Point Group Symmetry Analysis of the Electronic Structure of Bare and Protected Metal Nanocrystals

TL;DR

This paper introduces a point group symmetry analysis method for electronic structures of metal nanocrystals, revealing core shape effects and enabling computational savings in optical property calculations.

Contribution

It presents a symmetry analysis approach that surpasses traditional spherical models, applicable to non-spherical nanocrystals and ligand-protected clusters, improving understanding and computational efficiency.

Findings

Symmetry analysis correlates electronic states with core shape.

Method reduces computational time for optical spectra calculations.

Applicable to non-spherical, atomically ordered nanocrystals.

Abstract

The electronic structures of a variety of experimentally identified gold and silver nanoclusters from 20 to 246 atoms, either unprotected or protected by several types of ligands, are characterized by using point group specific symmetry analysis. The delocalized electron states around the HOMO-LUMO energy gap, originating from the metal s-electrons in the cluster core, show symmetry characteristics according to the point group that describes best the atomic arrangement of the core. This indicates strong effects of the lattice structure and overall shape of the metal core to the electronic structure, which cannot be captured by the conventional analysis based on identification of spherical angular momentum shells in the superatom model. The symmetry analysis discussed in this paper is free from any restrictions regarding shape or structure of the metal core, and is shown to be superior to the conventional spherical harmonics analysis for any symmetry that is lower than Ih. As an immediate application, we also demonstrate that it is possible to reach considerable savings in computational time by using the symmetry information inside a conventional linear-response calculation for the optical absorption spectrum of the Ag55 cluster anion, without any loss in accuracy of the computed spectrum. Our work demonstrates an efficient way to analyze the electronic structure of non-spherical, but atomically ordered nanocrystals and ligand-protected clusters with nanocrystal metal cores and it can be viewed as the generalization of the superatom model demonstrated for spherical shapes ten years ago (Walter et al., PNAS 2008, 105, 9157).