A substrate includes a through cavity. A heat sink is mounted so as to close one end of the through cavity. An integrated circuit (IC) chip is also mounted in the cavity. Conductive wires provide an electrical connection between pads on an upper surface of the IC chip and metallizations on the substrate. The mounted heat sink is positioned within the substrate in one implementation and positioned mounted to a back surface of the substrate in another implementation.

The present disclosure provides a semiconductor package including a substrate, a display unit, a flexible circuit board, a driving circuit, and a memory. The substrate has a first surface and a second surface opposite to each other, and the first surface has a display region and a bonding region. The display unit is disposed on the display region of the first surface. The flexible circuit board is disposed below the second surface and has a connection portion extended to the bonding region of the first surface. The driving circuit is disposed on the flexible circuit board and electrically connects to the display unit. The memory is disposed on the flexible circuit board and electrically connects to the driving circuit.

A fan-out semiconductor package includes a frame comprising a plurality of wiring layers electrically connected to one another, and having a recessed portion having a stopper layer 112aM disposed on a bottom surface of the recessed portion, and a through-hole penetrating through the stopper layer; a semiconductor chip having an active surface on which a connection pad is disposed and an inactive surface opposing the active surface, and disposed in the recessed portion such that the inactive surface opposes the stopper layer; an encapsulant covering at least portions of the frame and the inactive surface of the semiconductor chip, and filling at least a portion of the recessed portion; and an interconnect structure disposed on the frame and the active surface of the semiconductor chip, and comprising a redistribution layer electrically connected to the plurality of wiring layers and the connection pad.

A semiconductor package includes a cavity substrate, a semiconductor die, and an encapsulant. The cavity substrate includes a redistribution structure and a cavity layer on an upper surface of the redistribution structure. The redistribution structure includes pads on the upper surface, a lower surface, and sidewalls adjacent the upper surface and the lower surface. The cavity layer includes an upper surface, a lower surface, sidewalls adjacent the upper surface and the lower surface, and a cavity that exposes pads of the redistribution structure. The semiconductor die is positioned in the cavity. The semiconductor die includes a first surface, a second surface, sidewalls adjacent the first surface and the second surface, and attachment structures that are operatively coupled to the exposed pads. The encapsulant encapsulates the semiconductor die in the cavity and covers sidewalls of the redistribution structure.

A method is provided for fabricating an encapsulated emissive element. Beginning with a growth substrate, a plurality of emissive elements is formed. The growth substrate top surface is conformally coated with an encapsulation material. The encapsulation material may be photoresist, a polymer, a light reflective material, or a light absorbing material. The encapsulant is patterned to form fluidic assembly keys having a profile differing from the emissive element profiles. In one aspect, prior to separating the emissive elements from the handling substrate, a fluidic assembly keel or post is formed on each emissive element bottom surface. In one variation, the emissive elements have a horizontal profile. The fluidic assembly key has horizontal profile differing from the emissive element horizontal profile useful in selectively depositing different types of emissive elements during fluidic assembly. In another aspect, the emissive elements and fluidic assembly keys have differing vertical profiles useful in preventing detrapment.

The vibrator device includes: a base; a circuit element disposed on the base; a vibrating element disposed to at least partially overlap the circuit element in a plan view; and a support substrate that is disposed between the circuit element and the vibrating element and supports the vibrating element. In addition, the vibrating element has a frequency adjustment portion that performs frequency adjustment by removing at least a part of the vibrating element, and the support substrate includes a base portion that supports the vibrating element, a support portion that supports the base portion, a beam portion that couples the base portion the support portion, and a shielding portion that is connected to the beam portion, overlaps the frequency adjustment portion in a plan view, and has light shielding properties.

A semiconductor device, includes: a semiconductor element including an element main surface and an element back surface facing opposite sides in a thickness direction; a wiring part electrically connected to the semiconductor element; an electrode pad electrically connected to the wiring part; a sealing resin configured to cover a part of the semiconductor element; and a first metal layer configured to make contact with the element back surface and exposed from the sealing resin, wherein the semiconductor element overlaps the first metal layer when viewed in the thickness direction.

Substrates, assemblies, and techniques for enabling multi-chip flip chip packages are disclosed herein. For example, in some embodiments, a package substrate may include a first side face; a second side face, wherein the second side face is opposite to the first side face along an axis; a portion of insulating material extending from the first side face to the second side face; wherein a cross-section of the portion of insulating material taken perpendicular to the axis has a stairstep profile. Solder pads may be disposed at base and step surfaces of the portion of insulating material. One or more dies may be coupled to the package substrate (e.g., to form a multi-chip flip chip package), and in some embodiments, additional IC packages may be coupled to the package substrate. In some embodiments, the package substrate may be reciprocally symmetric or approximately reciprocally symmetric.

A semiconductor device includes an insulating carrier structure comprised of an insulating inorganic material. The carrier structure has a receptacle in which a semiconductor chip is disposed. The semiconductor chip has a first side, a second side and a lateral rim. The carrier structure laterally surrounds the semiconductor chip and the lateral rim. The semiconductor device also includes a metal structure on and in contact with the second side of the semiconductor chip and embedded in the carrier structure.

Disclosed are a laser bonding apparatus and a laser bonding method capable of bonding an electronic component to a three-dimensional structure having a regular or irregular shape in a curved portion such as an automobile tail lamp or a headlamp. The laser bonding apparatus and method for a three-dimensional structure may prevent misalignment and poor bonding of the electronic component with respect to the three-dimensional structure.