Lithium ion secondary battery and method of manufacturing lithium ion secondary battery

The invention claimed is: 1. A lithium ion secondary battery including: an electrode body including: a negative electrode sheet including a negative metal foil and a negative active material layer formed on the negative metal foil, the negative active material layer containing negative active material particles; a positive electrode sheet including a positive metal foil and a positive active material layer formed on the positive metal foil; and separators interposed between the positive electrode sheet and the negative electrode sheet; a battery case housing the electrode body; and an electrolyte accommodated in the battery case, the electrolyte containing lithium ions, the electrolyte including a retained electrolyte retained between the positive electrode sheet and the negative electrode sheet of the electrode body, the negative active material layer having a facing portion placed to face the positive active material layer of the positive electrode sheet adjacent through the separators and a non-facing portion placed outside the facing portion on an outer circumferential side of the negative active material layer without facing the positive active material layer, wherein the negative active material particles are flat-shaped particles containing graphite and being able to be oriented by a magnetic field, in particle cross sections of 100 or more of the negative active material particles in a vertical cross section of the negative electrode sheet observed through a scanning electron microscope (SEM), an angle formed between an extending direction of a major axis of the particle cross section and the negative metal foil is assumed as θ, of the observed negative active material particles, a number of the negative active material particles having the angle θ of 60° to 90° is assumed as MA, a number of the negative active material particles having the angle θ of 0° to 30° is assumed as MB, and a value obtained by dividing the number MA by the number MB (=MA/MB) is assumed as an orientation degree AL of the negative active material particles, the negative active material layer is configured such that a non-facing portion orientation degree AL 1 which is the orientation degree AL of the negative active material particles in the non-facing portion is 1.2 or higher, wherein the facing portion of the negative active material layer is configured such that a facing portion orientation degree AL 2 which is the orientation degree AL in the facing portion is 0.8 or less. 2. A method for manufacturing a lithium ion secondary battery including: an electrode body including: a negative electrode sheet including a negative metal foil and a negative active material layer formed on the negative metal foil, the negative active material layer containing negative active material particles; a positive electrode sheet including a positive metal foil and a positive active material layer formed on the positive metal foil; and separators interposed between the positive electrode sheet and the negative electrode sheet; a battery case housing the electrode body; and an electrolyte accommodated in the battery case, the electrolyte containing lithium ions, the electrolyte including a retained electrolyte retained between the positive electrode sheet and the negative electrode sheet of the electrode body, the negative active material layer having a facing portion placed to face the positive active material layer of the positive electrode sheet adjacent through the separators and a non-facing portion placed outside the facing portion on an outer circumferential side of the negative active material layer without facing the positive active material layer, wherein the negative active material particles are flat-shaped particles containing graphite and being able to be oriented by a magnetic field, in particle cross sections of 100 or more of the negative active material particles in a vertical cross section of the negative electrode sheet observed through a scanning electron microscope (SEM), an angle formed between an extending direction of a major axis of the particle cross section and the negative metal foil is assumed as θ, of the observed negative active material particles, a number of the negative active material particles having the angle θ of 60° to 90° is assumed as MA, a number of the negative active material particles having the angle θ of 0° to 30° is assumed as MB, and a value obtained by dividing the number MA by the number MB (=MA/MB) is assumed as an orientation degree AL of the negative active material particles, the negative active material layer is configured such that a non-facing portion orientation degree AL 1 which is the orientation degree AL of the negative active material particles in the non-facing portion is 1.2 or higher, wherein, the method includes: an applying step of applying active material paste containing the negative active material particles dispersed in a solvent to a main surface of the negative metal foil to form a coating; an orientation step of applying a magnetic field to a prospective non-facing portion of the coating, which will be the non-facing portion of the negative active material layer, to orient the negative active material particles contained in the prospective non-facing portion by a magnetic field; and a drying step of drying the coating after the orientation step, wherein the facing portion of the negative active material layer is configured such that a facing portion orientation degree AL 2 which is the orientation degree AL in the facing portion is 0.8 or less, and wherein the orientation step includes applying a magnetic field to the prospective non-facing portion without applying a magnetic field to a prospective facing portion which will be the facing portion of the negative active material layer.