Abstract
In this work, we introduce a new perspective on the development of Localized Surface Plasmon Resonance (LSPR) optical biosensors. Computational simulations, focused on the assessment of the LSPR spectrum and spatial distribution of the electromagnetic field enhancement near a metallic nanoparticle, elucidated the behavior of crucial parameters, as figure of merit, bulk and molecular sensitivity, which governs a LSPR sensor performance. Gold and silver nanospheres were explored as starting point to assess plasmonic optical characteristics of the nanostructured sensor platform. Here, for the first time in the literature, Campbell’s model was evaluated exploiting a NP size-dependence approach. The theoretical analyses indicate a nonlinear behavior of the bulk and molecular sensitivity as function of the NP size. Substantial LSPR peak shifts due to the adsorption of molecules layer on a NP surface were observed for nanoparticles with ~5 nm and ~40 nm radius. Moreover, on molecular sensing, LSPR peak shift is also determined by the thickness of adsorbed molecular shell layers. We observed that for 40 nm radius gold and silver nanospheres, significant LSPR peak shift could be induced by small (few nm) thickness change of the adsorbate shell layer. Moreover, this work provides insights on the LSPR behavior due to adsorption of molecular layer on a NP surface, establishing a new paradigm on engineering LSPR biosensor. Furthermore, the proposed approach can be extended to engineer an efficiently use of different nanostructures on molecular sensing.
Highlights
IntroductionE. de Araujo pendent absorption, scattering and robust local electric field enhancement
We observed that for 40 nm radius gold and silver nanospheres, significant Localized Surface Plasmon Resonance (LSPR) peak shift could be induced by small thickness change of the adsorbate shell layer
The establishment of high performance LSPR biosensor requires the description of sensing parameters as function of the nanoparticle structure
Summary
E. de Araujo pendent absorption, scattering and robust local electric field enhancement. These extraordinary optical characteristics of small particles have led to remarkable interest into their potential applications as nanoscale elements in diverse range of technologies. These optical characteristics are governed due to collective coherent oscillations of free electrons, known as localized surface plasmon resonance (LSPR) [1]. The spectrum of LSPR excitations have been the subject of intensive research efforts and encourage researchers to synthesize the growth of complex shapes nanostructures such as nanoshells [3], nanorice [4], nanocages [5], nanostars [6], nanorods [7] and nanopyramids [8], which shows plasmon peaks in various spectral regions. Spherical nanostructures provide a starting point to evaluate plasmonic optical characteristics of metals
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