Mueller matrix polarimetry of plasmon resonant silver nano-rods: biomedical prospects

TL;DR

This study uses Mueller-matrix polarimetry combined with T-matrix calculations to analyze the polarization properties of silver nano-rods, revealing tunable resonances and high sensitivity for potential biomedical sensing and imaging applications.

Contribution

It introduces a novel combination of Mueller-matrix polarimetry with T-matrix approach to study polarization in nano-rods, demonstrating unprecedented control and sensitivity to local refractive index changes.

Findings

Identification of longitudinal and transverse plasmon resonances.

Spectral and amplitude tunability of diattenuation and retardance.

High sensitivity of diattenuation dips for medium characterization.

Abstract

Fundamental understanding of the light-matter interaction in the context of nano-particles is immensely bene- fited by the study of geometry dependent tunable Localized Surface Plasmon Resonance (LSPR) and has been demonstrated to have potential applications in various areas of science. The polarization characteristics of LSPR in addition to spectroscopic tuning can be suitably exploited in such systems as contrast enhancement mech- anisms and control parameters. Such polarization characteristics like diattenuation and retardance have been studied here using a novel combination of Muller-matrix polarimetry with the T-matrix matrix approach for silver nano-rods to show unprecedented control and sensitivity to local refractive index variations. The study carried out over various aspect ratios for a constant equal volume sphere radius shows the presence of longitu- dinal (dipolar and quadrupolar) and transverse (dipolar) resonances; arising due to differential contribution of polarizabilities in two directions. The overlap regions of these resonances and the resonances themselves exhibit enhanced retardance and diattenuation respectively. The spectral and amplitude tunability of these polarimetric parameters through the aspect ratios to span from the minimum to maximum ([0, 1] in the case of diattenuation and [0, {\pi}] in the case of retardance) presents a novel result that could be used to tailor systems for study of biological media. On the other hand, the high sensitivity of diattenuation dip (caused by equal contribution of polarizabilities) could be possibly used for medium characterization and bio-sensing or bio-imaging studies.