A display device comprises a substrate divided into emission and non-emission areas, a storage capacitor, a first insulating layer, a first light emitting element and a second light emitting element, a bank in the non-emission area, and defining an opening corresponding to the emission area, a first pixel electrode electrically connected to a first end of the first light emitting element, a second pixel electrode electrically connected to a second end of the second light emitting element, an intermediate electrode between the first pixel electrode and the second pixel electrode, surrounding at least a portion of the first pixel electrode, and electrically connected to a second end of the first light emitting element and to a first end of the second light emitting element, and a sub-electrode electrically connected to a lower electrode of the storage capacitor through a contact hole, and overlapping the first pixel electrode.

A 3D stack includes a first chip having first interconnection pads of rectangular section, the first interconnection pads having a first pitch in a first direction and a second pitch in a second direction perpendicular to the first direction; and a second chip having second interconnection pads, the second interconnection pads having a third pitch in the first direction and a fourth pitch in the second direction, at least one part of the second interconnection pads being in contact with the first interconnection pads to electrically couple the first and second chips. The first interconnection pads have a first dimension in the first direction equal to m times the third pitch and a second dimension in the second direction equal to n times the fourth pitch. The first interconnection pads are separated two by two in the first direction by a first distance equal to q times the third pitch.

A semiconductor structure is provided. The semiconductor structure includes a semiconductor substrate and a first conductive bump. The semiconductor substrate has an integrated circuit and an interconnection metal layer, and a tilt surface is formed on an edge of the semiconductor substrate. The first conductive bump is electrically connected to the integrated circuit via the interconnection metal layer, and is disposed on the tilt surface, wherein a profile of the first conductive bump extends beyond a side surface of the edge of the semiconductor layer.

A semiconductor package includes a package substrate, a semiconductor chip on the package substrate and having a first surface facing the package substrate and a second surface, opposite to the first surface, an encapsulant disposed on the package substrate and on a side surface of the semiconductor chip, a heat dissipation member on the semiconductor chip and spaced apart from the semiconductor chip, a bonding enhancing layer on the second surface of the semiconductor chip, a thermal interface material layer on the bonding enhancing layer and in a gap between the bonding enhancing layer and the heat dissipation member, wherein the thermal interface material layer includes liquid metal, and a porous barrier structure formed of a metal material and surrounding the bonding enhancing layer and the thermal interface material layer.

A semiconductor package includes: a base substrate; an interposer disposed on the base substrate, wherein the interposer includes a plurality of recesses in a bottom surface thereof; a semiconductor chip disposed on the interposer; a plurality of interposer connection terminals between the interposer and the base substrate, wherein the plurality of interposer connection terminals electrically connect the interposer to the base substrate; and a first underfill layer disposed between the interposer and the base substrate, wherein the first underfill layer at least partially surrounds the plurality of interposer connection terminals, wherein the first underfill layer at least partially surrounds a side surface of each of the plurality of recesses and has a slope declining from the bottom surface of the interposer to a top surface of the base substrate.

A method for manufacturing a semiconductor module can prevent performance and reliability degradation of a semiconductor module. The method for manufacturing a semiconductor module includes: arranging an insulating wiring board on a low die; arranging a sintering material at plural locations on the insulating wiring board and arranging a semiconductor chip on each of the plural sintering materials; arranging a structure above protruding portions of the sintering materials protruding from a periphery of each of the plural semiconductor chips; and sintering by pressurizing and heating the plural sintering materials by an upper die through the structure at the protruding portions and through the semiconductor chips at contacting portions in contact with lower surfaces of the semiconductor chips.

The disclosure relates to a glass-based antenna array package. In an aspect, such a glass-based antenna array package includes a single glass substrate layer, one or more antennas attached to a first side of the glass substrate layer, at least one semiconductor device attached to a second side of the glass substrate layer, and a first photoimageable dielectric layer adhered to the second side of the glass substrate layer and encapsulating the at least one semiconductor device. A method of manufacturing the same is also disclosed.

A semiconductor package structure includes a capacitor substrate and a first semiconductor die. The capacitor substrate has a first surface and a second surface opposite the first surface and includes a first redistribution structure, a second redistribution structure, a through via, and a first capacitor structure. The first redistribution structure is disposed on the first surface. The second redistribution structure is disposed on the second surface. The through via electrically couples the first redistribution structure to the second redistribution structure. The first capacitor structure is disposed between the first redistribution structure and the second redistribution structure and is electrically coupled to the second redistribution structure. The first semiconductor die is disposed over the capacitor substrate and is electrically coupled to the first capacitor structure through the second redistribution structure.

A 3D stack includes a first chip having first interconnection pads of rectangular section, the first interconnection pads having a first pitch in a first direction and a second pitch in a second direction perpendicular to the first direction; and a second chip having second interconnection pads, the second interconnection pads having a third pitch in the first direction and a fourth pitch in the second direction, at least one part of the second interconnection pads being in contact with the first interconnection pads to electrically couple the first and second chips. The first interconnection pads have a first dimension in the first direction equal to m times the third pitch and a second dimension in the second direction equal to n times the fourth pitch. The first interconnection pads are separated two by two in the first direction by a first distance equal to q times the third pitch.

Provided is a semiconductor package including a circuit board, a semiconductor chip on the circuit board, a heat dissipation member adjacent to the semiconductor chip, and a heat transmission member between the semiconductor chip and the heat dissipation member, the heat transmission member including a resin insulating body and phase change metal particles connected to each other in the resin insulating body, wherein the phase change metal particles connect the semiconductor chip and the heat dissipation member, the phase change metal particles being configured to transmit heat generated by the semiconductor chip to the heat dissipation member.