【摘 要】
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The design and development of electrocatalysts composed of non-noble-metal catalysts with both large surface area and high electrical conductivities are crucial for the hydrogen evolution reaction (HER).Here,a xylose-based porous carbon is coupled with a
【机 构】
:
State Key Laboratory of Pulp and Paper Engineering, South China University of Technology, Guangzhou
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The design and development of electrocatalysts composed of non-noble-metal catalysts with both large surface area and high electrical conductivities are crucial for the hydrogen evolution reaction (HER).Here,a xylose-based porous carbon is coupled with a MoS2-MoP heterojunction (MoS2-MoP/FPC) hybrid and used as a promising catalyst for HER.The hybrid is prepared by immobilizing petal-like MoS2 nanosheets on porous carbon (MoS2/FPC),followed by controlling the phosphidation in Ar/H2 to form MoS2-MoP/FPC.Red phosphorus provides the P species that can induce the construction of the heterojunction under the reducing atmosphere,along with the generation of a MoP phase and the splitting of the MoS2 phase.The as-prepared MoS2-MoP/FPC catalyst offers a low overpotential of 144mV at a current density of 10 mAcm-2 and a small Tafel slope of 41 mVdec-1 for the HER in acidic media,as well as remarkable stability.Apart from the active nature of the hybrid,its outstanding activity is attributed to the MoS2-MoP heterojunction,and the good charge/mass-transfer ability of porous carbon.This strategy provides a new method to develop and design low-cost and high-performance catalysts for the HER.
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