Disclosed is a semiconductor package comprising a semiconductor chip, a redistribution pattern on a bottom surface of the semiconductor chip and coupled to the semiconductor chip, a protection layer that covers a bottom surface of the redistribution pattern, a conductive pattern on a bottom surface of the protection layer and coupled to the redistribution pattern, a buffer pattern in contact with a bottom surface of a first part of the conductive pattern and with the bottom surface of the protection layer, and an under bump pattern on a bottom surface of the second part of the conductive pattern and covering a bottom surface and a side surface of the buffer pattern. The under bump pattern is coupled to the second part of the conductive pattern.

A display device is provided. The display device comprising: a substrate including a display area and a pad area, a first conductive layer disposed on the substrate and including a first signal line disposed in the display area, a buffer layer disposed on the first conductive layer, a semiconductor layer disposed on the buffer layer in the display area, a gate insulating film disposed on the semiconductor layer, a second conductive layer disposed on the gate insulating film and including a gate electrode overlapping the semiconductor layer in the display area, a first electrode of a transistor disposed to overlap one side of the semiconductor layer in the display area and connected to the first signal line through a contact hole penetrating through the buffer layer and the gate insulating film, and a second electrode of the transistor disposed to overlap the other side of the semiconductor layer in the display area, a first pad disposed on the buffer layer in the pad area and exposed by a pad opening, a first insulating layer disposed on the second conductive layer and the first pad, and a light emitting element disposed on the first insulating layer in the display area, wherein the first pad is formed of the first conductive layer or the second conductive layer.

A display device includes pixels, each of the pixels including light emitting elements disposed in pixels, a color conversion layer disposed on the light emitting elements of the pixels, an optical layer disposed on the color conversion layer, and an organic layer disposed on the optical layer. At least one of the optical layer and the organic layer includes recess patterns disposed between the pixels.

A method comprises molding laser direct structuring material onto at least one semiconductor die, forming resist material on the laser direct structuring material, producing mutually aligned patterns of electrically-conductive formations in the laser direct structuring material and etched-out portions of the resist material having lateral walls sidewise of said electrically-conductive formations via laser beam energy, and forming electrically-conductive material at said etched-out portions of the resist material, the electrically-conductive material having lateral confinement surfaces at said lateral walls of said etched-out portions of the resist material.

A semiconductor package includes a die and a first lamination layer on the die with openings through the first lamination layer. A redistribution layer is on the first lamination layer and extends through the openings to the die. A plurality of conductive extensions are on the redistribution layer with each stud including a first surface on the redistribution layer, a second surface opposite to the first surface, and a sidewall between the first surface and the second surface. A second lamination layer is on the redistribution layer and the first lamination layer with the die encapsulated in molding compound. The second lamination layer is removed around the conductive extensions to expose the second surface and at least a portion of the sidewall of each stud to improve solder bond strength when mounting the package to a circuit board.

A method includes forming an insulating layer over a package. The package has a plurality of locations where openings are subsequently formed. A first laser shot is performed, location by location, on each of the locations across the package. A first laser spot of the first laser shot overlaps with each of the locations. The first laser shot removes a first portion of the insulating layer below the first laser spot. Another laser shot is performed, location by location, on each of the locations across the package. Another laser spot of the another laser shot overlaps with each of the locations. The another laser shot removes another portion of the insulating layer below the another laser spot. Performing the another laser shot, location by location, on each of the locations across the package is repeated multiple times, until desired portions of the insulating layer are removed.

An embedded component stack includes a first metal layer, a first dielectric layer disposed on the first metal layer, a second metal layer disposed on the first dielectric layer, a first component disposed and embedded entirely within the first dielectric layer and entirely between the first metal layer and the second metal layer, a second dielectric layer disposed on the second metal layer, and a second component disposed on or embedded entirely within the second dielectric layer. The first and second components can be bare, unpackaged dies disposed over the metal layers by micro-transfer printing. The metal layers can be patterned and can be electrically connected to the components. The first component can be rotated with respect to the second component. Multiple components can be embedded in one or more of the dielectric layers.

A display device includes a conductive pattern on a substrate, a via layer on the conductive pattern with a via hole exposing the conductive pattern, a first electrode and a second electrode on the via layer and spaced apart from each other, a first insulating layer on the first electrode and the second electrode, a bank layer on the first insulating layer defining an emission area and a subarea, a light-emitting element on the first insulating layer, and a first connection electrode and a second connection electrode on the first insulating layer and the light-emitting element. The first connection electrode electrically contacts an end of the light-emitting element, and the second connection electrode electrically contacts another end of the light-emitting element. The bank layer includes a bank extension portion extended to the subarea and the bank extension portion overlaps at least a portion of the via hole.

A semiconductor package includes a semiconductor die, a first thermal conductive pattern and a second thermal conductive pattern. The semiconductor die is encapsulated by an encapsulant. The first thermal conductive pattern is disposed aside the semiconductor die in the encapsulant. The second thermal conductive pattern is disposed over the semiconductor die, wherein the first thermal conductive pattern is thermally coupled to the semiconductor die through the second thermal conductive pattern and electrically insulated from the semiconductor die.

A system and method of providing high bandwidth and low latency memory architecture solutions for next generation processors is disclosed. The package contains a substrate, a memory device embedded in the substrate via EMIB processes and a processor disposed on the substrate partially over the embedded memory device. The I/O pads of the processor and memory device are vertically aligned to minimize the distance therebetween and electrically connected through EMIB uvias. An additional memory device is disposed on the substrate partially over the embedded memory device or on the processor. I/O signals are routed using a redistribution layer on the embedded memory device or an organic VHD redistribution layer formed over the embedded memory device when the additional memory device is laterally adjacent to the processor and the I/O pads of the processor and additional memory device are vertically aligned when the additional memory device is on the processor.