Both of them depended on the narrow nanogap distribution. Third, the gradual hemispherical nanostructures could enhance

the Raman cross-sectional area by amplifying the incidence signal of the radiation and absorption. Although, the hemiellipsoidal structural parameters were kept the same with the hemispherical nanostructure, starting from the PS diameter as 200 nm, etching depth as 130 nm, and 5-Fluoracil cell line all deposited with 20-nm Ag film. The SERS average enhancement factor of hemiellipsoidal nanostructure was only about 106, smaller than the hemispherical nanostructure. Among these three structures, the distance between two adjacent hemiellipsoidal structures was the largest. The SERS enhancement factor of pyramidal pits was about 108, which was smaller than the hemispherical nanostructure; however, larger than the hemiellipsoidal nanostructure, and also larger than the previous literatures [30, 31]. Although the three sharp vertices of the surface grids and bottom points of pyramidal pits constructed the hot-spots, the scale of top-surface triangular grid of the pyramidal pits was still small enough to concentrate the light and boost the SERS enhancement. The tunable SERS signals altered with the controllable nanogaps (Additional file 1: Figure S1). Such kind of SERS substrate is a reusable substrate which can be reused

simply by removing and redepositing the metal thin film (Additional file 1: Figure S2). Figure 3 SERS spectra of monolayer R6G (a) and average SERS enhancement factor EF (b). (a) Monolayer Selleckchem H 89 R6G is absorbed on three types of 3D Ag nanostructures, with laser power 1.8 mW and the integration time 10 s. The SERS spectrum of the unpatterned Ag film was amplified 40-fold and performed with laser power 9 mW, the integration time 20 s, and the concentration of R6G 10-3 mM. (b) Average SERS enhancement factor EF as the function of the geometries. Almost every experimental study of SERS omitted the issues of the negative effects

of adhesion layer [32–36], while we found that it had a dramatic influence of SERS enhancement. Since noble metals possess (involving Au, Ag, Pt, and so on) poor Ribonucleotide reductase adhering ability to quartz substrate, an artificial adhesion-promoting intermediate layer between noble metal and quartz substrate, such as Cr (Chromium) or Ti (Titanium) is needed. However, the intermediate layer Cr or Ti would greatly shift and broaden the surface plasmon resonance. The magnitude of resonance damping has also been found when the thickness of the adhesion layer increases. Fortunately, our 3D nanostructures could resolve the adhesion-promoting intermediate layer issue because the noble metal deposition procedure was the final step, which avoided influence on the chemical reagents and poor adhering ability.