A multichip module comprises a carrier, a plurality of chips, an electrical insulating layer, and an electrical interconnect structure. The carrier includes a bottom wall and four side walls defining an internal cavity. The chips are positioned in the internal cavity, with each chip including a plurality of bond pads. The electrical insulating layer is formed from electrically insulating material and is positioned on an upper surface of the carrier and the chips. The electrical interconnect structure includes a plurality of interconnect traces, with each interconnect trace formed from electrically conductive material and electrically connected to a first bond pad on a first chip and a second bond pad on a second chip. Each interconnect trace includes a bridge having a segment that is spaced apart from, and positioned above, the electrical insulating layer.

A display device includes a pixel disposed in a display area. The pixel includes a first electrode and a second electrode spaced apart from each other; a light emitting element disposed between the first electrode and the second electrode and including a first end portion and a second end portion; a third electrode disposed on the first end portion of the light emitting element and electrically connecting the first end portion to the first electrode; and a fourth electrode disposed on the second end portion of the light emitting element and electrically connecting the second end portion to the second electrode. An opening is formed in at least one of the first to fourth electrodes and disposed in a first area and a second area that are adjacent to the first end portion and the second end portion of the light emitting element.

A semiconductor package includes a lower encapsulated semiconductor device, a lower redistribution structure, an upper encapsulated semiconductor device, and an upper redistribution structure. The lower redistribution structure is disposed over and electrically connected to the lower encapsulated semiconductor device. The upper encapsulated semiconductor device is disposed over the lower encapsulated semiconductor device and includes a sensor die having a pad and a sensing region, an upper encapsulating material at least laterally encapsulating the sensor die, and an upper conductive via extending through the upper encapsulating material and connected to the lower redistribution structure. The upper redistribution structure is disposed over the upper encapsulated semiconductor device. The upper redistribution structure covers the pad of the sensor die and has an opening located on the sensing region of the sensor die.

An integrated circuit (IC) package is disclosed that contains high density interconnects to connect multiple dies. The IC package includes an encapsulated layer, a first dielectric layer, and a second dielectric layer. The encapsulated layer forms the base of the IC package and includes the multiple dies. The first dielectric layer positioned between the encapsulated layer and the second layer. The first dielectric layer includes vias to connect to the input/ouput pads of active surfaces of the multiple dies. The second dielectric layer includes interconnect layers where at least one of the interconnect layers forms an electrical path to connect at least two of the multiple dies together. According to embodiments of the present disclosure, the IC package enables a high manufacturing yield due to large tolerances allowed for selection of dies. Embodiments of the present disclosure also increase an amount of input/output interconnection between multiple dies in the IC package. Embodiments of the present disclosure further enable lower manufacturing costs because of the use of mature reconstituted dies and redistribution layer technologies and the lack of a need for an interposer to connect multiple dies.

Some embodiments of the invention include a connecting structure between a support and at least one die attached to the support. The die includes a number of die bond pads on a surface of the die. The connecting structure includes a plurality of via and groove combinations. Conductive material is formed in the via and groove combinations to provide connection between the die bond pads and bond pads on the support. Other embodiments are described and claimed.

An electronic package is provided, in which a surface treatment layer is formed on parts of a surface of a functional pad, such that an electronic element is in contact with and bonded to the functional pad and the surface treatment layer via a bonding layer. Therefore, when the electronic package undergoes thermal shock, the surface treatment layer having buffering capability can improve packaging reliability of the electronic package.

An integrated circuit chip includes a front face having an electrical connection pad. An overmolded encapsulation block encapsulates the integrated circuit chip and includes a front layer at least partially covering a front face of the integrated circuit chip. A through-hole the encapsulation block is located above the electrical connection pad of the integrated circuit chip. A wall of the through-hole is covered with an inner metal layer that is joined to the front pad of the integrated circuit chip. A front metal layer covers a local zone of the front face of the front layer, with the front metal layer being joined to the inner metal layer to form an electrical connection. The inner metal layer and the front metal layer are attached or anchored to activated additive particles that are included in the material of the encapsulation block.

This disclosure relates to a new package concept that eliminates the need for epoxy or epoxy solder used in traditional clip/lead frame-based power packages. The disclosure overcomes this disadvantage in clip-based packages by depositing the interconnect structure directly to the bod pads. The formation of the interconnect done at lower temperature leads to lower stress induced onto the die. Another advantage of the present disclosure is that semiconductor dies packaged using a method according to the present disclosure will have smaller footprint as the pads are directly built up/deposited. Another advantage of the method according to the present disclosure is that it allows large scale, i.e., panel level processing. Such a panel may include multiple ICs, or transistor or any other semiconductor devices.

A method of forming a semiconductor device is provided. The method includes placing a semiconductor die and routing structure on a carrier substrate. At least a portion of the semiconductor die and routing structure are encapsulated with an encapsulant. A cavity formed in the encapsulant. A top portion of the routing structure is exposed through the cavity. A conductive trace is formed to interconnect the semiconductor die with the routing structure.

A semiconductor package comprises a substrate, a pad, a first isolation layer, an interconnection layer, and a conductive post. The substrate has a first surface and a second surface opposite the first surface. The pad has a first portion and a second portion on the first surface of the substrate. The first isolation layer is disposed on the first surface and covers the first portion of the pad, and the first isolation layer has a top surface. The interconnection layer is disposed on the second portion of the pad and has a top surface. The conductive post is disposed on the top surface of the first isolation layer and on the top surface of the interconnection layer. The top surface of the first isolation layer and the top surface of the interconnection layer are substantially coplanar.