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Quantitative and Sensitive SERS Platform with Analyte Enrichment and Filtration Function

Qianqian Ding, Jing Wang, Xueyan Chen, Hong Liu, Quanjiang Li, Yanling Wang, Shikuan Yang

2020Nano Letters293 citationsDOI

Abstract

Surface-enhanced Raman scattering (SERS) technique with naturally born analyte identification capability can achieve ultrahigh sensitivity. However, the sensitivity and quantification capability of SERS are assumed to be mutually exclusive. Here, we prohibit the formation of the ultrasensitive SERS sites to achieve a high quantification capability through separating the gold (Au) nanorods from approaching each other with thick metal organic framework (MOF) shells. The sensitivity decrease caused by the absence of the ultrasensitive SERS sites is compensated by the analyte enrichment function of a slippery surface. The porous MOF shell around the Au nanorod only allows analytes smaller than the pore size to approach the Au nanorods and contribute to the SERS spectrum within the complex sample, greatly enhancing the analyte identification capability. Overall, we have demonstrated an integrated SERS platform with analyte enrichment and analyte filtration function, realizing sensitive, quantitative, and size selective analyte identification in complex environments.

Topics & Concepts

AnalyteNanorodRaman scatteringNanotechnologyMaterials scienceFiltration (mathematics)ChemistryAnalytical Chemistry (journal)Raman spectroscopyChromatographyOpticsMathematicsStatisticsPhysicsGold and Silver Nanoparticles Synthesis and ApplicationsNanocluster Synthesis and ApplicationsAdvanced Nanomaterials in Catalysis
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