A semiconductor package includes a lower semiconductor chip and semiconductor chips in a stack on the lower semiconductor chip in a first direction perpendicular to a top surface of the lower semiconductor chip. Connection bumps are between the lower semiconductor chip and a bottommost one of the semiconductor chips and between the semiconductor chips, A protection layer covers a lateral surface of each of the connection bumps. A mold layer is on the lower semiconductor chip and covering lateral surfaces of the semiconductor chips. The mold layer extends between the bottommost one of the semiconductor chips and the lower semiconductor chip and between the semiconductor chips. The protection layer is between the mold layer and the lateral surface of each of the connection bumps.

Embodiments include semiconductor packages and method of forming the semiconductor packages. A semiconductor package includes first waveguides over a package substrate. The first waveguides include first angled conductive layers, first transmission lines, and first cavities. The semiconductor package also includes a first dielectric over the first waveguides and package substrate, second waveguides over the first dielectric and first waveguides, and a second dielectric over the second waveguides and first dielectric. The second waveguides include second angled conductive layers, second transmission lines, and second cavities. The first angled conductive layers are positioned over the first transmission lines and package substrate having a first pattern of first triangular structures. The second angled conductive layers are positioned over the second transmission lines and first dielectric having a second pattern of second triangular structures, where the second pattern is shaped as a coaxial interconnects enclosed with second triangular structures and portions of first dielectric.

Embodiments include semiconductor packages and method of forming the semiconductor packages. A semiconductor package includes first waveguides over a package substrate. The first waveguides include first angled conductive layers, first transmission lines, and first cavities. The semiconductor package also includes a first dielectric over the first waveguides and package substrate, second waveguides over the first dielectric and first waveguides, and a second dielectric over the second waveguides and first dielectric. The second waveguides include second angled conductive layers, second transmission lines, and second cavities. The first angled conductive layers are positioned over the first transmission lines and package substrate having a first pattern of first triangular structures. The second angled conductive layers are positioned over the second transmission lines and first dielectric having a second pattern of second triangular structures, where the second pattern is shaped as a coaxial interconnects enclosed with second triangular structures and portions of first dielectric.

Package assemblies for and methods of packaging integrated circuit chips are described. Disclosed package assemblies have spacers and recessed regions comprising IC chips. Architectural structures are provided that enable, for example, three dimensional (3D) packaging (or system in package (SiP) or multi-chip modules), systems-on-chip 3D packaging, and hybrid 3D bonding. Embodiments of the invention can be used, for example, to create logic-to-memory, memory-to-memory, and logic-to-logic interface stacking assemblies.

A fan-out semiconductor package includes: a frame including insulating layers, wiring layers, and connection via layers, and having a recess portion having a stopper layer; a semiconductor chip having connection pads and disposed in the recess portion so that an inactive surface is connected to the stopper layer; first metal bumps disposed on the connection pads; second metal bumps disposed on an uppermost wiring layer of the wiring layers; an encapsulant covering at least portions of each of the frame, the semiconductor chip, and the first and second metal bumps and filling at least portions of the recess portion; and a connection member disposed on the frame and the active surface of the semiconductor chip and including a redistribution layer electrically connected to the connection pads and the uppermost wiring layer through the first and second metal bumps.

A fan-out semiconductor package includes: a frame including insulating layers, wiring layers, and connection via layers, and having a recess portion having a stopper layer; a semiconductor chip having connection pads and disposed in the recess portion so that an inactive surface is connected to the stopper layer; first metal bumps disposed on the connection pads; second metal bumps disposed on an uppermost wiring layer of the wiring layers; an encapsulant covering at least portions of each of the frame, the semiconductor chip, and the first and second metal bumps and filling at least portions of the recess portion; and a connection member disposed on the frame and the active surface of the semiconductor chip and including a redistribution layer electrically connected to the connection pads and the uppermost wiring layer through the first and second metal bumps.

Package assemblies for and methods of packaging integrated circuit chips are described. Disclosed package assemblies have spacers and recessed regions comprising IC chips. Architectural structures are provided that enable, for example, three dimensional (3D) packaging (or system in package (SiP) or multi-chip modules), systems-on-chip 3D packaging, and hybrid 3D bonding. Embodiments of the invention can be used, for example, to create logic-to-memory, memory-to-memory, and logic-to-logic interface stacking assemblies.

Package assemblies for and methods of packaging integrated circuit chips are described. Disclosed package assemblies have spacers and recessed regions comprising IC chips. Architectural structures are provided that enable, for example, three dimensional (3D) packaging (or system in package (SiP) or multi-chip modules), systems-on-chip 3D packaging, and hybrid 3D bonding. Embodiments of the invention can be used, for example, to create logic-to-memory, memory-to-memory, and logic-to-logic interface stacking assemblies.

In one or more embodiments, a chip may be formed with a first set of contacts on a first surface layer and a second set of contacts on a second surface layer opposite the first surface layer. The first set of contacts may be communication (IO) contacts and the second set of contacts may be power contacts, including ball grid array (BGA) balls and capacitors. A PCB may be configured with a chip receiving area capable of receiving the second set of contacts for various chips.

A semiconductor device is provided with: a semiconductor chip die-bonding mounted face up on a support; an intermediate substrate connecting the semiconductor chip to a plurality of external connection portions; and a plurality of connection bumps connecting the semiconductor chip and the intermediate substrate. The plurality of connection bumps includes a plurality of power supply bumps connected to a plurality of electrode pads on the semiconductor chip for supplying power to the semiconductor chip. The intermediate substrate includes: a plurality of power supply pads connected to the plurality of electrode pads through the plurality of power supply bumps; a bump surface facing the semiconductor chip and having a plurality of power supply pads formed thereon; an external connection surface having a plurality of external connection pads formed thereon connected to the external connection portions; and a capacitor connected to the plurality of power supply bumps.