Optical response of single silver nano-objects : plasmonic coupling and photo-oxidation

La réponse optique de nanostructures métalliques est caractérisée par une amplification locale du champ électromagnétique appelée Résonance Plasmon de Surface (RPS) reliée à leur nature et leur morphologie. Pour étudier la réponse optique d’une nanoparticule unique, un dispositif ultra-sensible de spectroscopie à modulation spatiale utilisant une source de lumière blanche a été développé : il permet de mesurer la section efficace d’extinction absolue de nano-objets uniques sur un large domaine spectral (300-900 nm). Des images de microscopie électronique à transmission peuvent être obtenues indépendamment sur les mêmes objets. On a ainsi une corrélation directe entre la morphologie des nanoparticules et leur signature optique. Ce travail de thèse a permis d’une part de mettre en évidence les paramètres qui entrent en jeu dans le processus de vieillissement de nanoparticules uniques d’argent sous éclairement. En particulier, l’étude de nanocubes d’argent révèle une « sphérisation » et une photo-oxydation au cours du temps due à la partie UV du spectre. D’autre part, des mesures réalisées sur des doublets de nanocubes d’argent en interaction ont montré l’importance de la morphologie à l’interface entre les deux nanoparticules sur le couplage plasmonique. Pour une excitation lumineuse longitudinale, on observe, outre le décalage de la RPS vers les basses énergies lorsque la distance interparticule diminue, un dédoublement de cette bande de résonance. Des calculs théoriques réalisés avec la méthode DDA ont permis de corréler ce phénomène de dédoublement à des variations de courbure de surface dans la zone interparticule liées principalement au rognage des arêtes des cubesThe optical properties of noble metal nanoparticles are known to be dominated by the localized surface plasmon resonance (SPR) which is highly sensitive to the size of the particles, their shape, their environment, and eventually their chemical composition in the case of mixed systems. In order to study the optical response of a single supported metallic nanoparticle, a high sensitive spectroscopic setup using a white lamp (300-900 nm) has been developed in a transmission measurement configuration. This technique, the Spatial Modulation Spectroscopy, aims to detect the overall extinction of light by a nanoparticle. Moreover, the coupling of this technique with the direct observation of the particles by Transmission Electron Microscopy allows to get an unambiguous description of their optical response in relation with their exact morphology. In this work, the optical response of single silver nano-objects has been correlated with their morphology and their structure at a sub-nanometer scale. Time evolution of the optical response of single silver nanocubes under illumination was first investigated. We observed a “spherization” and a photo-oxidation due to the UV part of the light. Moreover, we studied pairs of cubic silver nanoantennas that showed a huge sensitivity of their optical response with the interparticle distance and their morphology. Indeed, the SPR is red-shifted with decreasing interparticle distance. One can also observe a striking splitting of the resonance for very low interparticle distances. Preliminary DDA calculations seem to show that the radius of curvature at the corners and edges of both cubes plays a key role in the splitting of the resonanc

Réponse optique de nano-objets uniques d’argent : couplage plasmonique et photo-oxydation

