Your search keyword '"Paolo Pengo"' showing total 2 results

1. Spotting Local Environments in Self-Assembled Monolayer-Protected Gold Nanoparticles

Author

Cristian Gabellini, Maria Şologan, Elena Pellizzoni, Domenico Marson, Mario Daka, Paola Franchi, Luca Bignardi, Stefano Franchi, Zbyšek Posel, Alessandro Baraldi, Paolo Pengo, Marco Lucarini, Lucia Pasquato, Paola Posocco, Gabellini, Cristian, Sologan, Maria, Pellizzoni, Elena, Marson, Domenico, Daka, Mario, Franchi, Paola, Bignardi, Luca, Franchi, Stefano, Posel, Zbyšek, Baraldi, Alessandro, Pengo, Paolo, Lucarini, Marco, Pasquato, Lucia, and Posocco, Paola

Subjects

machine-learning, mixed monolayers, General Engineering, General Physics and Astronomy, fluorinated nanoparticles, ESR, multiscale modeling, SOAP, nanoconfinement, mixed monolayer, General Materials Science, fluorinated nanoparticle

Abstract

Organic-inorganic (O-I) nanomaterials are versatile platforms for an incredible high number of applications, ranging from heterogeneous catalysis, molecular sensing, cell targeting, imaging, cancer diagnosis and therapy, just to name a few. Much of their potential stems from the unique control of organic environments around inorganic sites within a single O-I nanomaterial, which allows for new properties inaccessible using purely organic or inorganic materials. Structural and mechanistic characterization plays a key role in understanding and rationally designing such hybrid nanoconstructs. Here, we introduce a general methodology to identify and classify local (supra)molecular environments in an archetypal class of O-I nanomaterials, i.e. self-assembled monolayer-protected gold nanoparticles (SAM-AuNPs). By using an atomistic machine-learning guided workflow based on the Smooth Overlap of Atomic Positions (SOAP) descriptor, we analyze a collection of chemically different SAM-AuNPs, and detect and compare local environments in a way that is agnostic and automated, i.e. with no need of a-priori information and minimal user intervention. In addition, the computational results coupled with experimental electron spin resonance measurements prove that is possible to have more than one local environment inside SAMs, being thickness of the organic shell and solvation primary factors in determining number and nature of multiple co-existing environments. These indications are extended to complex mixed hydrophilic-hydrophobic SAMs. This work demonstrates that it is possible to spot out and compare local molecular environments in SAM-AuNPs exploiting atomistic machine-learning approaches, establishes ground rules to control them, and holds the potential for rational design of O-I nanomaterials instructed from data.

Published

2022

2. Patchy and Janus Nanoparticles by Self-Organization of Mixtures of Fluorinated and Hydrogenated Alkanethiolates on the Surface of a Gold Core

Author

Maria Şologan, Domenico Marson, Sabrina Pricl, Lucia Pasquato, Paola Posocco, Stefano Polizzi, Paolo Pengo, Silvia Boccardo, Sologan, Maria, Marson, Domenico, Polizzi, Stefano, Pengo, Paolo, Boccardo, Silvia, Pricl, Sabrina, Posocco, Paola, and Pasquato, Lucia

Subjects

Surface (mathematics), anisotropic nanoparticles, gold nanoparticles, multiscale molecular modeling, NMR, phase segregation, self-assembly, Materials Science (all), Engineering (all), Physics and Astronomy (all), Materials science, General Physics and Astronomy, Nanotechnology, 02 engineering and technology, Fluorine-19 NMR, 010402 general chemistry, 01 natural sciences, anisotropic nanoparticle, Phase (matter), Monolayer, General Materials Science, Anisotropy, Settore CHIM/02 - Chimica Fisica, Self-organization, Ligand, General Engineering, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Colloidal gold, 0210 nano-technology, gold nanoparticle

Abstract

The spontaneous self-organization of dissimilar ligands on the surface of metal nanoparticles is a very appealing approach to obtain anisotropic "spherical" systems. In addition to differences in ligand length and end groups, a further thermodynamic driving force to control the self-assembled monolayer organization may become available if the ligands are inherently immiscible, as is the case of hydrogenated (H-) and fluorinated (F-) species. Here, we validate the viability of this approach by combining (19)F NMR experiments and multiscale molecular simulations on large sets of mixed-monolayer-protected gold nanoparticles (NPs). The phase segregation of blends of F- and H-thiolates grafted on the surface of gold NPs allows a straightforward approach to patterned mixed monolayers, with the shapes of the monolayer domains being encoded in the structure of the F/H-thiolate ligands. The results obtained from this comprehensive study offer molecular design rules to achieve a precise control of inorganic nanoparticles protected by specifically patterned monolayers.

Published

2016