KOPS - Das Institutionelle Repositorium der Universität Konstanz

Temperature-stable and optically transparent thin-film zinc oxide aerogel electrodes as model systems for 3D interpenetrating organic–inorganic heterojunction solar cells

Temperature-stable and optically transparent thin-film zinc oxide aerogel electrodes as model systems for 3D interpenetrating organic–inorganic heterojunction solar cells

Zitieren

Dateien zu dieser Ressource

Dateien Größe Format Anzeige

Zu diesem Dokument gibt es keine Dateien.

KRUMM, Michael, Fabian PAWLITZEK, Jonas WEICKERT, Lukas SCHMIDT-MENDE, Sebastian POLARZ, 2012. Temperature-stable and optically transparent thin-film zinc oxide aerogel electrodes as model systems for 3D interpenetrating organic–inorganic heterojunction solar cells. In: ACS Applied Materials & Interfaces. 4(12), pp. 6522-6529. ISSN 1944-8244. eISSN 1944-8252. Available under: doi: 10.1021/am302458n

@article{Krumm2012-12Tempe-21601, title={Temperature-stable and optically transparent thin-film zinc oxide aerogel electrodes as model systems for 3D interpenetrating organic–inorganic heterojunction solar cells}, year={2012}, doi={10.1021/am302458n}, number={12}, volume={4}, issn={1944-8244}, journal={ACS Applied Materials & Interfaces}, pages={6522--6529}, author={Krumm, Michael and Pawlitzek, Fabian and Weickert, Jonas and Schmidt-Mende, Lukas and Polarz, Sebastian} }

Temperature-stable and optically transparent thin-film zinc oxide aerogel electrodes as model systems for 3D interpenetrating organic–inorganic heterojunction solar cells Krumm, Michael Schmidt-Mende, Lukas Novel, nanostructured electrode materials comprising porous ZnO films with aerogel morphology are presented. Almost any substrate including polymers, metals, or ceramics can be coated using a method that is suitable for mass production. The thin, porous films can be prepared from the wet gels via conventional drying, supercritical drying is not necessary. The filigree ZnO network is thermally very stable and exhibits sufficient electrical conductivity for advanced electronic applications. The latter was tested by realizing a highly desired architecture of organic−inorganic hybrid solar cells. After sensitizing of the ZnO with a purely organic squarine dye (SQ2), a nanostructured, interpenetrating 3D network of the inorganic semiconductor (ZnO) and organic semiconductor (P3HT) was prepared. The solar cell device was tested under illumination with AM 1.5G solar light (100 mW/cm2) and exhibited an energy conversion efficiency (ηeff) of 0.69%. Schmidt-Mende, Lukas deposit-license Pawlitzek, Fabian Weickert, Jonas 2013-02-08T12:22:11Z eng Polarz, Sebastian 2013-02-08T12:22:11Z ACS Applied Materials & Interfaces ; 4 (2012), 12. - S. 6522-6529 Weickert, Jonas Pawlitzek, Fabian 2012-12 Polarz, Sebastian Krumm, Michael

Das Dokument erscheint in:

KOPS Suche


Stöbern

Mein Benutzerkonto