Abstract
Surface-enhanced Raman scattering (SERS) for semiconductor nanomaterial systems is limited due to weak Raman signal intensity and unclear charge-transfer (CT) processes for chemical enhancement. Here, rare-earth element neodymium-doped titanium dioxide (Nd-TiO2) nanoparticles (NPs) were synthesized by the sol–gel method. The characterizations show that the doping of Nd ions causes TiO2 NPs to show an increase in the concentration of defects and change in the energy level structure. The CT process between Nd-TiO2 NPs substrate and probe molecule 4-Mercaptopyridine (4-Mpy) was innovatively analyzed using the relative energy level location relationship of the Dorenbos model. The SERS signal intensity exhibits an exponential enhancement with increasing Nd doping concentration and reaches its optimum at 2%, which is attributed to two factors: (1) The increase in the defect concentration is beneficial to the CT process between the TiO2 and the probe molecule; (2) the introduction of 4f electron orbital energy levels of rare-earth ions created unique CT process between Nd3+ and 4-Mpy. Moreover, the Nd-TiO2 NPs substrate shows excellent SERS performance in Raman signal reproducibility (RSD = 5.31%), the limit of detection (LOD = 10−6 M), and enhancement factor (EF = 3.79 × 104). Our work not only improves the SERS performance of semiconductor substrates but also provides a novel approach to the development of selective detection of probe molecules.
Highlights
Due to the high sensitivity, good selectivity, non-destructiveness, and information about the structure of adsorbed molecules, surface-enhanced Raman scattering (SERS) has attracted widespread interest [1,2,3]
The results show that the surface morphology, concentrations of defects, and energy level structure of the substrates were changed with an increasing Nd/Ti ratio concentration compared with pure TiO2 NPs
The SERS signal intensity is greatly enhanced and reaches its optimum at a doping concentration of 2%, which is the chemical enhancement mechanism triggered by a unique CT process that occurs between the Nd-TiO2 and 4-Mpy probe molecule
Summary
Due to the high sensitivity, good selectivity, non-destructiveness, and information about the structure of adsorbed molecules, surface-enhanced Raman scattering (SERS) has attracted widespread interest [1,2,3]. Yang et al [31] developed a novel sensitive Mo-doped Ta2 O5 semiconductor substrate by the “coupled resonance” effect, which can detect methyl violet (MV) molecules up to 9 × 10−9 M This SERS enhancement effect can be attributed to (i) MV molecular resonance,. The results show that the surface morphology, concentrations of defects, and energy level structure of the substrates were changed with an increasing Nd/Ti ratio concentration compared with pure TiO2 NPs. The SERS signal intensity is greatly enhanced and reaches its optimum at a doping concentration of 2%, which is the chemical enhancement mechanism triggered by a unique CT process that occurs between the Nd-TiO2 and 4-Mpy probe molecule. The substrate offers excellent SERS performance, and facilitates the exploration of the selective detection of various probe molecules in SERS applications
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