Photocatalytic Membrane for Hydrogen Evolution: Directed Electron and Hole Transfer across Pt–AgInS<sub>2</sub>–Nafion
Yiseul Yu, Anthony Kipkorir, Myong Yong Choi, Prashant V. Kamat
Abstract
A photocatalytically active membrane, designed by embedding AgInS 2 semiconductor nanoparticles and a Pt cocatalyst, facilitates a “vectorial” flow of photogenerated electrons and holes in opposite directions. The fabricated Pt–AgInS 2 –Nafion membrane, when inserted in an H-cell containing 50% ethanol (AgInS 2 side) and water (pH = 4, Pt side), produced H 2 under visible light irradiation. Photogenerated electrons reduced H + at the Pt surface to produce H 2, while oxidation of ethanol with holes at AgInS 2 also produced H 2 . Back electron transfer at the Pt surface and surface defects within AgInS 2 were responsible for the lower H 2 yield in the reduction compartment. Remediation of the AgInS 2 film with mercaptopropionic acid increased the yield 5–10 times by overcoming the loss of charge carriers at the defect sites. The feasibility of carrying out selective reduction and oxidation processes by directing the flow of charge carriers highlights the usefulness of photocatalytic membranes in solar fuel generation.