A semiconductor package includes a redistribution substrate having a first side and an opposite second side, a semiconductor chip on the first side of the redistribution substrate, a silicon capacitor on the second side of the redistribution substrate, a plurality of solder balls on the second side of the redistribution substrate and adjacent the silicon capacitor, and a metal pattern in the redistribution substrate and positioned between the silicon capacitor and the solder balls. The metal pattern includes a first portion extending in a first direction, and a second portion connected to the first portion and extending in a second direction different from the first direction.

A bonding structure includes a first layer of first alloy component disposed on a substrate and a first layer of a second alloy component disposed on the first alloy component. The second alloy component has a lower melting temperature than the first alloy component. A second layer of the first alloy component is disposed on the first layer of the second alloy component and a second layer of the second alloy component is disposed on the second layer of the first alloy component.

A bonding structure includes a first layer of first alloy component disposed on a substrate and a first layer of a second alloy component disposed on the first alloy component. The second alloy component has a lower melting temperature than the first alloy component. A second layer of the first alloy component is disposed on the first layer of the second alloy component and a second layer of the second alloy component is disposed on the second layer of the first alloy component.

A method to produce a semiconductor package or system-on-flex package comprising bonding structures for connecting IC/chips to fine pitch circuitry using a solid state diffusion bonding is disclosed. A plurality of traces is formed on a substrate, each respective trace comprising at least four different conductive materials having different melting points and plastic deformation properties, which are optimized for both diffusion bonding of chips and soldering of passives components.

A method to produce a semiconductor package or system-on-flex package comprising bonding structures for connecting IC/chips to fine pitch circuitry using a solid state diffusion bonding is disclosed. A plurality of traces is formed on a substrate, each respective trace comprising five different conductive materials having different melting points and plastic deformation properties, which are optimized for both diffusion bonding of chips and soldering of passives components.

Implementations generally relate to a multisided integrated circuit assembly. In some implementations, an assembly includes an integrated circuit (IC) chip having IC contact terminals. The assembly further includes surface interfaces coupled to the IC chip, where at least one first surface interface and at least one second surface interface of the surface interfaces are configured to couple to a motherboard. The assembly further includes surface contact terminals on the surface interfaces, where the surface contact terminals couple to the IC contact terminals, and where at least one subset of the surface contact terminals also couples to at least one subset of motherboard contact terminals on the motherboard.

The present disclosure relates to an air-cavity package, which includes a bottom substrate, a top substrate, a perimeter wall, a bottom electronic component, a top electronic component, and an external electronic component. The perimeter wall extends from a periphery of a lower side of the top substrate to a periphery of an upper side of the bottom substrate to form a cavity. The bottom electronic component is mounted on the upper side of the bottom substrate and exposed to the cavity. The top electronic component is mounted on the lower side of the top substrate and exposed to the cavity. And the external electronic component is mounted on an upper side of the top substrate, which is opposite the lower side of the top substrate and not exposed to the cavity.

The present disclosure relates to an air-cavity package, which includes a bottom substrate, a top substrate, a perimeter wall, a bottom electronic component, and a top electronic component. The bottom substrate includes a bottom signal via extending through the bottom substrate and the top substrate includes a top signal via extending through the top substrate. The perimeter wall extends between a periphery of the top substrate and a periphery of the bottom substrate to form a cavity. The bottom electronic component is mounted on the bottom substrate, exposed to the cavity, and electrically coupled to the bottom signal via. The top electronic component is mounted on the top substrate, exposed to the cavity, and electrically coupled to the top signal via.

A wiring board includes: a first insulating layer; a first wiring layer formed on a lower surface of the first insulating layer; a first through hole which penetrates the first insulating layer; a first via wiring including: a filling portion formed to fill the first through hole; and a protruding portion protruding upward from an upper surface of the first insulating layer; a second wiring layer including a land, wherein the land includes an outer circumferential portion and a central portion, a second insulating layer formed on the upper surface of the first insulating layer; a second through hole which penetrates the second insulating layer in the thickness direction; a second via wiring formed to fill the second through hole; and a third wiring layer formed on an upper surface of the second insulating layer.

A method to produce a semiconductor package or system-on-flex package comprising bonding structures for connecting IC/chips to fine pitch circuitry using a solid state diffusion bonding is disclosed. A plurality of traces is formed on a substrate, each respective trace comprising five different conductive materials having different melting points and plastic deformation properties, which are optimized for both diffusion bonding of chips and soldering of passives components.