Formation and thermodynamic stability of a novel class of useful materials: Close-packed monolayers of submicron monodisperse spheres just below a polymer surface

“…Some research groups have used scanning probe microscopy [58,65], X-ray reflectivity [60,61] and X-ray photoelectron spectroscopy [63] to study the embedding of metal NPs in polymers. Some studies highlighted a complete embedding of the metal NPs in the polymeric layers [55,56,61,62], while others analyses highlighted only partial embedding [58]. Such a difference is related to the dependence of the embedding process on the polymer chain mobility: so, partial or no embedding can be expected at temperatures below the polymer glass-transition temperature Tg, while NP complete embedding is observed at temperatures higher than Tg [62].…”

“…So, the Gibbs free energy minimization of the system is the driving force for embedding of metal-NPs in polymers. In particular, the surface Gibbs free energy is effectively reduced by NPs embedding if γm > γp + γMP being γm the metal surface tension, γp the polymer surface tension, and γmp the metal-polymer interfacial tension [55,56]. This condition is, usually, fulfilled for metal NPs on a polymer given the fact that metals have surface energies two orders of magnitude higher than the polymers.…”

“…The metal NPs' embedding process into the polymer layer can be understood on the basis of surface free energy considerations: the Gibbs free energy of a metal NP inside a polymer is lower than that of the NP at the polymer surface [55,56]. So, the Gibbs free energy minimization of the system is the driving force for embedding of metal-NPs in polymers.…”

“…A method, alternative to metals and polymers co-deposition processes, to produce polymer-metal nanocomposite films is based on the embedding phenomenon of metal NPs deposited on the polymers surface [27,30,31,[55][56][57][58][59][60][61][62][63][64][65]. For example, in fact, first the polymer can be spin-coated on a substrate and the thickness of the polymer layer can be controlled by the process parameters (rpm, etc.…”

Metal-Polymer Nanocomposites: (Co-)Evaporation/(Co)Sputtering Approaches and Electrical Properties

“…Some research groups have used scanning probe microscopy [58,65], X-ray reflectivity [60,61] and X-ray photoelectron spectroscopy [63] to study the embedding of metal NPs in polymers. Some studies highlighted a complete embedding of the metal NPs in the polymeric layers [55,56,61,62], while others analyses highlighted only partial embedding [58]. Such a difference is related to the dependence of the embedding process on the polymer chain mobility: so, partial or no embedding can be expected at temperatures below the polymer glass-transition temperature Tg, while NP complete embedding is observed at temperatures higher than Tg [62].…”

“…So, the Gibbs free energy minimization of the system is the driving force for embedding of metal-NPs in polymers. In particular, the surface Gibbs free energy is effectively reduced by NPs embedding if γm > γp + γMP being γm the metal surface tension, γp the polymer surface tension, and γmp the metal-polymer interfacial tension [55,56]. This condition is, usually, fulfilled for metal NPs on a polymer given the fact that metals have surface energies two orders of magnitude higher than the polymers.…”

“…The metal NPs' embedding process into the polymer layer can be understood on the basis of surface free energy considerations: the Gibbs free energy of a metal NP inside a polymer is lower than that of the NP at the polymer surface [55,56]. So, the Gibbs free energy minimization of the system is the driving force for embedding of metal-NPs in polymers.…”

“…A method, alternative to metals and polymers co-deposition processes, to produce polymer-metal nanocomposite films is based on the embedding phenomenon of metal NPs deposited on the polymers surface [27,30,31,[55][56][57][58][59][60][61][62][63][64][65]. For example, in fact, first the polymer can be spin-coated on a substrate and the thickness of the polymer layer can be controlled by the process parameters (rpm, etc.…”

Metal-Polymer Nanocomposites: (Co-)Evaporation/(Co)Sputtering Approaches and Electrical Properties

“…The oxidation of islands causes an irreversible increase in electrical resistance [2]. An interesting sub-surface particulate structure formation was reported when certain inorganic materials are deposited on to softened polymer substrates [3][4][5][6] and the morphology and formation of such structures depend on thermodynamic as well as deposition parameters [6,5]. The use of softened polymer substrats provides the unique possibility of easily controlling the viscosity of the substrate to form a subsurface discontinuous silver particulate films.…”

Silver Particulate Films on Compatible Softened Polymer Composites

Chemistry, diffusion and cluster formation at metal-polymer interfaces