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http://dx.doi.org/10.5012/bkcs.2011.32.8.2743

Wavelength Conversion Lanthanide(III)-cored Complex for Highly Efficient Dye-sensitized Solar Cells  

Oh, Jung-Hwan (Department of Advanced Materials Chemistry and Center for Advanced Photovoltaic Materials (ITRC) and Center for Next Generation Photovoltaic System (WCU), Korea University)
Song, Hae-Min (Department of Advanced Materials Chemistry and Center for Advanced Photovoltaic Materials (ITRC) and Center for Next Generation Photovoltaic System (WCU), Korea University)
Eom, Yu-Kyung (Department of Advanced Materials Chemistry and Center for Advanced Photovoltaic Materials (ITRC) and Center for Next Generation Photovoltaic System (WCU), Korea University)
Ryu, Jung-Ho (Department of Advanced Materials Chemistry and Center for Advanced Photovoltaic Materials (ITRC) and Center for Next Generation Photovoltaic System (WCU), Korea University)
Ju, Myung-Jong (Department of Advanced Materials Chemistry and Center for Advanced Photovoltaic Materials (ITRC) and Center for Next Generation Photovoltaic System (WCU), Korea University)
Kim, Hwan-Kyu (Department of Advanced Materials Chemistry and Center for Advanced Photovoltaic Materials (ITRC) and Center for Next Generation Photovoltaic System (WCU), Korea University)
Publication Information
Bulletin of the Korean Chemical Society / v.32, no.8, 2011 , pp. 2743-2750 More about this Journal
Abstract
Lanthanide(III)-cored complex as a wavelength conversion material has been successfully designed and synthesized for highly efficient dye-sensitized solar cells, for the first time, since light with a short wavelength has not been effectively used for generating electric power owing to the limited absorption of these DSSCs in the UV region. A black dye (BD) was chosen and used as a sensitizer, because BD has a relatively weak light absorption at shorter wavelengths. The overall conversion efficiency of the BD/WCM device was remarkably increased, even with the relatively small amount of WCM added to the device. The enhancement in $V_{oc}$ by WCM, like DCA, could be correlated with the suppression of electron recombination between the injected electrons and $I_3{^-}$ ions. Furthermore, the short-circuit current density was significantly increased by WCM with a strong UV light-harvesting effect. The energy transfer from the Eu(III)-cored complex to the $TiO_2$ film occurred via the dye, so the number of electrons injected into the $TiO_2$ surface increased, i.e., the short-circuit current density was increased. As a result, BD/WCM-sensitized solar cells exhibit superior device performance with the enhanced conversion efficiency by a factor of 1.22 under AM 1.5 sunlight: The photovoltaic performance of the BD/WCM-based DSSC exhibited remarkably high values, $J_{sc}$ of 17.72 mA/$cm^2$, $V_{oc}$ of 720 mV, and a conversion efficiency of 9.28% at 100 mW $cm^{-2}$, compared to a standard DSSC with $J_{sc}$ of 15.53 mA/$cm^2$, $V_{oc}$ of 689 mV, and a conversion efficiency of 7.58% at 100 mW $cm^{-2}$. Therefore, the Eu(III)-cored complex is a promising candidate as a new wavelength conversion coadsorbent for highly efficient dye-sensitized solar cells to improve UV light harvesting through energy transfer processes. The abstract should be a single paragraph which summaries the content of the article.
Keywords
Europium(III)-cored complex; Wavelength conversion material; Energy transfer; UV light harvesting; Dye-sensitized solar cells;
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