The present disclosure relates to methods and apparatus for forming thin-form-factor reconstituted substrates and semiconductor device packages for radio frequency applications. The substrate and package structures described herein may be utilized in high-density 2D and 3D integrated devices for 4G, 5G, 6G, and other wireless network systems. In one embodiment, a silicon substrate is structured by laser ablation to include cavities for placement of semiconductor dies and vias for deposition of conductive interconnections. Additionally, one or more cavities are structured to be filled or occupied with a flowable dielectric material. Integration of one or more radio frequency components adjacent the dielectric-filled cavities enables improved performance of the radio frequency elements with reduced signal loss caused by the silicon substrate.

The present disclosure relates to thin-form-factor reconstituted substrates and methods for forming the same. The reconstituted substrates described herein may be utilized to fabricate homogeneous or heterogeneous high-density 3D integrated devices. In one embodiment, a silicon substrate is structured by direct laser patterning to include one or more cavities and one or more vias. One or more semiconductor dies of the same or different types may be placed within the cavities and thereafter embedded in the substrate upon formation of an insulating layer thereon. One or more conductive interconnections are formed in the vias and may have contact points redistributed to desired surfaces of the reconstituted substrate. The reconstituted substrate may thereafter be integrated into a stacked 3D device.

A semiconductor device assembly that includes a semiconductor device positioned over a substrate with a number of electrical interconnections formed between the semiconductor device and the substrate. The surface of the substrate includes a plurality of discrete solder mask standoffs that extend towards the semiconductor device. A thermal compression bonding process is used to melt solder to form the electrical interconnects, which lowers the semiconductor device to contact and be supported by the plurality of discrete solder mask standoffs. The solder mask standoffs permit the application of a higher pressure during the bonding process than using traditional solder masks. The solder mask standoffs may have various polygonal or non-polygonal shapes and may be positioned in pattern to protect sensitive areas of the semiconductor device and/or the substrate. The solder mask standoffs may be an elongated shape that protects areas of the semiconductor device and/or substrate.

The present disclosure relates to thin-form-factor reconstituted substrates and methods for forming the same. The reconstituted substrates described herein may be utilized to fabricate homogeneous or heterogeneous high-density 3D integrated devices. In one embodiment, a silicon substrate is structured by direct laser patterning to include one or more cavities and one or more vias. One or more semiconductor dies of the same or different types may be placed within the cavities and thereafter embedded in the substrate upon formation of an insulating layer thereon. One or more conductive interconnections are formed in the vias and may have contact points redistributed to desired surfaces of the reconstituted substrate. The reconstituted substrate may thereafter be integrated into a stacked 3D device.

A semiconductor device including a clip, and the clip includes a clip slot, and a slug and the slug includes a groove. The clip and the slug are attached by the ultrasonic welding. The groove and the clip slot are at least partially overlapping to form a gas pathway.

A semiconductor processing apparatus includes a process chamber that defines an enclosure. The enclosure includes a substrate support configured to support a substrate and rotate the substrate about a central axis of the process chamber. The substrate support is also configured to move vertically along the central axis and position the substrate at multiple locations in the enclosure. The apparatus also includes one or more UV lamps configured to irradiate a top surface of the substrate supported on the substrate support.

A semiconductor device according to the disclosure includes a substrate, a semiconductor chip provided on the substrate, a nut, a lead frame provided on the semiconductor chip and the nut and screwed to the nut, a nut box accommodating the nut and having an opening which exposes the nut downward formed in a bottom portion and solder provided at least between the semiconductor chip and the substrate or the lead frame.

A semiconductor device includes a semiconductor wafer. A plurality of pillar bumps is formed over the semiconductor wafer. A solder is deposited over the pillar bumps. The semiconductor wafer is singulated into a plurality of semiconductor die after forming the pillar bumps while the semiconductor wafer is on a carrier. An encapsulant is deposited around the semiconductor die and pillar bumps while the semiconductor die remains on the carrier. The encapsulant covers an active surface of the semiconductor die between the pillar bumps.

A semiconductor device includes a semiconductor wafer. A plurality of pillar bumps is formed over the semiconductor wafer. A solder is deposited over the pillar bumps. The semiconductor wafer is singulated into a plurality of semiconductor die after forming the pillar bumps while the semiconductor wafer is on a carrier. An encapsulant is deposited around the semiconductor die and pillar bumps while the semiconductor die remains on the carrier. The encapsulant covers an active surface of the semiconductor die between the pillar bumps.

A semiconductor chip (6) is bonded to a metal pattern (5) of an insulating substrate (2). A recess (12) and a groove (13) are formed on an upper surface of an electrode (7). The groove (13) reaches a side surface of the electrode (7) from the recess (12). First solder (15) is placed in the recess (12). Second solder (17) is provided between an upper surface of the metal pattern (5) and a lower surface of the electrode (7). The first solder (15) and the second solder (17) are melted. The melted first solder (15) are fused to the second solder (17) via the groove (13) to form a solder fillet (14) which bonds the upper surface of the metal pattern (5) to the lower surface of the electrode (7) and covers the upper surface of the electrode (7).