Low-cost plasmonic semiconductors are ideal substitutes for precious metals in surface-enhanced Raman scattering (SERS) applications. However, developing plasmonic semiconductors with both high-sensitivity SERS performance and the capability to monitor molecular… Click to show full abstract
Low-cost plasmonic semiconductors are ideal substitutes for precious metals in surface-enhanced Raman scattering (SERS) applications. However, developing plasmonic semiconductors with both high-sensitivity SERS performance and the capability to monitor molecular reactions during photocatalysis remains a significant challenge. Herein, 1D plasmonic W18O49 (WO) nanowires were grown on the surface of 2D reduced graphene oxide (rGO) to construct a 1D/2D heterostructure (WO/rGO). The ultrathin 2D-rGO stabilizes the surface oxygen vacancies within 1D-WO for strong localized surface plasmon resonance (LSPR), while facilitating the generation of more hot electrons and effectively mitigating their ultrafast relaxation. The optimized WO/rGO heterostructure demonstrates exceptional SERS performance for target methylene blue (MB) molecules, with the detection limit reaching down to 10-10 M. More intriguingly, the plasmonic WO/rGO heterostructure simultaneously enables boosted photocatalytic MB degradation and in situ SERS monitoring of the catalytic process. Mechanistic studies reveal that the C-H bonds in MB are preferentially cleaved over the aromatic C-C bonds during photocatalysis, providing molecular-level insights into the degradation pathway. This dual-functional plasmonic heterostructure holds great promise for quantitative SERS analysis of bio-chemicals and self-tracking of catalytic reactions.
               
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