Metal oxide having a surface onto which a multitude of individual polymers are grafted, each polymer comprising an addition polymer having a first and a second end, and a first moiety comprising a terminal phosphonate group, which first moiety is bonded to the first end, which phosphonate group attaches to the metal oxide surface in such a way that the multitude of the grafted polymers comprises at least one group of adjacent polymers that have a stretched chain conformation wherein the adjacent stretched chains have a substantially parallel orientation, such that the polymers within said group together form a brush structure. Method of grafting a multitude of individual polymers onto a surface of a metal oxide.

The present invention relates to a core-shell nanoparticle comprising (a) an inorganic core comprising a nanoparticle comprising a metal, a metal oxide or combination thereof, and a silica component; (b) a shell material comprising a copolymer having at least two polymers selected from a pH-responsive polymer and a hydrophobic polymer; and (c) a crosslinker that conjugates the shell material to the inorganic core. There is also provided a method for producing the core-shell nanoparticle and uses thereof.

The present invention relates to a core-shell nanoparticle comprising (a) an inorganic core comprising a nanoparticle comprising a metal, a metal oxide or combination thereof, and a silica component; (b) a shell material comprising a copolymer having at least two polymers selected from a pH-responsive polymer and a hydrophobic polymer; and (c) a crosslinker that conjugates the shell material to the inorganic core. There is also provided a method for producing the core-shell nanoparticle and uses thereof.

The present application relates to polymer microparticle-metal nanoparticle composites, to methods of preparing polymer microparticle-metal nanoparticle composites and to uses of such composites. The methods comprise introducing into a microfluidic device, a composition comprising: a cationic metal nanoparticle precursor; a polymer microparticle precursor that comprises a plurality of photopolymerizable groups; and a photoreducer-photoinitiator; then irradiating the composition under conditions to simultaneously reduce the cationic metal and polymerize the photopolymerizable groups to obtain the composite.

Metal oxide having a surface onto which a multitude of individual polymers are grafted, each polymer comprising an addition polymer having a first and a second end, and a first moiety comprising a terminal phosphonate group, which first moiety is bonded to the first end, which phosphonate group attaches to the metal oxide surface in such a way that the multitude of the grafted polymers comprises at least one group of adjacent polymers that have a stretched chain conformation wherein the adjacent stretched chains have a substantially parallel orientation, such that the polymers within said group together form a brush structure. Method of grafting a multitude of individual polymers onto a surface of a metal oxide.

Metal oxide having a surface onto which a multitude of individual polymers are grafted, each polymer comprising an addition polymer having a first and a second end, and a first moiety comprising a terminal phosphonate group, which first moiety is bonded to the first end, which phosphonate group attaches to the metal oxide surface in such a way that the multitude of the grafted polymers comprises at least one group of adjacent polymers that have a stretched chain conformation wherein the adjacent stretched chains have a substantially parallel orientation, such that the polymers within said group together form a brush structure. Method of grafting a multitude of individual polymers onto a surface of a metal oxide.

The present invention relates to a method for preparing a copolymer, comprising adding a surface-modified silica nanopowder, a vinyl cyan-based monomer, and an aromatic vinyl-based monomer and polymerizing the same, wherein the surface-modified silica nanopowder is a silica nanopowder which are surface-modified with a chain transfer agent for reversible addition-fragmentation chain transfer polymerization; a copolymer prepared according to the method; and a thermoplastic resin-molded article manufactured using the copolymer. More particularly, the present invention relates to a method for preparing a copolymer having improved heat shrinkage and reflection haze; a copolymer; and a thermoplastic resin-molded article.

The present invention relates to a method for preparing a copolymer, comprising adding a surface-modified silica nanopowder, a vinyl cyan-based monomer, and an aromatic vinyl-based monomer and polymerizing the same, wherein the surface-modified silica nanopowder is a silica nanopowder which are surface-modified with a chain transfer agent for reversible addition-fragmentation chain transfer polymerization; a copolymer prepared according to the method; and a thermoplastic resin-molded article manufactured using the copolymer. More particularly, the present invention relates to a method for preparing a copolymer having improved heat shrinkage and reflection haze; a copolymer; and a thermoplastic resin-molded article.

Nanostructures and associated compositions, systems, and methods are provided. In some embodiments, a nanostructure may comprise polymers, intermolecular bonding groups, and a particle. The polymers may be associated with the particle and the intermolecular bonding groups may be associated with at least some of the polymers. In some embodiments, at least some of the intermolecular bonding groups may have a different chemical composition and/or chemical property than the polymers. In some embodiments, nanostructures may reversibly associate with each other via the intermolecular bonding groups to form a material. In some such cases, the intermolecular bonding groups on different nanostructures may reversibly associate with each other. In some embodiments, the nanostructures may be designed, such that the energy required to disassociate at least a portion of the nanostructures in the material is greater than the energy required to dissociate a single association between intermolecular bonding groups.

Nanostructures and associated compositions, systems, and methods are provided. In some embodiments, a nanostructure may comprise polymers, intermolecular bonding groups, and a particle. The polymers may be associated with the particle and the intermolecular bonding groups may be associated with at least some of the polymers. In some embodiments, at least some of the intermolecular bonding groups may have a different chemical composition and/or chemical property than the polymers. In some embodiments, nanostructures may reversibly associate with each other via the intermolecular bonding groups to form a material. In some such cases, the intermolecular bonding groups on different nanostructures may reversibly associate with each other. In some embodiments, the nanostructures may be designed, such that the energy required to disassociate at least a portion of the nanostructures in the material is greater than the energy required to dissociate a single association between intermolecular bonding groups.