Patent ID: 8377344

Claim:
A method for producing an optical film comprising: a resin material which is cellulose acylate having a polydispersiveness index (Mw/Mn) of from 1.0 to 5.0; and an additive having a molecular weight of 3,000 or less in an amount of at least 0.3% by mass based on the resin material, wherein when the optical film is divided into 10 equal portions in a thickness direction of the optical film, an amount of the additive existing in each of 8 portions excepting the two outermost layer portions of the 10 equal portions is from 80 to 120% based on a mean additive amount in an entire optical film, the method comprising steps (1) and (2): (1) a step of adding the additive to the resin material at plural different concentrations, adding a solvent to dissolve the additive and the resin material, and preparing plural solutions having different additive concentrations and a dope transparency of 85% or more; and (2) a step of casting the plural solutions onto a substrate in a co-casting process or a multi-layer casting process in a manner that a solution having a higher additive concentration among the plural solutions forms an outer layer of the optical film, so as to form an optical film in which when the optical film is divided into 10 equal portions in a thickness direction of the optical film, an amount of the additive existing in each of 8 portions excepting the two outermost layer portions of the 10 equal portions is from 80 to 120% based on a mean additive amount in an entire optical film, wherein the optical film contains at least one optical anisotropy-lowering compound within a range satisfying the following formulae (a) and (b): ( Rth ( A )− Rth (0))/ A≦− 1.0, (a) 0.01 ≦A≦ 30, (b) wherein Rth(A) means Rth (nm) of the film that contains A % of a compound of lowering Rth; Rth(0) means Rth (nm) of the film not containing a compound of lowering Rth; A means the mass (%) of the compound relative to the solid content mass, 100, of a polymer in the optical film, and wherein the optical film has Re (λ) and Rth (λ) satisfying formulae (I) and (II): 0 ≦Re (630) ≦10, and | Rth (630) |≦25, (I) | Re (400) −Re (700) |≦10, and | Rth (400) −Rth (700) |≦35, (II) wherein Re (λ) represents an in-plane retardation value (unit: nm) of the optical film at a wavelength of λ nm; and Rth (λ) represents a thickness-direction retardation value (unit: nm) of the optical film at a wavelength of λ nm.