On the exciton blocking layer at the interface organic/cathode in planar multiheterojunction organic solar cells

On the exciton blocking layer at the interface organic/cathode in planar multiheterojunction organic solar cells

•Use of ROETOM as new exciton buffer layer in organic planar heterojunction.•The thickness of an efficient exciton buffer layer depends on its homogeneity.•ROETOM gives very highly homogeneous thin films.•The optimum thickness of ROETOM is only 6.5nm. A successful approach to improve organic solar c...

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Bibliographic Details
Published in:Solid-state electronics Vol. 104; pp. 1 - 5
Main Authors: Lakhdar Toumi, A., Khelil, A., Tobel, K., Makha, M., Hernández, L.A., Mouchaal, Y., Cattin, L., del Valle, M.A., Diaz, F.R., Bernède, J.C.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-02-2015
Elsevier
Subjects:
Blocking
Cathodes
Chemical Sciences
Diffusion
Excitation
Exciton blocking layer
Homogeneity
Interfaces
Optimization
Organic solar cells
Photovoltaic cells
Physical vapour deposition
Solar cells
Thin films
Interfaces
Physical vapour deposition
Organic solar cells
Exciton blocking layer
interfaces
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Summary:•Use of ROETOM as new exciton buffer layer in organic planar heterojunction.•The thickness of an efficient exciton buffer layer depends on its homogeneity.•ROETOM gives very highly homogeneous thin films.•The optimum thickness of ROETOM is only 6.5nm. A successful approach to improve organic solar cell (OSC) performance is the introduction of a thin layer called exciton blocking layer (EBL) at the interface organic material/cathode. It is shown that, the EBL allows improving significantly the solar cells performances whatever the molecule used, either the well known bathocuproine (BCP) or the new molecule Z, 5[4-Me-3-N (2-OMe Phenyl)Δ4 thiazolidene], 2-thioxo-3-N(2-OEthylphenyl)thizolidine-4-one (ROETOM). The optimum thickness of the EBL in the case of ROETOM is 6nm, while it is 9nm in the case of BCP. These different behaviours are justified by the very high homogeneity of the ROETOM layer. Homogeneity which prevents easily metal atom diffusion when it is introduced in OSC and therefore 6nm are sufficient to prevent metal atom diffusion into the acceptor.
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ISSN:0038-1101
1879-2405
DOI:10.1016/j.sse.2014.11.006