A semiconductor package structure includes a semiconductor die having an active surface, a conductive bump electrically coupled to the active surface, and a dielectric layer surrounding the conductive bump. The conductive bump and the dielectric layer form a planar surface at a distal end of the conductive bump with respect to the active surface. The distal end of the conductive bump is wider than a proximal end of the conductive bump with respect to the active surface.

A method includes producing a semiconductor arrangement having a semiconductor layer, a first insulation layer arranged on the semiconductor layer and facing a first surface of the semiconductor arrangement, and an insulating via extending in a vertical direction through the semiconductor layer as far as the first insulation layer, the insulating via surrounding a region of the semiconductor layer in a ring-shaped fashion. The method further includes permanently securing a first carrier to the first surface of the semiconductor arrangement.

A device-bonded body includes: a first device where a plated bump is disposed; a second device where a bonding electrode bonded to the plated bump is disposed; and a sealing layer made of NCF or NCP, the sealing layer being disposed between the first device and the second device and including filler particles made of inorganic material; wherein a surface of the plated bump includes a first area and a second area higher than the first area; and at least a part of a side surface of an outer circumferential portion of the second area intersects with a surface of the first area.

A semiconductor device includes a substrate and a semiconductor chip. The semiconductor chip includes a semiconductor element on a first surface thereof. The semiconductor chip is provided on the substrate such that a second surface thereof, which is opposite to the first surface, faces an upper surface of the substrate. A metal layer is provided between the second surface of the semiconductor chip and the upper surface of the substrate. A metal material, in which the range of rays is shorter than for single-crystal silicon, is used in the metal layer.

A method of forming a bonded assembly includes providing a first semiconductor die containing a first substrate, first semiconductor devices, first dielectric material layers overlying the first semiconductor devices, and first metal interconnect structures, providing a second semiconductor die containing a second substrate, second semiconductor devices, second dielectric material layers overlying the second semiconductor devices, and second metal interconnect structures, depositing a manganese layer on a top surface of the first dielectric material layers, disposing the second semiconductor die on the manganese layer such that a surface of the second dielectric material layers contacts the manganese layer, and performing a bonding anneal to bond the first semiconductor die to the second semiconductor die and to convert the manganese layer into a manganese-containing oxide layer, such that the manganese-containing oxide layer is bonded to the first dielectric material layers and the second dielectric material layers.

A semiconductor package structure includes a semiconductor die having an active surface, a conductive bump electrically coupled to the active surface, and a dielectric layer surrounding the conductive bump. The conductive bump and the dielectric layer form a planar surface at a distal end of the conductive bump with respect to the active surface. The distal end of the conductive bump is wider than a proximal end of the conductive bump with respect to the active surface.

A semiconductor device includes: a mounting member having an electrode; a conductive member facing the electrode; and a bonding member electrically and mechanically connecting the electrode and the conductive member. The bonding member is made of a sintered body in which an additive particle including a metal atom having aggregation energy higher than a silver atom is added to an silver particle.

Implementations of semiconductor packages may include: a semiconductor wafer, a glass lid fixedly coupled to a first side of the semiconductor die by an adhesive, a redistribution layer coupled to a second side of the semiconductor die, and a plurality of ball mounts coupled to the redistribution layer on a side of the redistribution layer coupled to the semiconductor die. The adhesive may be located in a trench around a perimeter of the semiconductor die and located in a corresponding trench around a perimeter of the glass lid.

An inventive composition and process for formation of a conductive bonding film are disclosed. The invention combines adhesive bonding sheet technologies (e.g. die attach films, or DAFs) with the electrical and thermal conductivity performance of transient liquid phase sintered paste compositions. The invention films are characterized by high bulk thermal and electrical conductivity within the film as well as low and stable thermal and electrical resistance at the interfaces between the inventive film and metallized adherends.

An inventive composition and process for formation of a conductive bonding film are disclosed. The invention combines adhesive bonding sheet technologies (e.g. die attach films, or DAFs) with the electrical and thermal conductivity performance of transient liquid phase sintered paste compositions. The invention films are characterized by high bulk thermal and electrical conductivity within the film as well as low and stable thermal and electrical resistance at the interfaces between the inventive film and metallized adherends.