A resin composition includes a cellulose derivative of which a weight average molecular weight is 10,000 or greater and less than 75,000 and in which at least one hydroxyl group is substituted with an acyl group having 1 to 6 carbon atoms.

The present invention provides a method for producing resin beads which can provide various types of products, such as cosmetics, imparted with superior tactile impression, spreadability on the skin, transparency, and product stability, and which can be substituted for resin particles composed of a synthetic material derived from petroleum. The method is a method for producing resin beads containing a cellulose derivative as a main component. The production method includes: a suspension preparation step of mixing an oil phase containing the cellulose derivative and an organic solvent that dissolves the cellulose derivative, the organic solvent having a water-solubility of 0.1 to 50.0 g, and an aqueous phase containing a dispersion stabilizer, thereby preparing a suspension containing oil droplets containing the cellulose derivative and the organic solvent; and an oil droplet contraction step of adding water to the suspension, thereby contracting the oil droplets, wherein the water is added to the suspension in such a way as to satisfy the following expression (A) until a content of the organic solvent in the suspension becomes equal to or less than the water-solubility of the organic solvent.

(W/S)/T≤1.00  (A), wherein

W: an addition amount of water (parts by mass),

S: an amount of the suspension (parts by mass), and

T: a time (minutes) required for addition.

The present invention provides a method for producing resin beads which can provide various types of products, such as cosmetics, imparted with superior tactile impression, spreadability on the skin, transparency, and product stability, and which can be substituted for resin particles composed of a synthetic material derived from petroleum. The method is a method for producing resin beads containing a cellulose derivative as a main component. The production method includes: a suspension preparation step of mixing an oil phase containing the cellulose derivative and an organic solvent that dissolves the cellulose derivative, the organic solvent having a water-solubility of 0.1 to 50.0 g, and an aqueous phase containing a dispersion stabilizer, thereby preparing a suspension containing oil droplets containing the cellulose derivative and the organic solvent; and an oil droplet contraction step of adding water to the suspension, thereby contracting the oil droplets, wherein the water is added to the suspension in such a way as to satisfy the following expression (A) until a content of the organic solvent in the suspension becomes equal to or less than the water-solubility of the organic solvent.

(W/S)/T≤1.00  (A), wherein

W: an addition amount of water (parts by mass),

S: an amount of the suspension (parts by mass), and

T: a time (minutes) required for addition.

Provided is an optical film containing a cellulose derivative, the optical film having an in-plane retardation Ro.sub.550 within the range of 120 to 160 nm measured at a wavelength of 550 nm under an atmosphere of a temperature of 23° C. and a relative humidity of 55%, and a ratio Ro.sub.450/Ro.sub.550 within the range of 0.65 to 0.99, Ro.sub.450/Ro.sub.550 being a ratio of an in-plane retardation Ro.sub.450 measured at a wavelength of 450 nm to the in-plane retardation Ro.sub.550 measured at a wavelength of 550 nm, wherein, a substituent of a glucose skeleton in the cellulose derivative satisfies the requirements (a) and (b) which are described in the specification, and the optical film contains a compound A satisfying the following condition defined by Expression (a1) which is described in the specification.

Provided is an optical film containing a cellulose derivative, the optical film having an in-plane retardation Ro.sub.550 within the range of 120 to 160 nm measured at a wavelength of 550 nm under an atmosphere of a temperature of 23° C. and a relative humidity of 55%, and a ratio Ro.sub.450/Ro.sub.550 within the range of 0.65 to 0.99, Ro.sub.450/Ro.sub.550 being a ratio of an in-plane retardation Ro.sub.450 measured at a wavelength of 450 nm to the in-plane retardation Ro.sub.550 measured at a wavelength of 550 nm, wherein, a substituent of a glucose skeleton in the cellulose derivative satisfies the requirements (a) and (b) which are described in the specification, and the optical film contains a compound A satisfying the following condition defined by Expression (a1) which is described in the specification.

An organic peroxide formulation includes at least one organic peroxide and at least one cellulose compound. Embodiments of the organic peroxide formulations significant improvements in surface tackiness (often including but not limited to tack-free surfaces) when curing elastomers in the presence of oxygen. Embodiments of the present invention relate to organic peroxide formulations that can cure solid elastomers in the full or partial presence of oxygen using, for example, a hot air oven or tunnel, molten salt bath, or steam autoclave. Embodiments of the invention also relate to crosslinkable elastomer compositions, processes for curing the elastomers, and products made by such processes.

An organic peroxide formulation includes at least one organic peroxide and at least one cellulose compound. Embodiments of the organic peroxide formulations significant improvements in surface tackiness (often including but not limited to tack-free surfaces) when curing elastomers in the presence of oxygen. Embodiments of the present invention relate to organic peroxide formulations that can cure solid elastomers in the full or partial presence of oxygen using, for example, a hot air oven or tunnel, molten salt bath, or steam autoclave. Embodiments of the invention also relate to crosslinkable elastomer compositions, processes for curing the elastomers, and products made by such processes.

A conductive paste obtained by adding an organic solvent B to a vehicle containing a Ni powder, a binder resin component, and an organic solvent A. The Ni powder has an average primary particle size of 30 to 400 nm. The binder resin component is cellulose acetate butyrate. Organic solvent A is a solvent having a Δ δ value of 11.5 or less with the cellulose acetate butyrate. Organic solvent B is a solvent having a Δ δ value from 11.5 to 25.0 with the cellulose acetate butyrate. A ratio of the organic solvent B relative to a total of the organic solvent A and the organic solvent B is 5.0 to 40.0 wt %.

A conductive paste obtained by adding an organic solvent B to a vehicle containing a Ni powder, a binder resin component, and an organic solvent A. The Ni powder has an average primary particle size of 30 to 400 nm. The binder resin component is cellulose acetate butyrate. Organic solvent A is a solvent having a Δ δ value of 11.5 or less with the cellulose acetate butyrate. Organic solvent B is a solvent having a Δ δ value from 11.5 to 25.0 with the cellulose acetate butyrate. A ratio of the organic solvent B relative to a total of the organic solvent A and the organic solvent B is 5.0 to 40.0 wt %.

A conductive paste obtained by adding an organic solvent B to a vehicle containing a Ni powder, a binder resin component, and an organic solvent A. The Ni powder has an average primary particle size of 30 to 400 nm. The binder resin component is cellulose acetate butyrate. Organic solvent A is a solvent having a Δ δ value of 11.5 or less with the cellulose acetate butyrate. Organic solvent B is a solvent having a Δ δ value from 11.5 to 25.0 with the cellulose acetate butyrate. A ratio of the organic solvent B relative to a total of the organic solvent A and the organic solvent B is 5.0 to 40.0 wt %.