A semiconductor package includes a semiconductor chip including a chip pad and an external bump pad electrically connected to the chip pad of the semiconductor chip. The external bump pad may include a trench portion extending from a perimeter surface of the external bump pad toward a center of the external bump pad. The semiconductor package includes an external connector on the external bump pad, with the external connector including a portion that is in the trench portion of the external bump pad.

A package includes a first redistribution structure, a die, a plurality of conductive structures, an encapsulant, and a second redistribution structure. The first redistribution structure includes a composite dielectric layer, a plurality of under bump metallization patterns, a dielectric layer, and a plurality of conductive patterns. The composite dielectric layer includes a first sub-layer and a second sub-layer stacked on the first sub-layer. The under bump metallization patterns are over the first sub-layer and penetrate through the composite dielectric layer. The dielectric layer is disposed on the second sub-layer of the composite dielectric layer. The conductive patterns are embedded in the dielectric layer. The die and the conductive structures are on the first redistribution structure. The encapsulant encapsulates the die and the conductive structures. The second redistribution structure is over the conductive structures, the encapsulant, and the die.

The present disclosure relates to a semiconductor package including a first semiconductor chip having a first surface on which first connection pads are disposed, and a second surface on which second connection pads are disposed, and including through-vias connected to the second connection pads; a connection structure disposed on the first surface and including a first redistribution layer; a first redistribution disposed on the second surface; and a second semiconductor chip disposed on the connection structure. The first connection pads are connected to a signal pattern of the first redistribution layer, and the second connection pads are connected to at least one of a power pattern and a ground pattern of the second redistribution layer.

The present disclosure relates to a semiconductor package including a first semiconductor chip having a first surface on which first connection pads are disposed, and a second surface on which second connection pads are disposed, and including through-vias connected to the second connection pads; a connection structure disposed on the first surface and including a first redistribution layer; a first redistribution disposed on the second surface; and a second semiconductor chip disposed on the connection structure. The first connection pads are connected to a signal pattern of the first redistribution layer, and the second connection pads are connected to at least one of a power pattern and a ground pattern of the second redistribution layer.

A method for forming microvias for packaging applications is disclosed. A sacrificial photosensitive material is developed to form microvias with reduced diameter and improved placement accuracy. The microvias are filled with a conductive material and the surrounding dielectric is removed and replaced with an RDL polymer layer.

A stacked integrated circuit includes a first chip including a first area and a second area that are disposed to be substantially symmetrical to each other in relation to a first rotating axis. The first area includes a first through via set and a first front pad set that are connected by using a first connection method. The second area includes a second through via set and a second front pad set that are connected by using a second connection method. The first through via set and the second through via set are disposed to be substantially symmetrical to each other in relation to the first rotating axis. The first front pad set and the second front pad set are disposed to be substantially symmetrical to each other in relation to the first rotating axis.

A 3D fan-out packaging structure of an interconnection system with ultra-high density and a method for manufacturing the same are disclosed; the packaging structure includes a first insulating layer, first metal solder pads, a metal pillar, a first chip, a second insulating layer, second metal solder pads, a first encapsulating layer, a first rewiring layer, a second chip, a second encapsulating layer, a second rewiring layer, and a solder ball. The packaging structure adopts the “RDL first” process, and non-soldering interfaces between the first and second metal solder pads help achieve bonding with a spacing of 5-10 μm or even less, much smaller than conventional soldering spacings, thus increasing the number of available I/O ports and obtaining a high-density, highly integrated packaging structure. In addition, in the present disclosure, various chips and electronic components can be integrated together, thereby achieving high-performance system-level packaging with higher flexibility and compatibility.

Semiconductor devices and methods of manufacture are described herein. The methods include forming a local organic interconnect (LOI) by forming a stack of conductive traces embedded in a passivation material, forming first and second local contacts over the passivation material, the second local contact being electrically coupled to the first local contact by a first conductive trace of the stack. The methods further include forming a backside redistribution layer (RDL) and a front side RDL on opposite sides of the LOI with TMVs electrically coupling the backside and front side RDLs to one another. First and second external contacts are formed over the backside RDL for mounting of semiconductor devices, the first and second external contacts being electrically connected to one another by the LOI. An interconnect structure is attached to the front side RDL for further routing. External connectors electrically coupled to the external contacts at the backside RDL.

Provided herein include various examples of a method for manufacturing aspects of an apparatus, a sensor system. The method may include obtaining a first carrier bonded to an upper surface of the silicon wafer. This wafer includes through silicon vias (TSVs) extended through openings in a passivation stack, with electrical contacts coupled to portions of the TSVs exposed through these openings. The method may include de-bonding the first carrier from the upper surface of the silicon wafer. The method may include dicing the silicon wafer into subsections comprising dies.

A method for forming microvias for packaging applications is disclosed. A sacrificial photosensitive material is developed to form microvias with reduced diameter and improved placement accuracy. The microvias are filled with a conductive material and the surrounding dielectric is removed and replaced with an RDL polymer layer.