An anisotropic conductive film in which conductive particles are disposed in an insulating resin layer has a particle disposition of the conductive particles such that a first orthorhombic lattice region being formed by arranging a plurality of arrangement axes of the conductive particles, disposed in an a direction at a predetermined pitch, in a b direction inclined with respect to the a direction at an angle, and a second orthorhombic lattice region being formed by arranging a plurality of arrangement axes of the conductive particles, disposed in the a direction at a predetermined pitch, in a c direction obtained by inverting the b direction with respect to the a direction are repeatedly disposed.

An anisotropic conductive film in which conductive particles are disposed in an insulating resin layer has a particle disposition of the conductive particles such that a first orthorhombic lattice region being formed by arranging a plurality of arrangement axes of the conductive particles, disposed in an a direction at a predetermined pitch, in a b direction inclined with respect to the a direction at an angle, and a second orthorhombic lattice region being formed by arranging a plurality of arrangement axes of the conductive particles, disposed in the a direction at a predetermined pitch, in a c direction obtained by inverting the b direction with respect to the a direction are repeatedly disposed.

The present disclosure relates to a method for manufacturing a semiconductor package including vacuum-laminating a non-conductive film on a substrate on which a plurality of through silicon vias are provided and bump electrodes are formed, and then performing UV irradiation, wherein an increase in melt viscosity before and after UV irradiation can be adjusted to 30% or less, whereby a bonding can be performed without voids during thermo-compression bonding, and resin-insertion phenomenon between solders can be prevented, fillets can be minimized and reliability can be improved.

The present disclosure relates to a method for manufacturing a semiconductor package including vacuum-laminating a non-conductive film on a substrate on which a plurality of through silicon vias are provided and bump electrodes are formed, and then performing UV irradiation, wherein an increase in melt viscosity before and after UV irradiation can be adjusted to 30% or less, whereby a bonding can be performed without voids during thermo-compression bonding, and resin-insertion phenomenon between solders can be prevented, fillets can be minimized and reliability can be improved.

The present disclosure is directed to a hybrid conductive ink including: silver nanoparticles and eutectic low melting point alloy particles, wherein a weight ratio of the eutectic low melting point alloy particles and the silver nanoparticles ranges from 1:20 to 1:5. Also provided herein are methods of forming an interconnect including a) depositing a hybrid conductive ink on a conductive element positioned on a substrate, wherein the hybrid conductive ink comprises silver nanoparticles and eutectic low melting point alloy particles, the eutectic low melting point alloy particles and the silver nanoparticles being in a weight ratio from about 1:20 to about 1:5; b) placing an electronic component onto the hybrid conductive ink; c) heating the substrate, conductive element, hybrid conductive ink and electronic component to a temperature sufficient i) to anneal the silver nanoparticles in the hybrid conductive ink and ii) to melt the low melting point eutectic alloy particles, wherein the melted low melting point eutectic alloy flows to occupy spaces between the annealed silver nanoparticles, d) allowing the melted low melting point eutectic alloy of the hybrid conductive ink to harden and fuse to the electronic component and the conductive element, thereby forming an interconnect. Electrical circuits including conductive traces and, optionally, interconnects formed with the hybrid conductive ink are also provided.

A semiconductor package includes a package substrate, a lower semiconductor chip on the package substrate, an interposer on the lower semiconductor chip, the interposer including a plurality of pieces spaced apart from each other, an upper semiconductor chip on the interposer, and a molding member covering the lower semiconductor chip and the interposer.

A semiconductor device according to an embodiment includes a lead frame, a semiconductor chip provided above the lead frame, and a bonding material including a sintered material containing a predetermined metal material and a predetermined resin, where the bonding material includes a first portion provided between the lead frame and the semiconductor chip, and a second portion provided on the lead frame around the semiconductor chip, where the bonding material bonds the lead frame and the semiconductor chip, wherein an angle formed by a lower face of the semiconductor chip and an upper face of the second portion adjacent to the lower face is 80 degrees or less.

A semiconductor device according to an embodiment includes a lead frame, a semiconductor chip provided above the lead frame, and a bonding material including a sintered material containing a predetermined metal material and a predetermined resin, where the bonding material includes a first portion provided between the lead frame and the semiconductor chip, and a second portion provided on the lead frame around the semiconductor chip, where the bonding material bonds the lead frame and the semiconductor chip, wherein an angle formed by a lower face of the semiconductor chip and an upper face of the second portion adjacent to the lower face is 80 degrees or less.

A semiconductor package includes a package substrate, a lower semiconductor chip on the package substrate, an interposer on the lower semiconductor chip, the interposer including a plurality of pieces spaced apart from each other, an upper semiconductor chip on the interposer, and a molding member covering the lower semiconductor chip and the interposer.

A thermosetting sheet according to the present invention includes a thermosetting resin and a thermoplastic resin, in which a thickness change rate when a temperature is changed from 25° C. to 200° C. is 0% or more and 10% or less.