The present invention relates to a technology for producing a black pearlescent pigment for cosmetics which is a human-friendly and nature-friendly by using a pigment including natural charcoal powder. The production method of the pearlescent pigment using natural charcoal according to the present invention includes (a) milling natural charcoal to produce a pigment including natural charcoal powder; and (b) coating a flake substrate with the produced pigment including the natural charcoal powder, wherein the milling is performed at 20 to 40 Hz for 24 to 72 hours, and an average particle size of the pigment including the natural charcoal powder is 100 to 300 nm.

This invention deals with effect pigment mixture comprising platelet-like aluminum effect pigments obtained by grinding of aluminum or aluminum based alloy shot and silvery pearlescent pigments, wherein the silvery pearlescent pigments are taken from the group consisting of: a) pearlescent pigments comprising a transparent substrate which is coated with a high-refractive index layer with n>1.8, which comprises or consists of an iron-oxide with Fe(II)-ions, b) pearlescent pigments comprising a transparent substrate which is coated with a high-refractive index layer with n>1.8, which comprises or consists of titanium suboxide or a pearlescent pigment comprising a substrate with a high-refractive index with n>1.8 layer, which comprises or consists of a titanium suboxide that is optionally coated with a high-refractive index layer with n>1.8, c) pearlescent pigments comprising a transparent substrate which is coated with a high-refractive index layer with n>1.8, which comprises or consists of titanium oxynitride, d) pearlescent pigments comprising a transparent substrate which is coated with a layer comprising carbon, wherein the carbon is enclosed in a particulate form in another metal oxide layer or is formed as a separate, individual layer, e) a transparent substrate coated with a first layer comprising or consisting of a mixture of the oxides of titanium, iron and at least one of cobalt and chromium and a second layer on the first layer, wherein the second layer comprises an oxide of titanium, and mixtures or combinations of the pearlescent pigments a) to e) or pearlescent pigments with mixtures or combinations of the various coating layers mentioned in the pearlescent pigments a) to e), wherein the weight ratio of the pearlescent pigment to the aluminum effect pigment is in a range of 0.4 to 5.0. The invention deals also with a coating formulation containing this effect pigment mixture.

An encapsulated palette flake includes a palette flake having a first surface and a second surface, and a layer on at least one of the first surface and the second surface. A blackness My of the encapsulated palette flake is greater than or equal to 110 and less than or equal to 140. A reflectivity of the encapsulated palette flake in a visible spectrum of electromagnetic radiation that is less than or equal to 10.0%. A reflectivity of the encapsulated palette flake in a near-IR and LiDAR spectrum of electromagnetic radiation that is between 10% and 90%. A method for forming an encapsulated palette flake includes combining a base solution comprising palette flakes and a precipitating agent with a solution comprising a copper source, drying the precipitate, and calcining the dried precipitate. The precipitating agent is selected from sodium hydroxide, sodium carbonate, or ammonium carbonate.

The present invention is directed to a display fluid comprising charged composite color particles dispersed in a solvent. The composite color particle comprises core particles which are at least one color core particle and at least one core particle having a high refractive index, a shell in which the color core particles and the high refractive index core particles are completely or partially embedded, and steric stabilizer molecules on the surface of the composite color particle. A display fluid comprising the composite color particles of the present invention provides improved optical performance.

The invention relates to pearlescent pigments comprising a largely transparent platelet-shaped synthetic substrate having a density ?.sub.S and at least one optically active coating having a density ?.sub.M, the substrate having an average size d.sub.50 from a range from 2.0 ?m to 8.0 ?m and an average height h.sub.S from a range from 40 nm to 110 nm and the total lead content of the pearlescent pigments is ?10 ppm. The invention further relates to a method for producing the pearlescent pigments, and also to the use thereof.

A pigment including a pre-flake; and a coating of nanoparticles present on a surface of the pre-flake, wherein the nanoparticles can be present in the coating in an amount greater than about 40% by volume is disclosed. A method of making a pigment is also disclosed.

The present invention relates to a process for colouring surfaces, in particular surfaces of foods, with effect pigments, preferably pearlescent pigments, based on flake-form substrates, where (i) the effect pigment is incorporated into a pasty, transparent, water-based material and (ii) the application medium prepared in step (i) is applied to the surface.

A process for the preparation and colouring of pulverulent foods which is distinguished by the fact that uncoloured pulverulent foods are mixed with effect pigments based on flake-form substrates.

The present invention relates to pearlescent pigments, to a process of manufacturing such pearlescent pigments based on a wet oxidation step as well as to the use of such pearlescent pigments.

The present invention relates to semitransparent pearlescent pigments, to processes for producing them, and to the use of such pearlescent pigments, where the pearlescent pigments comprise monolithically constructed substrate platelets composed of a metal oxide having an average thickness of 1 to 40 nm and a form factor, expressed by the ratio of the mean size to the average thickness, of at least 80, which are enveloped by at least one substantially transparent coating A composed of at least one low-index metal oxide and/or metal oxide hydrate, having a refractive index of less than 1.8, and at least one interference layer in the form of a coating B composed of at least one high-index metal oxide, having a refractive index of at least 1.8.