# Determinant role of size-dependent electron relaxation processes in the   nonlinear luminescence emission of resonantly excited gold nanorods

**Authors:** C\'eline Molinaro, Sylvie Marguet, Ludovic Douillard, Fabrice Charra,, C\'eline Fiorini-Debuisschert

arXiv: 1908.00859 · 2019-08-05

## TL;DR

This study investigates how size-dependent electron relaxation processes influence the nonlinear luminescence of gold nanorods, revealing optimal sizes for maximum two-photon luminescence and proposing a comprehensive model including local field effects and electron thermalization.

## Contribution

It introduces a detailed model that combines local field enhancement and size-dependent electron thermalization to explain nonlinear luminescence in gold nanorods, supported by experimental data and simulations.

## Key findings

- Maximum TPL signal at nanorod diameter around 10 nm.
- Non-monotonic TPL variation with size, highlighting optimal dimensions.
- Good agreement between experimental data and the proposed model.

## Abstract

The two-photon luminescence (TPL) of gold nanoparticles (NP) was shown to result from the excitation of hot carriers, the plasmonic NP resonances playing an important role both for plasmon enhanced absorption and plasmon enhanced emission. However, the exact parameters enabling to control or optimize the NP nonlinear luminescence still need to be understood in detail. In this paper, we report the two-photon excited photoluminescence of single gold nanorods exhibiting identical aspect ratio (close to 4) and thus identical plasmonic resonances, but increasing volumes V (707 <V< 160 103 nm3 i.e. rod diameters varying between 6 and 40 nm). The two-photon luminescence intensity of a high number of colloidal nanorods was investigated at the single object level, combining polarization resolved TPL and simultaneously acquired topography. Non-monotonic TPL variations are evidenced, nanorods with an intermediate size (diameter around 10 nanometers) exhibiting the highest TPL signal intensity. A model is proposed considering both the local field enhancement effects at the NP and the size-dependent electron thermalization processes. BEM (Boundary Elements Method) simulations are used to compute the fields at both the transverse and longitudinal plasmon resonance. A good fitting of the experimental data is obtained considering integration of the fields over the whole the NP volume.

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Source: https://tomesphere.com/paper/1908.00859