The present disclosure provides a semiconductor device, a method of manufacturing the semiconductor device and a mothed of method of manufacturing a semiconductor device assembly. The semiconductor device includes a substrate, a bonding dielectric disposed on the substrate, a first conductive feature disposed in the bonding dielectric, an air gap disposed in the bonding dielectric to separate a portion of a periphery of the first conductive feature from the bonding dielectric, and a second conductive feature including a base disposed in the bonding dielectric and a protrusion stacked on the base.

Embodiments of the invention relate generally to directed self-assembly (DSA) and, more particularly, to the DSA of electronic components using diamagnetic levitation.

Provided are an apparatus for manufacturing a semiconductor device and a method of manufacturing a semiconductor package using the same. The manufacturing apparatus may include a base with a plurality of through holes and weight blocks respectively bound by the through holes.

An assembly includes a substrate; a coating including a Bingham fluid disposed on a surface of the substrate; and a discrete component partially embedded in or disposed on the coating including the Bingham fluid. A method includes irradiating a dynamic release structure disposed on a carrier, in which a discrete component is adhered to the dynamic release structure, the irradiating causing the discrete component to be released from the carrier; and receiving the released discrete component into or onto a coating disposed on a surface of a substrate, the coating comprising a Bingham fluid.

A device for applying underfill material into a space between a substrate and a semiconductor chip is provided. The device includes a frame housing configured to cover at least an outer edge area of the semiconductor chip that is bonded to the substrate. The device also includes a sealant attached to the frame housing and configured to contact the outer edge area of the semiconductor chip. The device also includes an outlet made on the frame housing for evacuating the space; and an inlet made on the frame housing for injecting the underfill material to the space.

A jig for manufacturing a semiconductor package includes a bottom piece and an upper piece. The bottom piece includes a base, a support plate, and at least one elastic connector. The support plate is located in a central region of the base. The at least one elastic connector is interposed between the support plate and the base. The upper piece includes a cap and outer flanges. The cap overlays the support plate when the upper piece is disposed on the bottom piece. The outer flanges are disposed at edges of the cap, connected with the cap. The outer flanges contact the base of the bottom piece when the upper piece is disposed on the bottom piece. The cap includes an opening which is a through hole. When the upper piece is disposed on the bottom piece, a vertical projection of the opening falls entirely on the support plate.

The disclosure provides a micro light-emitting diode mass transfer apparatus and method. The micro light-emitting diode mass transfer apparatus includes a solution container, display backplanes, a solution drive assembly and a liquid level control assembly. The solution container contains a transfer solution, and micro light-emitting diodes to be transferred float on the liquid surface of the transfer solution. The display backplanes are submerged in the transfer solution and each provided with a plurality of chip mounting cells; mounting cell opening directions of the plurality of chip mounting cells face toward the micro light-emitting diodes; and at least one of the chip mounting cells is exposed on the liquid surface. The solution drive assembly is disposed in the solution container. The liquid level control assembly is configured to control a liquid level of the transfer solution in the solution container. The liquid level control assembly controls the liquid level of the transfer solution, the solution drive assembly provides a centrifugal force to the transfer solution, and the micro light-emitting diodes are precisely transferred into the corresponding chip mounting cells through the centrifugal force.

A semiconductor package includes a mounting substrate, a first semiconductor chip on the mounting substrate and electrically connected to the mounting substrate, a heat dissipation element on an upper surface of the first semiconductor chip, where the heat dissipation element comprises a sidewall comprising an inclined surface and an upper surface directly connected to the inclined surface, and a package molding portion on the mounting substrate and the inclined surface of the heat dissipation element. The package molding portion exposes at least a portion of the upper surface of the heat dissipation element, the upper surface of the heat dissipation element is parallel to the upper surface of the first semiconductor chip, and an angle formed by the upper surface of the heat dissipation element and the inclined surface of the heat dissipation element is an obtuse angle.

Chip manufacturing, including: assembling at least two chips on a layer; and applying mold compound on the at least two chips to the sides and bottom including flowing around interconnects, thereby leaving the top of each of the at least two chips exposed.

A header for a semiconductor package includes an eyelet having a first surface, a second surface opposite to the first surface, and a through hole penetrating the eyelet from the first surface to the second surface, and a metal block having a pedestal, and a columnar part protruding from the pedestal. The pedestal is inserted into the through hole, so that a portion of the columnar part protrudes from the first surface. The columnar part includes a device mounting surface on which a semiconductor device is mounted. An outer periphery of the pedestal is exposed around the columnar part in a plan view.