makes the surface hydrophilic, thereby improving wettability of polyethyleneimine (PEIE). This increased wettability of PEIE yields a reflective cathode with low work function of 3.73 eV. The ITO layer also tunes the light absorption spectrum in the active layer. Finite-domain time-difference simulation provides evidence that the ITO layer played a role in both the shift in resonant wavelength in the microcavity and confinement of the electric field to the active layer. Time-dependent simulation suggests that the time to reach steady-state light absorption is longer (6.6 fs) when a microcavity is present than when it is not present (3.8 fs); i.e., the microcavity increases light absorption in the active layer. The designed IT-PSCs show a maximum photo-conversion efficiency of 6.4% on plastic film and 6.1% on opaque copper foil; these are the highest values obtained by top-illuminated PSCs on a metallic substrate. The IT-PSCs have excellent mechanical flexibility and more stable in air than conventional normal structured devices.
@article{ADFM:ADFM201601764,
abstract = {Flexible inverted top-illuminated polymer solar cells (IT-PSCs) are fabricated by wetting of polyelectrolyte and designing a microcavity structure by laying an indium-tin-oxide (ITO) interlayer on top of an Ag reflector. The ITO-coated Ag makes the surface hydrophilic, thereby improving wettability of polyethyleneimine (PEIE). This increased wettability of PEIE yields a reflective cathode with low work function of 3.73 eV. The ITO layer also tunes the light absorption spectrum in the active layer. Finite-domain time-difference simulation provides evidence that the ITO layer played a role in both the shift in resonant wavelength in the microcavity and confinement of the electric field to the active layer. Time-dependent simulation suggests that the time to reach steady-state light absorption is longer (6.6 fs) when a microcavity is present than when it is not present (3.8 fs); i.e., the microcavity increases light absorption in the active layer. The designed IT-PSCs show a maximum photo-conversion efficiency of 6.4% on plastic film and 6.1% on opaque copper foil; these are the highest values obtained by top-illuminated PSCs on a metallic substrate. The IT-PSCs have excellent mechanical flexibility and more stable in air than conventional normal structured devices.},
added-at = {2016-06-07T16:34:39.000+0200},
author = {Dong, Wan Jae and Park, Jae Yong and Ham, Juyoung and Jung, Gwan Ho and Lee, Illhwan and Lee, Jong-Lam},
biburl = {https://www.bibsonomy.org/bibtex/200bc055096e1ae7b43ebb222afb4b503/bretschneider_m},
description = {Dual Effect of ITO-Interlayer on Inverted Top-Illuminated Polymer Solar Cells: Wetting of Polyelectrolyte and Tuning of Cavity - Dong - 2016 - Advanced Functional Materials - Wiley Online Library},
doi = {10.1002/adfm.201601764},
interhash = {565b66c0b36c4f74cb8854f5966483ca},
intrahash = {00bc055096e1ae7b43ebb222afb4b503},
issn = {1616-3028},
journal = {Advanced Functional Materials},
keywords = {Inverted Organic Polymer},
pages = {n/a--n/a},
timestamp = {2016-06-07T16:34:39.000+0200},
title = {Dual Effect of ITO-Interlayer on Inverted Top-Illuminated Polymer Solar Cells: Wetting of Polyelectrolyte and Tuning of Cavity},
url = {http://dx.doi.org/10.1002/adfm.201601764},
year = 2016
}