A method of forming a semiconductor device includes forming a first interconnect structure over a carrier; forming a thermal dissipation block over the carrier; forming metal posts over the first interconnect structure; attaching a first integrated circuit die over the first interconnect structure and the thermal dissipation block; removing the carrier; attaching a semiconductor package to the first interconnect structure and the thermal dissipation block using first electrical connectors and thermal dissipation connectors; and forming external electrical connectors, the external electrical connectors being configured to transmit each external electrical connection into the semiconductor device, the thermal dissipation block being electrically isolated from each external electrical connection.

In an embodiment, a method includes attaching a first package component to a first carrier, the first package component comprising: an aluminum pad disposed adjacent to a substrate; a sacrificial pad disposed adjacent to the substrate, the sacrificial pad comprising a major surface opposite the substrate, a protrusion of the sacrificial pad extending from the major surface; and a dielectric bond layer disposed around the aluminum pad and the sacrificial pad; attaching a second carrier to the first package component and the first carrier, the first package component being interposed between the first carrier and the second carrier; removing the first carrier; planarizing the dielectric bond layer to comprise a top surface being coplanar with the protrusion; and etching a portion of the protrusion.

A method of forming a semiconductor package includes attaching a first package component to a first carrier; attaching a second package component to the first carrier, the second package component laterally displaced from the first package component; attaching a third package component to the first package component, the third package component being electrically connected to the first package component; removing the first carrier from the first package component and the second package component; after removing the first carrier, performing a first circuit probe test on the second package component to obtain first test data of the second package component; and comparing the first test data of the second package component with prior data of the second package component.

An electronic circuit device according to the present invention includes a base substrate including a wiring layer having a connection part, at least one electronic circuit element, and a re-distribution layer including a photosensitive resin layer, the photosensitive resin layer enclosing a surface on which a connection part of the electronic circuit element is formed and a side surface of the electronic circuit element and embedding a first wiring photo via, a second wiring photo via and a wiring, the first wiring photo via directly connected to the connection part of the electronic circuit element, the second wiring photo via arranged at the outer periphery of the electronic circuit element and directly connected to a connection part of the wiring layer, the wiring electrically connected to the first wiring photo via and the second wiring photo via on a same surface.

A semiconductor package includes a first semiconductor chip including a first surface and a second surface, and including a first active layer on a portion adjacent to the first surface; a first redistribution structure on the first surface of the first semiconductor chip, wherein the first redistribution structure includes a first area and a second area next to the first area; a second semiconductor chip mounted in the first area of the first redistribution structure, including a third surface, which faces the first surface, and a fourth surface, and including a second active layer on a portion adjacent to the third surface; a conductive post mounted in the second area of the first redistribution structure; a molding layer at least partially surrounding the second semiconductor chip and the conductive post on the first redistribution structure; and a second redistribution structure disposed on the molding layer and connected to the conductive post.

In one example, a semiconductor device can comprise (a) an electronic device comprising a device top side, a device bottom side opposite the device top side, and a device sidewall between the device top side and the device bottom side, (b) a first conductor comprising, a first conductor side section on the device sidewall, a first conductor top section on the device top side and coupled to the first conductor side section, and a first conductor bottom section coupled to the first conductor side section, and (c) a protective material covering the first conductor and the electronic device. A lower surface of the first conductor top section can be higher than the device top side, and an upper surface of the first conductor bottom section can be lower than the device top side. Other examples and related methods are also disclosed herein.

A package includes at least one memory component and an insulating encapsulation. The at least one memory component includes a stacked memory structure and a plurality of conductive posts. The stacked memory structure is laterally encapsulated in a molding compound. The conductive posts are disposed on an upper surface of the stacked memory structure. The upper surface of the stacked memory structure is exposed from the molding compound. The insulating encapsulation encapsulates the at least one memory component. The top surfaces of the conductive posts are exposed form the insulating encapsulation. A material of the molding compound is different a material of the insulating encapsulation.

The present invention relates to a method for manufacturing a display device using semiconductor light-emitting elements and a display device. The method for manufacturing a display device according to the present invention comprises the steps of: transferring semiconductor light-emitting elements provided on a growth substrate to an adhesive layer of a temporary substrate; curing the adhesive layer of the temporary substrate; aligning the temporary substrate with a wiring substrate having a wiring electrode and a conductive adhesive layer; compressing the temporary substrate to the wiring substrate so that the semiconductor light-emitting elements bond to the wiring substrate together with the adhesive layer of the temporary substrate, and then removing the temporary substrate; and removing at least a part of the adhesive layer to expose the semiconductor light-emitting elements to the outside, and depositing electrodes on the semiconductor light-emitting elements.

A semiconductor package includes: a first redistribution layer; a first semiconductor chip including a first side and a second side, wherein the first side faces the first redistribution layer; a first sealing material covering the second side of the first semiconductor chip and having a first filler content; a second sealing material formed on the first sealing material and having a second filler content lower than the first filler content; and a second redistribution layer disposed on the second sealing material.

A memory device including a base chip and a memory cube mounted on and connected with the base chip is described. The memory cube includes multiple stacked tiers, and each tier of the multiple stacked tiers includes semiconductor chips laterally wrapped by an encapsulant and a redistribution structure. The semiconductor chips of the multiple stacked tiers are electrically connected with the base chip through the redistribution structures in the multiple stacked tiers. The memory cube includes a thermal path structure extending through the multiple stacked tiers and connected to the base chip. The thermal path structure has a thermal conductivity larger than that of the encapsulant. The thermal path structure is electrically isolated from the semiconductor chips in the multiple stacked tiers and the base chip.