The present disclosure provides a composition comprising: (A) a polypropylene polymer; (B) a polyolefin elastomer; (C) a polymer comprising an acetoacetyl functional group; and (D) a compatibilizer component. The present disclosure also provides an article made from the composition.

A processes and precursor are provided for use in selective laser sintering (SLS) that can create uniform packing densities that create good prints of 3D articles with a decrease in voids and incomplete infill. The resulting articles are electrically conductivity owing to a graphene coating thereby rendering such articles amenable to electroplating, or electrostatic coating processes. The process and precursor provide small diameter filled polymeric materials for 3D printing that are commercially viable to produce an article in a cost effective manner that has superior properties compared to conventional parts owing to reduced void volume and less residual inter-particle stress. The distribution of particles is spherical in shape and have a mean size polydispersity that varies by less than 5% in diameter. As a result of the control of polydispersity, the particles have the attribute of spontaneously forming closed packed arrangements common to crystals.

A processes and precursor are provided for use in selective laser sintering (SLS) that can create uniform packing densities that create good prints of 3D articles with a decrease in voids and incomplete infill. The resulting articles are electrically conductivity owing to a graphene coating thereby rendering such articles amenable to electroplating, or electrostatic coating processes. The process and precursor provide small diameter filled polymeric materials for 3D printing that are commercially viable to produce an article in a cost effective manner that has superior properties compared to conventional parts owing to reduced void volume and less residual inter-particle stress. The distribution of particles is spherical in shape and have a mean size polydispersity that varies by less than 5% in diameter. As a result of the control of polydispersity, the particles have the attribute of spontaneously forming closed packed arrangements common to crystals.

A composite is provided including metal chalcogenide nanotubes as the dispersed phase in a polymeric matrix, in which the polymeric matrix may be a fluoropolymer, urethane (e.g., polyurethane), sulfonic polymer, as well as epoxy and acrylic polymers for adhesive applications, such as pressure sensitive adhesives.

A composite is provided including metal chalcogenide nanotubes as the dispersed phase in a polymeric matrix, in which the polymeric matrix may be a fluoropolymer, urethane (e.g., polyurethane), sulfonic polymer, as well as epoxy and acrylic polymers for adhesive applications, such as pressure sensitive adhesives.

Fibers sized with a coating of amorphous polyetherketoneketone are useful in the preparation of reinforced polymers having improved properties, wherein the amorphous polyetherketoneketone can improve the compatibility of the fibers with the polymeric matrix.

Fibers sized with a coating of amorphous polyetherketoneketone are useful in the preparation of reinforced polymers having improved properties, wherein the amorphous polyetherketoneketone can improve the compatibility of the fibers with the polymeric matrix.

Various embodiments discussed in the present document relate to an implant assembly. The implant assembly includes a porous metal coating. The implant assembly further includes a biocompatible implant material. A polymeric binder layer is disposed between the porous metal coating and the biocompatible implant material.

Various embodiments discussed in the present document relate to an implant assembly. The implant assembly includes a porous metal coating. The implant assembly further includes a biocompatible implant material. A polymeric binder layer is disposed between the porous metal coating and the biocompatible implant material.

A curable composition contains a resin containing a curable group, a colorant, a polymerization inhibitor, and a polymerization initiator. A manufacturing method of the curable composition includes a colorant dispersing step of mixing together the resin containing a curable group, the colorant, and the polymerization inhibitor and a mixing step of mixing together the colorant dispersion and the polymerization initiator so as to obtain the curable composition. A cured film is obtained by curing the curable composition. A color filter, a solid-state imaging element, and an infrared sensor have the cured film. A manufacturing method of the cured film includes a curable composition layer-forming step, an exposure step, and a development step.