Ion beam nanoengineering of surfaces for molecular detection using surface enhanced Raman scattering

Ion beam nanoengineering of surfaces is a promising way to tailor the surface properties for a variety of technological applications. One of the unique applications of ion beam methods is to synthesize embedded nanostructures at the nearby surface region of a variety of materials. This is an excelle...

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Bibliographic Details
Published inMolecular systems design & engineering Vol. 7; no. 5; pp. 411 - 421
Main Authors Prakash, Jai, Samriti, Wijesundera, Dharshana N., Rajapaksa, Indrajith, Chu, Wei-Kan
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 10.05.2022
Subjects
Biomedical materials
Gold
Ion beams
Ion implantation
Irradiation
Molecular ions
Nanoengineering
Nanostructure
Noble metals
Optical properties
Raman spectra
Selectivity
Silver
Surface properties
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Summary:Ion beam nanoengineering of surfaces is a promising way to tailor the surface properties for a variety of technological applications. One of the unique applications of ion beam methods is to synthesize embedded nanostructures at the nearby surface region of a variety of materials. This is an excellent means of controlling the concentration of dopant elements and their space localization. In addition, it modifies the surface properties without introducing any chemical contamination and affecting the bulk properties of the materials. In recent years, it has emerged as a promising technique for surface modification resulting in improved surface enhanced Raman scattering (SERS) sensitivity and selectivity for molecular detection at an ultralow level in the environment and biomedical research. Ion beam methods such as implantation (Au/Ag ions) and irradiation engineer the surface by synthesizing and tailoring embedded plasmonic nanostructures within the surface region, respectively. In this minireview, the role of low energy ion implantation and irradiation in engineering surfaces of a variety of materials has been discussed for potential applications in the ultrasensitive SERS molecular detection and identification of chemical and biological species. Furthermore, recent results based on noble metal (Au/Ag) ion implantation or irradiation (Ar, Ne, molecular ions, etc. ) induced engineered surfaces with emphasis on tailoring the surface and optical properties for ultrasensitive SERS molecular detection are addressed followed by present challenges and future outlook.
ISSN:2058-9689
2058-9689
DOI:10.1039/D2ME00006G