A hybrid bonding structure and a semiconductor including the hybrid bonding structure are provided. The hybrid bonding structure includes a solder ball and a solder paste bonded to the solder ball. The solder paste may include solder particles including at least one of In, Zn, SnBiAg alloy, or SnBi alloy, and ceramic particles. The solder paste may include a flux. The solder particles may include Sn(42.0 wt %)-Ag(0.4 wt %)-Bi(57.5−X) wt %, and the ceramic particles include CeO.sub.2(X) wt %, where 0.05≤X≤0.1.

A method includes bonding a first package component over a second package component, dispensing a first underfill between the first package component and the second package component, and bonding a third package component over the second package component. A second underfill is between the third package component and the second package component. The first underfill and the second underfill are different types of underfills.

The present invention discloses flip-chip bonding method using an anisotropic adhesive polymer. The method includes applying an adhesive polymer solution containing metal particles dispersed therein onto a circuit substrate to form an adhesive polymer layer such that the adhesive polymer layer covers the metal particles; drying the adhesive polymer layer; and positioning an electronic element to be electrically connected to the circuit substrate on the dried adhesive polymer layer and causing dewetting of the polymer from the metal particles.

A flip-chip package and a method for assembling a flip-chip package includes positioning the die on a substrate and introducing an underfill material into a space between the die and the substrate, where a portion of the underfill material extends beyond an edge of the die and forms a fillet that at least partially surrounds the die. The underfill material is cured, and a portion of the fillet is removed to reduce the area of the fillet.

A semiconductor package including a substrate; a semiconductor stack on the substrate; an underfill between the substrate and the semiconductor stack; an insulating layer conformally covering surfaces of the semiconductor stack and the underfill; a chimney on the semiconductor stack; and a molding member surrounding side surfaces of the chimney, wherein the semiconductor stack has a first upper surface that is a first distance from the substrate and a second upper surface that is a second distance from the substrate, the first distance being greater than the second distance, wherein the chimney includes a thermally conductive filler on the first and second upper surfaces of the semiconductor stack, the thermally conductive filler having a flat upper surface; a thermally conductive spacer on the thermally conductive filler; and a protective layer on the thermally conductive spacer, and wherein an upper surface of the thermally conductive spacer is exposed.

A display device includes a first electrode disposed on a substrate, a second electrode disposed on the substrate and spaced apart from the first electrode, at least one light-emitting element extending in a direction, disposed between the first electrode and the second electrode, and electrically connected to the first electrode and the second electrode, and an insulating pattern layer disposed on the first electrode and the second electrode, the insulating pattern layer including a fixer disposed on at least part of the at least one light-emitting element, and a barrier surrounding the at least one light-emitting element.

A stack of electrical components has a first electrical component having a first surface, a second surface that is opposite to the first surface and a side surface that is located between the first surface and the second surface; a second electrical component having a third surface on which the first electrical component is mounted, the third surface facing the second surface and forming a corner portion between the third surface and the side surface; an adhesive layer that bonds the first electrical component to the second electrical component, the adhesive layer has a first portion that is located between the second and third surface and a second portion that is made of a same material as the first portion and that fills the corner portion; and a conductive layer that extends on a side of the side surface, curves along the second portion and extends to the third surface.

Provided is a package structure including a photonic die, an electronic die, a conductive layer, a circuit substrate, and an underfill. The electronic die is bonded on a front side of the photonic die. The conductive layer is disposed on a back side of the photonic die. The conductive layer includes a plurality of conductive pads and a dam structure between the conductive pads and a first sidewall of the photonic die. The circuit substrate is bonded on the back side of the photonic die through a plurality of connectors and the conductive pads. The underfill laterally encapsulates the connectors, the conductive pads, and the dam structure. The underfill at the first sidewall of the photonic die has a first height, the underfill at a second sidewall of the photonic die has a second height, and the first height is lower than the second height.

Provided is a package structure including a photonic die, an electronic die, a conductive layer, a circuit substrate, and an underfill. The electronic die is bonded on a front side of the photonic die. The conductive layer is disposed on a back side of the photonic die. The conductive layer includes a plurality of conductive pads and a dam structure between the conductive pads and a first sidewall of the photonic die. The circuit substrate is bonded on the back side of the photonic die through a plurality of connectors and the conductive pads. The underfill laterally encapsulates the connectors, the conductive pads, and the dam structure. The underfill at the first sidewall of the photonic die has a first height, the underfill at a second sidewall of the photonic die has a second height, and the first height is lower than the second height.

A display panel and method of manufacture are described. In an embodiment, a display substrate includes a pixel area and a non-pixel area. An array of subpixels and corresponding array of bottom electrodes are in the pixel area. An array of micro LED devices are bonded to the array of bottom electrodes. One or more top electrode layers are formed in electrical contact with the array of micro LED devices. In one embodiment a redundant pair of micro LED devices are bonded to the array of bottom electrodes. In one embodiment, the array of micro LED devices are imaged to detect irregularities.