Metal nanoparticle arrays have been developed for various surface-enhanced Raman scattering applications, such as trace detection of analytes and medical-ingredients. The basic concept of the SERS effect is that the Raman scattering cross-section of molecules located in nanogaps among metallic nanostructures can be tremendously enhanced by the amplification of electromagnetic fields resulted from the excited localized surface plasmon resonances (LSPR). Herein, the extremely uniform-sized single-layer gold nanoparticle arrays and silver nanoparticle arrays embed in well-ordered mesoporous silica (MSNs and MSTF) on silicon wafer were fabricated via a surfactant-free method for SERS applications. The main research contents are as follow: (1) The MSNs and MSTF act as hosts to confine the size and uniformity of metal NPs. The pore size and nanogaps of metal NPs can be precisely controlled by tuning the pore size and pore to pore distance of MSNs and MSTF hosts. As a result, the MSN-Au_5 nm substrate achieved the outstanding SERS activities with an enhancement factor 2.8×108. Under the optimal conditions, this SERS substrate exhibited a low detection limit (10–10 M for 4-mercaptobenzoic) and excellent enhancement uniformity (relative standard deviation, RSD = 12%) and long-term storage stability for more than 3 months. Furthermore, the detection of the pesticide residue both in fruit juice and fruit peel showing the excellent SERS signals under the natural environment. These results indicate that MSN-Au_5 nm as a SERS substrate own great potential in the application of trace level pesticide detection. (2) MSN-Ag_5 nm substrate prepared by using silver thiosulfate as precursor. The results show that the residual sulfur on the surface of the substrate will affect the adsorption process of molecules to the substrate surface, and then affect the SERS performance of the substrate.