A device package and methods of forming are provided. The device package includes a logic die and a first passivation layer over the logic die. The device package also includes a memory die and a molding compound extending along sidewalls of the logic die and the memory die. The device package also includes a conductive via extending through the molding compound, and a first redistribution layer (RDL) structure over the molding compound. The molding compound extends between a top surface of the memory die and a bottom surface of the first RDL structure. A top surface of the first passivation layer contacts the bottom surface of the first RDL structure.

The interposer-chip-arrangement comprises an interposer (1), metal layers arranged above a main surface (10), a further metal layer arranged above a further main surface (11) opposite the main surface, an electrically conductive interconnection (7) through the interposer, the interconnection connecting one of the metal layers and the further metal layer, a chip (12) arranged at the main surface or at the further main surface, the chip having a contact pad (15), which is electrically conductively connected with the interconnection, a dielectric layer (2) arranged above the main surface with the metal layers embedded in the dielectric layer, a further dielectric layer (3) arranged above the further main surface with the further metal layer embedded in the further dielectric layer, and an integrated circuit (25) in the interposer, the integrated circuit being connected with at least one of the metal layers (5).

A method includes forming a metal layer extending into openings of a dielectric layer to contact a first metal pad and a second metal pad, and bonding a bottom terminal of a component device to the metal layer. The metal layer has a first portion directly underlying and bonded to the component device. A raised via is formed on the metal layer, and the metal layer has a second portion directly underlying the raised via. The metal layer is etched to separate the first portion and the second portion of the metal layer from each other. The method further includes coating the raised via and the component device in a dielectric layer, revealing the raised via and a top terminal of the component device, and forming a redistribution line connecting the raised via to the top terminal.

Provided is a wiring substrate and its manufacturing method in which a thick wiring layer capable of being applied with a large current and a thin wiring layer capable of being subjected to microfabrication coexist in the same layer. The wiring substrate includes: an insulating film located over a first wiring and having a via; and a second wiring over the insulating film. The second wiring has a stacked structure including a first layer and a second layer covering the first layer. The second layer is in direct contact with the first wiring in the via. A thickness of the second layer in a region overlapping with the first layer is different from a thickness of the second layer in the via

A chip package including a first device substrate is provided. The first device substrate is attached to a first surface of a second device substrate. A third device substrate is attached to a second surface of the second device substrate opposite to the first surface. An insulating layer covers the first, second and third device substrates and has at least one opening therein. At least one bump is disposed under a bottom of the opening. A redistribution layer is disposed on the insulating layer and electrically connected to the bump through the opening. A method for forming the chip package is also provided.

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 method includes forming a metal layer extending into openings of a dielectric layer to contact a first metal pad and a second metal pad, and bonding a bottom terminal of a component device to the metal layer. The metal layer has a first portion directly underlying and bonded to the component device. A raised via is formed on the metal layer, and the metal layer has a second portion directly underlying the raised via. The metal layer is etched to separate the first portion and the second portion of the metal layer from each other. The method further includes coating the raised via and the component device in a dielectric layer, revealing the raised via and a top terminal of the component device, and forming a redistribution line connecting the raised via to the top terminal.

A manufacturing method of a semiconductor structure includes covering first and second semiconductor dies with an insulating encapsulant. The first semiconductor die includes an active surface accessibly exposed by the insulating encapsulant and a first conductive terminal distributed at the active surface. The second semiconductor die includes an active surface accessibly exposed by the insulating encapsulant and a second conductive terminal distributed at the active surface. A redistribution circuit layer is formed on the insulating encapsulant and the active surfaces of the first and second semiconductor dies. A conductive trace of the redistribution circuit layer is electrically connected from the first semiconductor die and meanderingly extends to the second semiconductor die, and a ratio of a total length of the conductive trace to a top width of the insulating encapsulant between the first and second semiconductor dies ranges from about 3 to about 10.

A manufacturing method for a semiconductor apparatus sequentially includes bonding a first chip and a second chip together using an adhesive. The first chip includes a first electrode and has a protrusion, and the second chip has a recess. In the bonding, the first chip and the second chip are bonded together in such a manner that the protrusion is positioned into the recess. Further, the method includes forming a through hole in the second chip to expose the first electrode, the first surface being opposite to a second surface having the recess, and forming the second electrode which is electrically connected to the first electrode, in the through hole.

Provided is a wiring substrate and its manufacturing method in which a thick wiring layer capable of being applied with a large current and a thin wiring layer capable of being subjected to microfabrication coexist in the same layer. The wiring substrate includes: an insulating film located over a first wiring and having a via; and a second wiring over the insulating film. The second wiring has a stacked structure including a first layer and a second layer covering the first layer. The second layer is in direct contact with the first wiring in the via. A thickness of the second layer in a region overlapping with the first layer is different from a thickness of the second layer in the via.