The present application discloses a drive chip and a display panel. The drive chip includes a first area and a second area. The drive chip includes a substrate and drive pins. The density of the pins located in the first area is lower than the density of the pins located in the second area. The pins located in the second area includes first drive pins and second drive pins. The distance between the substrate and a face of the first drive pins away from the substrate is greater than the distance between the substrate and a face of the second drive pins away from the substrate. The occurrence of poor electric conduction is avoided.

A semiconductor package includes a first semiconductor chip, a plurality of second semiconductor chips stacked on the first semiconductor chip, and having widths narrower than a width of the first semiconductor chip, and a molded layer on an upper surface of the first semiconductor chip. The first semiconductor chip includes first front-surface pads, a first back-surface insulating layer divided into a first region and a second region, first back-surface pads in the first region, dummy pads in the second region, the dummy pads respectively having an upper surface on which a metal oxide film is disposed, and a first through-electrode electrically connecting the first front-surface pads and the first back-surface pads to each other. The plurality of second semiconductor chips respectively includes second front-surface pads, second back-surface pads, and a second through-electrode electrically connecting the second front-surface pads and the second back-surface pads to each other.

An integrated circuit device includes a first IC die with a first front surface, a first back surface, and a first side surface along opposed edges of the first front surface and the first back surfaces of the first IC die, a second IC die with a second front surface, a second back surface, and a second side surface along opposed edges of the second front surface and second back surface of the second IC die, a substrate coupled to the first side surface of the first IC die and the second side surface of the second IC die, and fill material between one of the first front surface and the first back surface of the first IC die and one of the second front surface and second back surface of the second IC die. Other embodiments are disclosed and claimed.

This disclosure is related to arranging micro devices in the donor substrate by either patterning or population so that there is no interfering with unwanted pads and the non-interfering area in the donor substrate is maximized. This enables to transfer the devices to receiver substrate with fewer steps.

A chip protection device includes a protection frame extending around side surfaces of a semiconductor chip mounted on a substrate. The protection frame includes a plurality of side walls, each wall facing and spaced apart from a respective side surface of the semiconductor chip, and a plurality of upper walls, each upper wall extending inward from an upper portion of a respective side wall toward the semiconductor chip. A plurality of apertures are formed through the side walls and through which a fluid enters and exits. The protection frame defines an inner space in which the fluid can flow via the plurality of apertures. Heat from the side surfaces of the semiconductor chip is transferred to the fluid in the inner space.

Some implementations described herein provide techniques and apparatuses for a fixture including a semiconductor die package and methods of formation. The semiconductor die package is mounted to an interposer. In addition to the semiconductor die package, the fixture includes a lid component having a top structure and footing structures that connect the lid component to the interposer. The fixture includes a thermal interface material between a top surface of the semiconductor die package and the top structure of the lid component. The footing structures, connected to the interposer using deposits of an epoxy material, provide increase a structural rigidity of the fixture relative to another fixture not including the footing structures.

A liquid alloy thermal paste comprises: a liquid alloy and a trace element, the liquid alloy and the trace element are stirred and reformed to a paste-like liquid alloy mixture that is viscous and does not flow easily, and the liquid alloy mixture is used as the liquid alloy thermal paste.

A semiconductor package includes a first substrate having a first surface and a second surface, and having a cavity extending from the first surface to the second surface in a vertical direction, a first chip disposed in the cavity of the first substrate, a redistribution structure on the first surface of the first substrate, a second chip on the redistribution structure, a third chip spaced apart from the second chip in a horizontal direction and disposed on the redistribution structure, and a bridge chip embedded in the redistribution structure, wherein the redistribution structure includes a first redistribution pattern, a second redistribution pattern, and a third redistribution pattern.

A semiconductor package includes a package substrate a package substrate including: a substrate core; an upper redistribution layer disposed on a first side of the substrate core; and a lower redistribution layer disposed on an opposing second side of the substrate core; a semiconductor device vertically stacked on and electrically connected to the package substrate; and an upper reinforcement layer embedded in the upper redistribution layer between the semiconductor device and the substrate core, the upper reinforcement layer having a Young's modulus that is higher than a Young's modulus of the upper redistribution layer.

A package structure is disclosed. The package structure includes a substrate including a conductive element and a plurality of wires having a surface area through which heat of the conductive element can be dissipated, lowering a bonding temperature of the conductive element. The package structure also includes a conductive layer disposed between the conductive element of the substrate and the plurality of wires. The conductive contact layer attaches the plurality of wires over the conductive element.