Browsing by Subject "hydrogen evolution reaction"

Molecular hydrogen is considered as the primary alternative to replace fossil fuels for future energy supply. Hydrogen can be produced sustainably through electrocatalytic hydrogen evolution reaction which is a vital step in water electrolysis. So far, the efficiencies of electrochemical and photoelectrochemical water electrolysis systems are too low to satisfy the demands for hydrogen on a commercial scale. Plasmonic nanostructures containing a plasmonic and a catalytic component hold great promise for enhancing the performance of typical water electrolysis systems through plasmonic photocatalysis utilizing localized surface plasmon resonance excitation. Here, a novel plasmonic-catalytic u@AgPd nanorattle is synthesized, characterized, and investigated for plasmon-enhanced hydrogen evolution reaction to provide new insights into the design of light-assisted water electrolysis systems. The nanorattle exhibited significant improvements of performance towards hydrogen evolution reaction under 427 nm illumination, displaying a near 2-fold current increase and a decreased overpotential of 58 mV at a current density of 10 mAcm-2. The material is evidenced to plasmon-enhance the electrocatalytic performance through a combination of charge transfer and local heating mechanisms.