Please use this identifier to cite or link to this item: https://physrep.ff.bg.ac.rs/handle/123456789/1312
Title: High-performance hydrogen evolution electrocatalysis using proton-intercalated TiO<inf>2</inf>nanotube arrays as interactive supports for Ir nanoparticles
Authors: Lačnjevac, Uroš
Vasilić, Rastko 
Dobrota, Ana
Đurđić, Slađana
Tomanec, Ondřej
Zbořil, Radek
Mohajernia, Shiva
Nguyen, Nhat Truong
Skorodumova, Natalia
Manojlović, Dragan
Elezović, Nevenka
Pašti, Igor
Schmuki, Patrik
Issue Date: 21-Nov-2020
Journal: Journal of Materials Chemistry A
Abstract: 
Developing ultraefficient electrocatalytic materials for the hydrogen evolution reaction (HER) with low content of expensive platinum group metals (PGMs) via low-energy-input procedures is the key to the successful commercialization of green water electrolysis technologies for sustainable production of high-purity hydrogen. In this study, we report a facile room-temperature synthesis of ultrafine metallic Ir nanoparticles on conductive, proton-intercalated TiO2 nanotube (H-TNT) arrays via galvanic displacement. A series of experiments demonstrate that a controlled transformation of the H-TNT surface microstructure from neat open-top tubes to disordered nanostripe bundles ("nanograss") is highly beneficial for providing an abundance of exposed Ir active sites. Consequently, for nanograss-engineered composites, outstanding HER activity metrics are achieved even at very low Ir(iii) precursor concentrations. An optimum Ir@TNT cathode loaded with 5.7 μgIr cm-2 exhibits an overpotential of -63 mV at -100 mA cm-2 and a mass activity of 34 A mgIr-1 at -80 mV under acidic conditions, along with excellent catalytic durability and structural integrity. Density functional theory (DFT) simulations reveal that the hydrogen-rich TiO2 surface not only stabilizes the deposited Ir and weakens its H binding strength to a moderate intensity, but also actively takes part in the HER mechanism by refreshing the Ir catalytic sites near the Ir|H-TiO2 interface, thus substantially promoting H2 generation. The comprehensive characterization combined with theory provides an in-depth understanding of the electrocatalytic behavior of H-TNT supported PGM nanoparticles and demonstrates their high potential as competitive electrocatalyst systems for the HER. This journal is
URI: https://physrep.ff.bg.ac.rs/handle/123456789/1312
ISSN: 2050-7488
DOI: 10.1039/d0ta07492f
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