Abstract
Solar hydrogen production from water could be a sustainable and environmentally friendly alternative to fossil energy carriers, yet so far photocatalysts active and stable enough for large-scale applications are not available, calling for advanced research efforts. In this work, H2 evolution rates of up to 1968 and 5188 μmol h−1 g−1 were obtained from aqueous solutions of triethanolamine (TEOA) and oxalic acid (OA), respectively, by irradiating composites of AgIn5S8 (AIS), mesoporous C3N4 (CN, surface area >150 m2/g) and ≤2 wt.% in-situ photodeposited Pt nanoparticles (NPs) with UV-vis (≥300 nm) and pure visible light (≥420 nm). Structural properties and electron transport in these materials were analyzed by XRD, STEM-HAADF, XPS, UV-vis-DRS, ATR-IR, photoluminescence and in situ-EPR spectroscopy. Initial H2 formation rates were highest for Pt/CN, yet with TEOA this catalyst deactivated by inclusion of Pt NPs in the matrix of CN (most pronounced at λ ≥ 300 nm) while it remained active with OA, since in this case Pt NPs were enriched on the outermost surface of CN. In Pt/AIS-CN catalysts, Pt NPs were preferentially deposited on the surface of the AIS phase which prevents them from inclusion in the CN phase but reduces simultaneously the initial H2 evolution rate. This suggests that AIS hinders transport of separated electrons from the CN conduction band to Pt NPs but retains the latter accessible by protons to produce H2.
Highlights
In light of the foreseeable depletion of fossil energy carriers, much research work has been done in recent years to explore alternative, sustainable and environmentally friendly ways of supplying energy [1,2]
It appeared that the total Pt content determined by ICP-OES in Pt/C3 N4 (CN) is much lower than the theoretical value of 2 wt.%, after both 3 h and 20 h irradiation with UV-vis light
This is probably due to the fact that not the whole amount of the solved [PtCl6 ]2− precursor but only a part of it is reduced and deposited as Pt NPs in basic TEOA
Summary
In light of the foreseeable depletion of fossil energy carriers, much research work has been done in recent years to explore alternative, sustainable and environmentally friendly ways of supplying energy [1,2]. Most of the common semiconductor-based photocatalysts, first and foremost TiO2 , and titanates and tantalates such as SrTiO3 and NaTaO3 , can only harvest UV light due to their large band gaps, while others have unsuitable band positions (e.g., WO3 ) or are not stable (e.g., CdS) [4]. C3 N4 , is an abundant, easy-to-prepare organic semiconductor which absorbs light in the visible range. Wang et al showed for the first time in 2009 that this material can liberate hydrogen from water using light with λ > 420 nm in the presence of methanol or triethanolamine (TEOA) as sacrificial agents [5]. Many papers on the use of differently prepared and modified C3 N4 photocatalysts for light-driven water splitting have been published
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