Abstract
We report on highly disordered array of Au coated silicon nanowires (Au/SiNWs) as surface enhanced Raman scattering (SERS) probe combined with electrochemical detection for biosensing applications. SiNWs, few microns long, were grown by plasma enhanced chemical vapor deposition on common microscope slides and covered by Au evaporated film, 150 nm thick. The capability of the resulting composite structure to act as SERS biosensor was studied via the biotin-avidin interaction: the Raman signal obtained from this structure allowed to follow each surface modification step as well as to detect efficiently avidin molecules over a broad range of concentrations from micromolar down to the nanomolar values. The metallic coverage wrapping SiNWs was exploited also to obtain a dual detection of the same bioanalyte by electrochemical impedance spectroscopy (EIS). Indeed, the SERS signal and impedance modifications induced by the biomolecule perturbations on the metalized surface of the NWs were monitored on the very same three-electrode device with the Au/SiNWs acting as both working electrode and SERS probe.
Highlights
We report on highly disordered array of Au coated silicon nanowires (Au/SiNWs) as surface enhanced Raman scattering (SERS) probe combined with electrochemical detection for biosensing applications
The materials are characterized by scanning electron microscopy (SEM) and energy-dispersive X-ray (EDX) analysis
We explored forest of SiNWs covered by a Au layer as effective substrate for enhancing Raman signal of the adsorbed molecules
Summary
We report on highly disordered array of Au coated silicon nanowires (Au/SiNWs) as surface enhanced Raman scattering (SERS) probe combined with electrochemical detection for biosensing applications. The advances in nanofabrication technologies have led to the emergence of a myriad of novel SERS substrates, including colloidal metal (essentially Au or Ag) nanoparticles (NPs)[7,8], assembly of metal nanostructures on different surfaces[9,10,11,12], metal decorated porous materials[13,14], metal films evaporated on nanosphere-coated substrates[15] These nanomaterials show large Raman enhancement ability, most of them are too technologically demanding and expensive to be used to fabricate large quantities of substrates for practical applications with high reproducibility and long term storage properties.
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