Conventional hybrid photonic integrated circuits (PIC) combine one type of semiconductor platform for the main PIC, and a different type of semiconductor platform for a secondary chip. Conventional mounting processes include forming a recess in the main PIC, and mating electrical connectors from the secondary chip and the main PIC within the recess. Mating the first and second electrical connectors in the recess increases the complexity of forming the main PIC, and hampers heat dissipation from secondary chip through oxide layers in the main PIC. Providing a conductive, e.g. redistribution, layer from the first electrode along the bottom and sides of the recess eliminates the complexity in forming the main PIC, and enables the first electrical connector to be mounted directly onto a more thermally conductive substrate material.

A semiconductor substrate having a through-silicon via with an air gap interposed between the through-silicon via and the semiconductor substrate is provided. An opening is formed partially through the semiconductor substrate. The opening is first lined with a first liner and then the opening is filled with a conductive material. A backside of the semiconductor substrate is thinned to expose the first liner, which is subsequently removed and a second liner formed with a low-k or extra low-k dielectric is formed in its place.

A semiconductor substrate having a through-silicon via with an air gap interposed between the through-silicon via and the semiconductor substrate is provided. An opening is formed partially through the semiconductor substrate. The opening is first lined with a first liner and then the opening is filled with a conductive material. A backside of the semiconductor substrate is thinned to expose the first liner, which is subsequently removed and a second liner formed with a low-k or extra low-k dielectric is formed in its place.

An integrated circuit package includes a die. An electrically conductive layer comprises a redistribution layer (RDL) in the die, or a micro-bump layer above the die, or both. The micro bump layer comprises at least one micro-bump line. A filter comprises the electrically conductive layer. A capacitor comprises an electrode formed in the electrically conductive layer.

A semiconductor device with redistribution layers formed utilizing dummy substrates is disclosed and may include forming a first redistribution layer on a first dummy substrate, forming a second redistribution layer on a second dummy substrate, electrically connecting a semiconductor die to the first redistribution layer, electrically connecting the first redistribution layer to the second redistribution layer, and removing the dummy substrates. The first redistribution layer may be electrically connected to the second redistribution layer utilizing a conductive pillar. An encapsulant material may be formed between the first and second redistribution layers. Side portions of one of the first and second redistribution layers may be covered with encapsulant. A surface of the semiconductor die may be in contact with the second redistribution layer. The dummy substrates may be in panel form. One of the dummy substrates may be in panel form and the other in unit form.

An integrated electronic device includes a semiconductor body and a passivation structure including a frontal dielectric layer bounded by a frontal surface. A conductive region forms a via region, extending into a hole through the frontal dielectric layer. An overlaid redistribution region extends over the frontal surface. A barrier structure includes at least a first barrier region extending into the hole and surrounding the via region. The first barrier region extends over the frontal surface. A first coating layer covers the top and the sides of the redistribution region and a second coating layer covers the first coating layer. A cavity extends between the redistribution region and the frontal surface and is bounded on one side by the first coating layer and on the other by the barrier structure.

Disclosed are a fan-out packaging device and a method of manufacturing the fan-out packaging device, and more particularly a fan-out packaging device using a bridge, the fan-out packaging device including a bridge formed at one side of a fan-out package having two or more dies integrated therein, at least one trace formed at the bridge, and a connection terminal formed at an end of the trace, the connection terminal being in contact with a contact terminal of the fan-out package, wherein the different dies integrated in the fan-out package are electrically connected to each other via the bridge.

Manufacturing method of semiconductor package includes following steps. Bottom package is provided. The bottom package includes a die and a redistribution structure electrically connected to die. A first top package and a second top package are disposed on a surface of the redistribution structure further away from the die. An underfill is formed into the space between the first and second top packages and between the first and second top packages and the bottom package. The underfill covers at least a side surface of the first top package and a side surface of the second top package. A hole is opened in the underfill within an area overlapping with the die between the side surface of the first top package and the side surface of the second top package. A thermally conductive block is formed in the hole by filling the hole with a thermally conductive material.

A package structure includes a redistribution layer (RDL) structure, a die, and an encapsulant. The die is attached to the RDL structure through an adhesive layer. The encapsulant is disposed on the RDL structure and laterally encapsulates the die and the adhesive layer. The encapsulant includes a protruding part extending into the RDL structure and having a bottom surface in contact with the RDL structure.

A multi-device package includes a substrate, at least two device regions, a first redistribution layer, an external chip and a plurality of first connectors. The two device regions are formed from the substrate, and the first redistribution layer is disposed on the substrate and electrically connected to the two device regions. The external chip is disposed on the first redistribution layer, and the first connectors are interposed between the first redistribution layer and the external chip to interconnect the two.