A conductive film includes an elongated release film and a plurality of conductive adhesive film pieces provided on the release film. Then, the plurality of adhesive film pieces are arranged in a longitudinal direction X of the release film. For this reason, the adhesive film piece can be set to an arbitrary shape. Accordingly, it is possible to attach the adhesive film piece to adhesive surfaces having various shapes and to efficiently use the adhesive film piece.

The present invention provides an anisotropic electrically conductive film with a structure, in which electrically conductive particles are disposed at lattice points of a planar lattice pattern in an electrically insulating adhesive base layer. A proportion of the lattice points, at which no electrically conductive particle is disposed, with respect to all the lattice points of the planar lattice pattern assumed as a reference region, is less than 20%. A proportion of the lattice points, at which plural electrically conductive particles are disposed in an aggregated state, with respect to all the lattice points of the planar lattice pattern, is not greater than 15%. A sum of omission of the electrically conductive particle and an aggregation of the electrically conductive particles is less than 25%.

The present invention provides an anisotropic electrically conductive film with a structure, in which electrically conductive particles are disposed at lattice points of a planar lattice pattern in an electrically insulating adhesive base layer. A proportion of the lattice points, at which no electrically conductive particle is disposed, with respect to all the lattice points of the planar lattice pattern assumed as a reference region, is less than 20%. A proportion of the lattice points, at which plural electrically conductive particles are disposed in an aggregated state, with respect to all the lattice points of the planar lattice pattern, is not greater than 15%. A sum of omission of the electrically conductive particle and an aggregation of the electrically conductive particles is less than 25%.

An aspect of the present disclosure is a method that includes depositing an ink as a liquid strand onto a substrate, transforming the liquid strand to a precursor strand, converting at least a portion of the precursor strand to a nanowire that includes a first metal, and coating the nanowire with a second metal to form a core-shell nanowire having a core and a shell, where at least a portion of the transforming occurs during the depositing, and the core includes the nanowire and the shell includes the second metal.

An aspect of the present disclosure is a method that includes depositing an ink as a liquid strand onto a substrate, transforming the liquid strand to a precursor strand, converting at least a portion of the precursor strand to a nanowire that includes a first metal, and coating the nanowire with a second metal to form a core-shell nanowire having a core and a shell, where at least a portion of the transforming occurs during the depositing, and the core includes the nanowire and the shell includes the second metal.

The present invention provides a conductive material in which, even when the conductive material is left for a certain period of time, solder of conductive particles can be efficiently placed on an electrode, and, in addition, yellowing of the conductive material can be sufficiently suppressed during heating. The conductive material according to the present invention contains a plurality of conductive particles having solder at an outer surface portion of a conductive portion, a curable compound, and a boron trifluoride complex.

The present invention provides a conductive material in which, even when the conductive material is left for a certain period of time, solder of conductive particles can be efficiently placed on an electrode, and, in addition, yellowing of the conductive material can be sufficiently suppressed during heating. The conductive material according to the present invention contains a plurality of conductive particles having solder at an outer surface portion of a conductive portion, a curable compound, and a boron trifluoride complex.

Provided is an anisotropic conductive film manufacturing method capable of reducing manufacturing costs. Also provided is an anisotropic conductive film capable of suppressing the occurrence of conduction defects. The anisotropic conductive film manufacturing method includes: a holding step of supplying conductive particles having a plurality of particle diameters on a member having a plurality of opening parts, and holding the conductive particles in the opening parts; and a transfer step of transferring the conductive particles held in the opening parts to an adhesive film. In the particle diameter distribution graph (X-axis: particle diameter (?m), Y-axis: number of particles) of the conductive particles held in the opening parts, the shape of the graph is such that the slope is substantially infinite in a range at or above a maximum peak particle diameter.

Provided is an anisotropic conductive film manufacturing method capable of reducing manufacturing costs. Also provided is an anisotropic conductive film capable of suppressing the occurrence of conduction defects. The anisotropic conductive film manufacturing method includes: a holding step of supplying conductive particles having a plurality of particle diameters on a member having a plurality of opening parts, and holding the conductive particles in the opening parts; and a transfer step of transferring the conductive particles held in the opening parts to an adhesive film. In the particle diameter distribution graph (X-axis: particle diameter (?m), Y-axis: number of particles) of the conductive particles held in the opening parts, the shape of the graph is such that the slope is substantially infinite in a range at or above a maximum peak particle diameter.

The present invention provides an anisotropic electrically conductive film with a structure, in which electrically conductive particles are disposed at lattice points of a planar lattice pattern in an electrically insulating adhesive base layer. A proportion of the lattice points, at which no electrically conductive particle is disposed, with respect to all the lattice points of the planar lattice pattern assumed as a reference region, is less than 20%. A proportion of the lattice points, at which plural electrically conductive particles are disposed in an aggregated state, with respect to all the lattice points of the planar lattice pattern, is not greater than 15%. A sum of omission of the electrically conductive particle and an aggregation of the electrically conductive particles is less than 25%.