Non-aqueous rechargeable battery and method for manufacturing non-aqueous rechargeable battery

What is claimed is: 1 . A non-aqueous rechargeable battery, comprising: an electrode body formed by rolling a stack of a positive electrode plate and a negative electrode plate with a separator arranged in between, wherein: at least one of the positive electrode plate and the negative electrode plate includes a substrate, a first mixture layer located on an outer side of the substrate, and a second mixture layer located on an inner side of the substrate; and the second mixture layer includes an active material having a BET specific surface area that is greater than that of an active material included in the first mixture layer. 2 . The non-aqueous rechargeable battery according to claim 1 , wherein the electrode body includes a curved portion in which layers of the electrode body are curved, and the second mixture layer has a density at the curved portion that is greater than that of the first mixture layer at the curved portion. 3 . A method for manufacturing a non-aqueous rechargeable battery, the method comprising: manufacturing a positive electrode plate; manufacturing a negative electrode plate; and manufacturing an electrode body by rolling a stack of the positive electrode plate and the negative electrode plate with a separator arranged in between, wherein: at least one of the manufacturing the positive electrode plate and the manufacturing the negative electrode plate includes forming a first mixture layer on a first surface of a substrate, and forming a second mixture layer on a second surface of the substrate opposite to the first surface; the forming the second mixture layer on the second surface is performed such that the second mixture layer includes an active material having a BET specific surface area that is greater than that of an active material included in the first mixture layer; and the manufacturing the electrode body includes rolling the substrate such that the first mixture layer is located on an outer side of the substrate and the second mixture layer is located on an inner side of the substrate. 4 . The method according to claim 3 , wherein: the forming the first mixture layer includes applying a first mixture paste to the first surface, and drying the first mixture paste; the forming the second mixture layer includes applying a second mixture paste to the second surface, and drying the second mixture paste; and the second mixture paste is dried at a speed that is lower than that of the first mixture paste. 5 . The method according to claim 4 , wherein the forming the second mixture layer is performed after the forming the first mixture layer. 6 . The method according to claim 3 , wherein an active material used as a raw material of the second mixture layer has a BET specific surface area that is greater than that of an active material used as a raw material of the first mixture layer. 7 . The method according to claim 3 , wherein: the forming the first mixture layer includes dry-kneading a first mixture paste including a raw material of the first mixture layer, and diluting the dry-kneaded first mixture paste; the forming the second mixture layer includes dry-kneading a second mixture paste including a raw material of the second mixture layer, and diluting the dry-kneaded second mixture paste; and the second mixture paste that is dry-kneaded has a solid content ratio that is lower than that of the first mixture paste that is dry-kneaded. 8 . The method according to claim 3 , wherein the forming the first mixture layer includes pressing the first mixture layer to adjust a thickness of the first mixture layer, the forming the second mixture layer includes pressing the second mixture layer to adjust a thickness of the second mixture layer, and a pressed amount of the second mixture layer is greater than that of the first mixture layer. 9 . The method according to claim 8 , wherein: the forming the first mixture layer further includes applying a first mixture paste including a raw material of the first mixture layer to the first surface, and drying the first mixture paste; the forming the second mixture layer further includes applying a second mixture paste including a raw material of the second mixture layer to the second surface, and drying the second mixture paste; and the applying a second mixture paste is performed such that the second mixture paste has a weight per unit area that is greater than that of the first mixture paste. 10 . The method according to claim 8 , wherein: the forming the first mixture layer further includes dry-kneading a first mixture paste including a raw material of the first mixture layer, diluting the dry-kneaded first mixture paste, applying the diluted first mixture paste to the first surface, and drying the first mixture paste; the forming the second mixture layer further includes dry-kneading a second mixture paste including a raw material of the second mixture layer, diluting the dry-kneaded second mixture paste, applying the diluted second mixture paste to the second surface, and drying the second mixture paste; and the diluting the dry-kneaded second mixture paste is performed such that the diluted second mixture paste has a solid content ratio that is greater than that of the diluted first mixture paste. 11 . The method according to claim 8 , wherein an active material used as a raw material of the second mixture layer has a tapped density that is less than that of an active material used as a raw material of the first mixture layer.