An example microelectronic assembly includes a substrate, a bridge die over the substrate, and a die stack between the substrate and the bridge die, the die stack including a logic die and at least one memory die, where the logic die is between the at least one memory die and the bridge die.

A manufacturing method of a semiconductor package includes the following steps. A chip is provided. The chip has an active surface and a rear surface opposite to the active surface. The chip includes conductive pads disposed at the active surface. A first solder-containing alloy layer is formed on the rear surface of the chip. A second solder-containing alloy layer is formed on a surface and at a location where the chip is to be attached. The chip is mounted to the surface and the first solder-containing alloy layer is aligned with the second solder-containing alloy layer. A reflow step is performed on the first and second solder-containing alloy layers to form a joint alloy layer between the chip and the surface.

Disclosed herein are local bridge-last architectures for heterogeneous integration applications and methods for manufacturing the same. The local bridge-last architectures may include a substrate, a first die, a second die, and a material. The substrate may define a cavity. The first and second dies may be connected to the substrate. The material may be attached to the substrate. The material may include a first portion and a second portion. The first portion of the material may be located proximate the first bump and the second portion of the material may be located proximate the second bump.

A port is to couple to another die over a die-to-die (D2D) link and includes a die-tio-die (D2D) adapter to determine, from a set of registers, a set of capabilities of the D2D adapter to advertise in a negotiation with a link partner D2D adapter, where the D2D adapter is on a die and the link partner D2D adapter is located on a remote link partner die. A first capabilities advertisement message is sent to the link partner D2D adapter to advertise the set of capabilities to the link partner D2D adapter. A second capabilities advertisement message is received from the link partner D2D adapter, wherein the second capabilities advertisement message identifies a set of capabilities of the link partner D2D adapter. A final configuration of a D2D link is determined to couple the die to the link partner die.

A device is provided. The device includes a bridge layer over a first substrate. A first connector electrically connecting the bridge layer to the first substrate. A first die is coupled to the bridge layer and the first substrate, and a second die is coupled to the bridge layer.

A semiconductor package includes semiconductor bridge, first and second multilayered structures, first encapsulant, and a pair of semiconductor dies. Semiconductor dies of the pair include semiconductor substrate and conductive pads disposed at front surface of semiconductor substrate. Semiconductor bridge electrically interconnects the pair of semiconductor dies. First multilayered structure is disposed on rear surface of one semiconductor die. Second multilayered structure is disposed on rear surface of the other semiconductor die. First encapsulant laterally wraps first multilayered structure, second multilayered structure and the pair of semiconductor dies. Each one of first multilayered structure and second multilayered structure includes a top metal layer, a bottom metal layer, and an intermetallic layer. Each one of first multilayered structure and second multilayered structure has surface coplanar with surface of first encapsulant. The top metal layers, the bottom metal layers, and the intermetallic layers are in contact with the first encapsulant.

A semiconductor device includes an active silicon connection layer therewithin to integrate a die. A power terminal of a die functional module within the die is connected to a connection point lead-out terminal through a silicon stack connection point. A power gating circuit is arranged within the silicon connection layer. A power output terminal of the power gating circuit within the silicon connection layer is connected to the corresponding connection point lead-out terminal of the die and thus connected to the power terminal of the die function module, so that the power gate circuit can control power supply to the die function module according to an obtained sleep control signal, and the idle die function module can enter into a sleep state to save power.

An integrated circuit device having separate dies for programmable logic fabric and circuitry to operate the programmable logic fabric are provided. A first integrated circuit die may include field programmable gate array fabric. A second integrated circuit die may be coupled to the first integrated circuit die. The second integrated circuit die may include fabric support circuitry that operates the field programmable gate array fabric of the first integrated circuit die.

A pocket integration for high density memory and logic applications and methods of fabrication are described. While various examples are described with reference to FeRAM, capacitive structures formed herein can be used for any application where a capacitor is desired. For instance, the capacitive structure can be used for fabricating ferroelectric based or paraelectric based majority gate, minority gate, and/or threshold gate.

A chip for multi-die communications couplings using a single bridge die, includes: a plurality of dies each including one or more functional circuit blocks; and a first bridge die directly communicatively coupling two or more pairs of dies of the plurality of dies.