Some embodiments of the invention include a connecting structure between a support and at least one die attached to the support. The die includes a number of die bond pads on a surface of the die. The connecting structure includes a plurality of via and groove combinations. Conductive material is formed in the via and groove combinations to provide connection between the die bond pads and bond pads on the support. Other embodiments are described and claimed.

A semiconductor device comprises a first conductive layer. A second conductive layer is formed over the first conductive layer. A semiconductor component is disposed over the first conductive layer. The second conductive layer lies in a plane between a top surface of the semiconductor component and a bottom surface of the semiconductor component. A third conductive layer is formed over the semiconductor component opposite the first conductive layer. The semiconductor device includes a symmetrical structure. A first insulating layer is formed between the first conductive layer and semiconductor component. A second insulating layer is formed between the semiconductor component and third conductive layer. A height of the first insulating layer between the first conductive layer and semiconductor component is between 90% and 110% of a height of the second insulating layer between the semiconductor component and third conductive layer. The semiconductor component includes a passive device.

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 device and method of fabricating are provided. The device includes a substrate having a first side and an opposite second side, a cavity defined within the substrate from the first side, a die coupled to a floor of the cavity and having a conductive pad on a side of the die distal to the floor of the cavity. A laminate layer coupled to the second side of the substrate may be included. A hole may be drilled, at one time, through layers of the device, through the die, and through the conductive pad. The hole extends through and is defined within the laminate layer (if present), the second side of the substrate, the die, and the conductive pad. A conductive material is provided within the hole and extends between and through the laminate layer (if provided), the second side of the substrate, the die, and the conductive pad.

A component carrier and a method of manufacturing the same are disclosed. The component carrier includes a stack having at least one electrically conductive layer structure and/or at least one electrically insulating layer structure, a component embedded in the stack, and at least one vertical through connection extending between two opposing main surfaces of and through the component.

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 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 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 method of manufacturing semiconductor devices such as integrated circuits comprises: providing one or more semiconductor chips having first and second opposed surfaces, coupling the semiconductor chip or chips with a support substrate with the second surface towards the support substrate, embedding the semiconductor chip or chips coupled with the support substrate in electrically-insulating packaging material by providing in the packaging material electrically-conductive passageways. The electrically-conductive passageways comprise: electrically-conductive chip passageways towards the first surface of the at least one semiconductor chip, and/or electrically-conductive substrate passageways towards the support substrate.

A three-dimensional stacking technique performed in a wafer-to-wafer fashion reducing the machine movement in production. The wafers are processed with metallic traces and stacked before dicing into separate die stacks. The traces of each layer of the stacks are interconnected via electroless plating.