An electronics package includes a support substrate, an electrical component having a first surface coupled to a first surface of the support substrate, and an insulating structure coupled to the first surface of the support substrate and sidewalls of the electrical component. The insulating structure has a sloped outer surface. A conductive layer encapsulates the electrical component and the sloped outer surface of the insulating structure. A first wiring layer is formed on a second surface of the support substrate. The first wiring layer is coupled to the conductive layer through at least one via in the support substrate.

A method for making a semiconductor device includes forming rims on first and second dice. The rims extend laterally away from the first and second dice. The second die is stacked over the first die, and one or more vias are drilled through the rims after stacking. The semiconductor device includes redistribution layers extending over at least one of the respective first and second dice and the corresponding rims. The one or more vias extend through the corresponding rims, and the one or more vias are in communication with the first and second dice through the rims.

A semiconductor package structure and a method for forming the same are disclosed. The semiconductor package structure includes a semiconductor die, a molding layer and an inductor. The semiconductor die includes an active surface, a back surface and a sidewall surface between the active surface and the back surface. The molding layer covers the back surface and the sidewall surface of the semiconductor die. The inductor is in the molding layer. The sidewall surface of the semiconductor die faces toward the inductor.

A semiconductor package structure and a method for forming the same are disclosed. The semiconductor package structure includes a semiconductor die, a molding layer and an inductor. The semiconductor die includes an active surface, a back surface and a sidewall surface between the active surface and the back surface. The molding layer covers the back surface and the sidewall surface of the semiconductor die. The inductor is in the molding layer. The sidewall surface of the semiconductor die faces toward the inductor.

A die includes a semiconductor layer, an electrical contact on a first side of the semiconductor layer, a backside electrical contact layer on second side of the semiconductor layer. The die further includes a zinc layer over at least one of the electrical contact or the backside electrical contact layer of the die, and a conversion coating over the zinc layer. The conversion coating includes at least one of zirconium and vanadium. As part of an embedded die package including the die, at least a portion of the conversion coating may adjacent to an electrically insulating substrate of the embedded die package.

A semiconductor structure and a manufacturing method thereof are provided. A semiconductor structure includes a first semiconductor die, an insulating encapsulation laterally encapsulating the first semiconductor die, an electromagnetic shielding structure enclosing the first semiconductor die and a first portion of the insulating encapsulation, and a redistribution structure. The electromagnetic shielding structure includes a first conductive layer and a dielectric frame laterally covering the first conductive layer. The first conductive layer surrounds the first portion of the insulating encapsulation and extends to cover a first side of the first semiconductor die. The dielectric frame includes a first surface substantially leveled with the first conductive layer. The redistribution structure is disposed on a second side of the first semiconductor die opposing to the first side, and the redistribution structure is electrically coupled to the first semiconductor die and the first conductive layer of the electromagnetic shielding structure.

A modular superconducting quantum processor includes a first superconducting chip including a first plurality of qubits each having substantially a first resonance frequency and a second plurality of qubits each having substantially a second resonance frequency, the first resonance frequency being different from the second resonance frequency, and a second superconducting chip including a third plurality of qubits each having substantially the first resonance frequency and a fourth plurality of qubits each having substantially the second resonance frequency. The quantum processor further includes an interposer chip connected to the first superconducting chip and to the second superconducting chip. The interposer chip has interposer coupler elements configured to couple the second plurality of qubits to the fourth plurality of qubits.

A method of forming a package structure includes: forming an inductor comprising a through-via over a carrier; placing a semiconductor device over the carrier; molding the semiconductor device and the through-via in a molding material; and forming a first redistribution layer on the molding material, wherein the inductor and the semiconductor device are electrically connected by the first redistribution layer.

A display device is disclosed. The display device includes a substrate having a plurality of pixels, wherein each of the plurality of pixels includes at least one light emitting chip, and a structure on one side of at least one of the plurality of pixels. A base material of the light emitting chip is the same as a base material of the structure.

A method of making a secure integrated-circuit system comprises providing a first integrated circuit in a first die having a first die size and providing a second integrated circuit in a second die. The second die size is smaller than the first die size. The second die is transfer printed onto the first die and connected to the first integrated circuit, forming a compound die. The compound die is packaged. The second integrated circuit is operable to monitor the operation of the first integrated circuit and provides a monitor signal responsive to the operation of the first integrated circuit. The first integrated circuit can be constructed in an insecure facility and the second integrated circuit can be constructed in a secure facility.