Abstract
Using hydrogen as fuel requires efficient production and retrieval from energy carriers. Here, we describe the synthesis of various pure phases of nickel phosphide and describe the growth mechanisms. A comparative study illustrates the phases’ catalytic activity towards hydrogen production through electrochemical water reduction as well as hydrogen retrieval by hydrolysis of hydrogen storage materials (ammonia-borane and NaBH4). Charge separation between the Niδ+ and Pδ− sites in the various Ni–P phases plays a key role in achieving the desired efficacy of the catalytic reaction. Ni2P exhibited a significant enhancement towards the hydrogen evolution reaction, with an overpotential of 126 mV at J= 10 mA cm−2 in acid and 180 mV in alkaline. Ni12P5 was the most efficient catalyst, with a turnover frequency (TOF) = 23.0 min−1 for hydrogen evolution from ammonia-borane, and TOF= 17.3 min−1 from NaBH4, which is in accordance with noble metal nanoparticles.
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