Low-temperature selective synthesis of metastable α-MoC with electrochemical properties: Electrochemical co-reduction of CO2 and MoO3 in molten salts

摘要

Metastable molybdenum carbide (alpha-MoC), as a catalyst and an excellent support for metal catalysts, has been widely used in thermo/electro-catalytic reactions. However, the selective synthesis of alpha-MoC remains a great challenge. Herein, a simple one-pot synthetic strategy for the selective preparation of metastable alpha-MoC is proposed by electrochemical co-reduction of CO2 and MoO3 in a low-temperature eutectic molten carbonate. The synthesized alpha-MoC shows a reed flower-like morphology. By controlling the electrolysis time and monitoring the phase and morphology of the obtained products, the growth process of alpha-MoC is revealed, where the carbon matrix is deposited first followed by the growth of alpha-MoC from the carbon matrix. Moreover, by analyzing the composition of the electrolytic products, the formation mechanism for alpha-MoC is proposed. In addition, through this one-pot synthetic strategy, S-doped alpha-MoC is successfully synthesized. Density functional theory (DFT) calculations reveal that S doping enhanced the HER performance of alpha-MoC by facilitating water absorption and dissociation and weakening the bond energy of Mo-H to accelerate H desorption. The present work not only highlights the valuable utilization of CO2 but also offers a new perspective on the design and controllable synthesis of metal carbides and their derivatives.

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