A method of forming a titania-coated inorganic particle comprising the steps of: (a) agitating a mixture of inorganic particle and organic solvent; (b) adding titania precursor dropwise into the mixture of step (a) under agitation; and (c) adding catalyst to the mixture of step (b) thereby converting said titania precursor to titania which then forms a coating on said inorganic particle; wherein steps (a) to (c) are performed at neutral pH and ambient temperature.

A composition including a first color shifting pigment flake population having a first D50 particle size; and a second color shifting pigment flake population having a second D50 particle size that is different from the first D50 particle size, wherein the first color shifting pigment flake population and the second color shifting pigment flake population have a similar face color and color shift is disclosed. An article including the composition is included. A method of making the composition and a method of making the article are also disclosed.

The invention relates to a method for preparing colored materials by heterogeneous nucleation of metallic nanoparticles, said nanoparticles exhibiting optical properties based on the surface plasmon phenomenon. The invention also relates to said colored materials obtained, as well as compositions comprising them. In particular, the method for preparing colored particulate material by heterogeneous nucleation notably comprises mixing a suspension at room temperature comprising: at least one salt of a metallic element, said metallic element exhibiting a plasmonic effect, at least one reducing agent, and at least one particulate substrate, said suspension mixture forming a colored particulate material.

A pigment flake may comprise a multilayer optical structure. The multilayer optical structure may have a first surface with a first modulation that corresponds to a relief of a diffraction grating. The multilayer optical structure may have a second surface having a second modulation, with the second surface being opposite from the first surface and the second modulation being smaller than the first modulation such that the second surface is comparatively flatter than the first surface. The multilayer optical structure may exhibit diffraction colors for a first range of angles of the multilayer optical structure with respect to an angle of incident light, and may exhibit an interference color for a second range of angles of the multilayer optical structure with respect to the angle of the incident light.

A composition including a first color shifting pigment flake population having a first D50 particle size; and a second color shifting pigment flake population having a second D50 particle size that is different from the first D50 particle size, wherein the first color shifting pigment flake population and the second color shifting pigment flake population have a similar face color and color shift is disclosed. An article including the composition is included. A method of making the composition and a method of making the article are also disclosed.

A composite comprising a polymeric matrix and EM absorbers dispersed within the polymeric matrix. Each EM absorber comprises a dielectric flake, and a continuous magnetic coating on at least one major surface of the dielectric flake. The EM absorbers function as dielectric and magnetic absorbers in the 1-100 GHz frequency range. The composite can be used as an electromagnetic shielding article to mitigate electromagnetic interference in, for example, high speed, high frequency (HSHF) consumer electronics.