Devices and methods for forming a chip package structure including a package substrate, a first adhesive layer attached to a top surface of the package substrate, and a beveled stiffener structure attached to the package substrate. The beveled stiffener structure may include a bottom portion including a tapered top surface, in which a bottom surface of the bottom portion is in contact with the first adhesive layer, a second adhesive layer attached to the tapered top surface, and a top portion including a tapered bottom surface, in which the tapered bottom surface is in contact with the second adhesive layer. The tapered top surface and the tapered bottom surface have a taper angle between 5 degrees and 60 degrees with respect to a top surface of the package substrate.

A package structure includes a circuit substrate, a semiconductor package, a lid structure, a passive device and a barrier structure. The semiconductor package is disposed on and electrically connected to the circuit substrate. The lid structure is disposed on the circuit substrate covering the semiconductor package. The lid structure is attached to the circuit substrate through an adhesive material. The passive device is disposed on the circuit substrate in between the semiconductor package and the lid structure. The barrier structure is separating the passive device from the lid structure and the adhesive material, and the barrier structure is in contact with the adhesive material.

Described herein are integrated circuit (IC) structures, devices, and methods associated with device layer interconnects. For example, an IC die may include a device layer including a transistor array along a semiconductor fin, and a device layer interconnect in the transistor array, wherein the device layer interconnect is in electrical contact with multiple different source/drain regions of the transistor array.

An interconnected semicondcutor subassembly structure and formation thereof. The interconnected semicondcutor subassembly structure includes an interconnect structure, and first and second semicondcutor dies bonded to respective portions of a top surface of the interconnect structure. The interconnected semicondcutor subassembly structure further includes an underfill layer formed within a first gap located between a bottom surface of the first semiconductor die and the first portion the top surface of the interconnect structure, formed within a second gap located between the bottom surface of the second semiconductor die and the second portion of the top surface of the interconnect structure, and formed within a first portion of a third gap located between the first semicondcutor die and the second semicondcutor die. A top surface of the underfill layer formed within the first portion of the third gap located between the first and second semicondcutor dies has a concave meniscus shape.

A package comprises an interposer, comprising an interposer substrate including at least one layer, and a plurality of RDLs formed through at least a portion of the interposer substrate. The package also includes a die device structure comprising at least one device die, and a first test line (TL) structure interposed between the interposer and the die device structure. The first TL structure includes at least one first test line electrically coupled to the at least one device die, at least a portion of the at least one first test line extending beyond a peripheral edge of the die device structure to provide an electrical interface with the at least one device die.

A package structure includes a circuit substrate, a semiconductor package, a first ring structure and a second ring structure. The semiconductor package is disposed on and electrically connected to the circuit substrate. The first ring structure is attached to the circuit substrate and surrounding the semiconductor package, wherein the first ring structure includes a central opening and a plurality of corner openings extending out from corners of the central opening, the semiconductor package is located in the central opening, and the plurality of corner openings is surrounding corners of the semiconductor package.

Provided is a package structure, including a substrate, a chip on the substrate in a flip-chip manner, the chip including a circuit layer, and a side heat dissipator on a side of the chip, the side heat dissipator comprising a heat conduction material, wherein the side heat dissipator is electrically connected to the circuit layer.

A method for manufacturing an electronic package comprises providing at least one electronic component, the at least one electronic component including at least one non-groundable thermal output, providing a substrate in which a ground plane is enclosed in or supported by the substrate, defining at least one thermally conductive pathway extending between an interface exposed on the substrate and the ground plane such that the interface is electrically isolated from the ground plane, and mounting the electronic component to the substrate, the mounting including thermally coupling the output to the interface with at least one thermally conductive member.

The invention provides an integrated circuit device and an adaptive power scaling method thereof to reduce and optimize power consumption. The integrated circuit device includes a first die and a second die, wherein the first die and the second die are stacked into a three-dimensional structure. A power circuit provides a power voltage to a first interface circuit of the first die and a second interface circuit of the second die. The first interface circuit transmits data to the second interface circuit via a die-to-die transfer circuit. The control logic controls the power circuit to adjust the power voltage provided to the first interface circuit and the second interface circuit based on the signal quality of the data received by the second interface circuit.

An electronic structure, an electronic package and a manufacturing method thereof are provided, in which a carrier and an adhesive layer are used to support or fix the electronic structure and the electronic package, and double carriers are used to support or fix the electronic structure and the electronic package, thereby avoiding the warpage problem of the electronic structure and the electronic package.