Abstract
Two-dimensional layered material Molybdenum disulfide (MoS(2)) exhibits a flat surface without dangling bonds and is expected to be a suitable surface-enhanced Raman scattering (SERS) substrate for the detection of organic molecules. However, further fabrication of nanostructures for enhancement of SERS is necessary because of the low detection efficiency of MoS(2). In this paper, period-distribution Si/MoS(2) core/shell nanopillar (NP) arrays were fabricated for SERS. The MoS(2) thin films were formed on the surface of Si NPs by sulfurizing the MoO(3) thin films coated on the Si NP arrays. Scanning electron microscopy, Raman spectroscopy, and X-ray photoelectron spectroscopy were performed to characterize Si/MoS(2) core-shell nanostructure. In comparison with a bare Si substrate and MoS(2) thin film, the use of Si/MoS(2) core-shell NP arrays as SERS substrates enhances the intensity of each SERS signal peak for Rhodamine 6G (R6G) molecules, and especially exhibits about 75-fold and 7-fold enhancements in the 1361 cm(-1) peak signal, respectively. We suggest that the Si/MoS(2) core-shell NP arrays with larger area could absorb more R6G molecules and provide larger interfaces between MoS(2) and R6G molecules, leading to higher opportunity of charge transfer process and exciton transitions. Therefore, the Si/MoS(2) core/shell NP arrays could effectively enhance SERS signal and serve as excellent SERS substrates in biomedical detection.