Abstract
Dye-Sensitized Photoelectrochemical Cells (DS-PECs) have been emerging as promising devices for efficient solar-induced water splitting. In DS-PECs, dyes and catalysts for water oxidation and/or reduction are typically two separate components, thus limiting charge transfer efficiency. A small number of organometallic dyes have been integrated with a catalyst to form an integrated dye–catalyst dyad for photoanodes, but until now no dyads based on metal-free organic dyes have been reported for photoanodes. We herein report the first example of dyad-sensitized photoanodes in DS-PEC water splitting based on metal-free organic dyes and a Ru catalyst. The di-branched donor–π–acceptor dyes carry a donor carbazole moiety which has been functionalized with two different terminal pyridyl ligands in order to coordinate a benchmark Ru complex as a water oxidation catalyst, affording water oxidation dyads. The two dyads have been fully characterized in their optical and electrochemical properties, and XPS has been used to confirm the presence of the catalyst bonded to the dye anchored to the semiconductor anode. The two dyads have been investigated in DS-PEC, showing an excellent faradaic efficiency (88% average across all cells, with a best cell efficiency of 95%), thus triggering new perspectives for the design of efficient molecular dyads based on metal-free dyes for DS-PEC water splitting.
Highlights
In the search for an alternative to fossil fuels, hydrogen is gaining increasing interest in the scienti c community and the automotive-aerospace sector, because its combustion generates only water with a zero-carbon footprint.[1,2,3] Hydrogen is today mainly produced from methane via the steam-reforming reaction.[4]
We report the first example of dyad-sensitized photoanodes in Dye-Sensitized Photoelectrochemical Cells (DS-photoelectrochemical cells (PEC)) water splitting based on metal-free organic dyes and a Ru catalyst
The two dyads have been investigated in DS-PEC, showing an excellent faradaic efficiency (88% average across all cells, with a best cell efficiency of 95%), triggering new perspectives for the design of efficient molecular dyads based on metal-free dyes for DS-PEC water splitting
Summary
In the search for an alternative to fossil fuels, hydrogen is gaining increasing interest in the scienti c community and the automotive-aerospace sector, because its combustion generates only water with a zero-carbon footprint.[1,2,3] Hydrogen is today mainly produced from methane via the steam-reforming reaction.[4]. We report the first example of dyad-sensitized photoanodes in DS-PEC water splitting based on metal-free organic dyes and a Ru catalyst. The electrochemical properties of the dyad-sensitized anodes have been investigated by CV and compared with those of the dye and the reference catalyst [Ru(bda)(pic)2] (Fig. S4 and S5, ESI†).
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