The optical properties of noble metal nanoparticles are known to be dominated by the localized surface plasmon resonance (SPR) which is highly sensitive to the size of the particles, their shape, their environment, and eventually their chemical composition in the case of mixed systems. In order to study the optical response of a single supported metallic nanoparticle, a high sensitive spectroscopic setup using a white lamp (300-900 nm) has been developed in a transmission measurement configuration. This technique, the Spatial Modulation Spectroscopy, aims to detect the overall extinction of light by a nanoparticle. Moreover, the coupling of this technique with the direct observation of the particles by Transmission Electron Microscopy allows to get an unambiguous description of their optical response in relation with their exact morphology. In this work, the optical response of single silver nano-objects has been correlated with their morphology and their structure at a sub-nanometer scale. Time evolution of the optical response of single silver nanocubes under illumination was first investigated. We observed a “spherization” and a photo-oxidation due to the UV part of the light. Moreover, we studied pairs of cubic silver nanoantennas that showed a huge sensitivity of their optical response with the interparticle distance and their morphology. Indeed, the SPR is red-shifted with decreasing interparticle distance. One can also observe a striking splitting of the resonance for very low interparticle distances. Preliminary DDA calculations seem to show that the radius of curvature at the corners and edges of both cubes plays a key role in the splitting of the resonanceLa réponse optique de nanostructures métalliques est caractérisée par une amplification locale du champ électromagnétique appelée Résonance Plasmon de Surface (RPS) reliée à leur nature et leur morphologie. Pour étudier la réponse optique d’une nanoparticule unique, un dispositif ultra-sensible de spectroscopie à modulation spatiale utilisant une source de lumière blanche a été développé : il permet de mesurer la section efficace d’extinction absolue de nano-objets uniques sur un large domaine spectral (300-900 nm). Des images de microscopie électronique à transmission peuvent être obtenues indépendamment sur les mêmes objets. On a ainsi une corrélation directe entre la morphologie des nanoparticules et leur signature optique. Ce travail de thèse a permis d’une part de mettre en évidence les paramètres qui entrent en jeu dans le processus de vieillissement de nanoparticules uniques d’argent sous éclairement. En particulier, l’étude de nanocubes d’argent révèle une « sphérisation » et une photo-oxydation au cours du temps due à la partie UV du spectre. D’autre part, des mesures réalisées sur des doublets de nanocubes d’argent en interaction ont montré l’importance de la morphologie à l’interface entre les deux nanoparticules sur le couplage plasmonique. Pour une excitation lumineuse longitudinale, on observe, outre le décalage de la RPS vers les basses énergies lorsque la distance interparticule diminue, un dédoublement de cette bande de résonance. Des calculs théoriques réalisés avec la méthode DDA ont permis de corréler ce phénomène de dédoublement à des variations de courbure de surface dans la zone interparticule liées principalement au rognage des arêtes des cube

Plasmon Coupling in Silver Nanocube Dimers : Resonance Splitting Induced by Edge Rounding

International audienceAbsolute extinction cross sections of individual silver nanocube dimers are measured using spatial modulation spectroscopy in correlation with their transmission electron microscopy images. For very small interparticle distances and an incident light polarized along the dimer axis, we give evidence for a clear splitting of the main dipolar surface plasmon resonance which is found to be essentially induced by cube edge rounding effects. Supported by discrete dipole approximation and finite element method calculations, this phenomenon highlights the high sensitivity of the plasmonic coupling to the exact shape of the effective capacitor formed by the facing surfaces of both particles, especially in the regime of very close proximity

Photo-Oxidation of Individual Silver Nanoparticles: A Real-Time Tracking of Optical and Morphological Changes

Absolute extinction measurements on individual silver nanoparticles under illumination show a steady evolution of their localized surface plasmon resonance. Their progressive transformation during light exposure and the influence of various parameters such as the nature of stabilizers, the local environment (oxygen rate), the spectral range of the incident light, and the shape of the nanoparticle (spheres or nanocubes) have been carefully investigated in correlation with transmission electron microscopy imaging. A combination of optics and electron microscopy gives evidence that photoaging mainly consists of the progressive formation of an oxide shell around a metallic silver core during light illumination. Moreover, in the case of nanocubes, the metallic core not only decreases in volume but also changes morphologically since edges and corners are rounded off during the photo-oxidation process. The generalized Mie theory and finite element method, used to calculate the optical extinction cross-section of core/shell Ag@Ag_<i>x</i>O nanoparticles, well account for the observed time evolutions of the absolute extinction spectra of the silver nanospheres and nanocubes. Furthermore, the calculated electromagnetic field at the nanocube surface, enhanced on edges and corners, can explain the higher efficiency of the photo-oxidation on edges and corners and the rounding increase under illumination