Aluminum and phosphorene based ultrasensitive SPR biosensor

In order to designing an ultrasensitive biosensor with high detection accuracy, a bimetallic (Al/Au) structure is proposed. Further sensitivity enhancement is obtained by applying Si nanosheet and some 2D materials. Few-layer phosphorene, graphene and tungsten disulfide are selected to enhance the a...

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Bibliographic Details
Published in:Optical materials 2018-12, Vol.86, p.119-125
Main Authors: Meshginqalam, Bahar, Barvestani, Jamal
Format: Article
Language:English
Subjects:
Biosensor
Graphene
Phosphorene
Sensitivity
Surface plasmon resonance
Tungsten disulfide
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Summary:In order to designing an ultrasensitive biosensor with high detection accuracy, a bimetallic (Al/Au) structure is proposed. Further sensitivity enhancement is obtained by applying Si nanosheet and some 2D materials. Few-layer phosphorene, graphene and tungsten disulfide are selected to enhance the angular sensitivity of the biosensor. Different coupling prisms are examined due to obtaining the best response. Considering the achievable highest sensitivity together with smallest minimum reflectance values, the optimized number of layers for each material is selected. Finally, 258% sensitivity enhancement with 3 nm Au, 7 nm Si and 5 layers of phosphorene on Al surface is obtained compared with bare Al-based SPR biosensor. •A bimetallic (Al/Au) structure based ultrasensitive SPR biosensor with high detection accuracy is proposed.•Angular sensitivity of the biosensor is enhanced using few-layer BP, graphene and WS2 layers over the bimetallic layer.•Optimized number of layers for each 2D material is reported considering the highest S together with smallest Rmin values.•258% sensitivity enhancement with 3nm Au, 7nm Si and 5 layers of phosphorene on Al/Au surface is obtained.
ISSN:0925-3467
1873-1252
DOI:10.1016/j.optmat.2018.10.003