Optimized electromagnetic enhancement and charge transfer in MXene/Au/Cu2O hybrids for achieving efficient SERS†
Abstract
The rational optimization of the electromagnetic field enhancement and charge transfer in a Raman substrate is vital for achieving efficient surface-enhanced Raman scattering (SERS). Herein, a ternary plasmonic substrate, whose structure-adjustable Au nanotriangle/Cu2O hybrids are combined with two-dimensional Ti3C2Tx MXene ultrathin nanosheets, is prepared and used for efficient SERS detection of molecules. By controlling the growth of Cu2O on Au nanotriangles, Au/Cu2O hybrids with three tips exposed are prepared, which show much better SERS performance than bare Au and core–shell Au@Cu2O in detecting methylene blue (MB) under excitation at 785 nm due to the optimized electromagnetic field enhancement and charge transfer. Furthermore, the Au/Cu2O hybrids are transferred to the plasmonic Ti3C2Tx nanosheet, generating a further enhanced electromagnetic field around their interfaces. As a result, the MXene/Au/Cu2O hybrids present further improved SERS activity, and their analytical enhancement factor reaches 2.4 × 109 and the detection limit is as low as 10−12 M. The enhancement mechanism can be ascribed to the improved electric field enhancement around the Au tips and the interface between MXene and Au/Cu2O. Meanwhile, the multiple charge-transfer processes between Au, Cu2O, MXene, and MB also play an important role in improving the SERS signal.