Surface reconstruction of oxygen evolution reaction electrocatalysts with enhanced catalysis activity has been intensively reported recently.However,the surface reconstruction has seldom been observed from hydrogen ev...Surface reconstruction of oxygen evolution reaction electrocatalysts with enhanced catalysis activity has been intensively reported recently.However,the surface reconstruction has seldom been observed from hydrogen evolution reaction(HER)catalysts.Here,we report the surface reconstruction with enhancement of catalysis activity in the HER catalyst of NiMoO_(4)-CoO nanosheets on carbon cloth.Mo species dissolve from NiMoO_(4)-CoO by activating the pristine catalyst at certain potential,which enables the formation of K_(2)Mo_(3)O10 on the catalyst surface.The surface reconstruction not only brings large numbers of active sites and enhanced charge transfer,but also boosts the intrinsic activity per catalysis site.Together with the above advantages and the benefits of nanosheet structure,the activated catalyst exhibits high HER activity with the ultralow overpotentials of 130 and 192 mV at high current densities of 100 and 400 mA cm^(-2).This finding provides new insight for the exploration on surface reconstruction of transition metal-based HER catalysts and may enable further understanding on the origin of catalysis activity improvement.展开更多
基金the financial support from Shandong Provincial Natural Science Foundation(ZR2019MEM035).
文摘Surface reconstruction of oxygen evolution reaction electrocatalysts with enhanced catalysis activity has been intensively reported recently.However,the surface reconstruction has seldom been observed from hydrogen evolution reaction(HER)catalysts.Here,we report the surface reconstruction with enhancement of catalysis activity in the HER catalyst of NiMoO_(4)-CoO nanosheets on carbon cloth.Mo species dissolve from NiMoO_(4)-CoO by activating the pristine catalyst at certain potential,which enables the formation of K_(2)Mo_(3)O10 on the catalyst surface.The surface reconstruction not only brings large numbers of active sites and enhanced charge transfer,but also boosts the intrinsic activity per catalysis site.Together with the above advantages and the benefits of nanosheet structure,the activated catalyst exhibits high HER activity with the ultralow overpotentials of 130 and 192 mV at high current densities of 100 and 400 mA cm^(-2).This finding provides new insight for the exploration on surface reconstruction of transition metal-based HER catalysts and may enable further understanding on the origin of catalysis activity improvement.
