Observation of intrinsic chirality of surface plasmon resonances in single nanocrystals

TL;DR

This study experimentally demonstrates intrinsic chirality in surface plasmon resonances of single nanocrystals, revealing spatial dispersion effects at nanometer scales that influence optical properties and symmetry-breaking phenomena.

Contribution

First experimental observation of natural circular dichroism in surface plasmons of spherical nanocrystals caused by spatial dispersion at nanometer dimensions.

Findings

Surface plasmons exhibit negative ellipticity and phase-shift, indicating optical left-handedness.

Quadrupolar plasmons show positive ellipticity and phase-shift, indicating right-handedness.

Structural and electronic factors like assembly, shape, and spin polarization affect optical chirality.

Abstract

Surface plasmons in a centrosymmetric metal nanocrystal have been perceived as achiral, based on the quantum-mechanical theory of molecular optical activity. The one-electron theory is insufficient to describe optical activity in crystals, where spatial variation of polarization states along the light propagation direction is crucial in dimensions exceeding molecules. Such spatial-dispersion, which can drastically modify the optical near-field in plasmonic nanocrystals, has yet to be experimentally proved at the nanometer scale. Here, the experimental observation of natural circular dichroism of surface plasmons in spherical gold, silver, and copper nanocrystals in solution is presented. It originates from spatial dispersion (nonlocality) occurred at a dimension as small as 5 nanometers in the optical region. In particular, the electromagnetic pressure or longitudinal volume plasmons result in phase-shift and polarization rotation of the transverse electric field of incident light. Dipolar surface plasmons exhibit negative ellipticity and corresponding negative phase-shift of the electric field (i.e., optically left-handed), whereas quadrupolar surface plasmons have positive signs in both ellipticity and phase-shift (i.e., optically right-handed). Structural effects such as nanocrystal assembly, nanocrystal shape, electron spin-polarization, and plasmon-molecule interaction are accessed. Volume plasmons inside the nanocrystal also produce a positive rotational strength for the interband transition. This study implicates optical symmetry-breaking in isotropic nanocrystals by the axial polarization parallel to the wavevector, which will impact on conduction electron dynamics, hot-electron generation, and nonlinear optical response at the surface of plasmonic nanocrystals as well as optical excitation of bound d-band electrons.