Techniques and mechanisms for high interconnect density communication with an interposer. In some embodiments, an interposer comprises a substrate and portions disposed thereon, wherein respective inorganic dielectrics of said portions adjoin each other at a material interface, which extends to each of the substrate and a first side of the interposer. A first hardware interface of the interposer spans the material interface at the first side, wherein a first one of said portions comprises first interconnects which couple the first hardware interface to a second hardware interface at the first side. A second one of said portions includes second interconnects which couple one of first hardware interface or the second hardware interface to a third hardware interface at another side of the interposer. In another embodiment, a metallization pitch feature of the first hardware interface is smaller than a corresponding metallization pitch feature of the second hardware interface.

A semiconductor device includes a first semiconductor die, a second semiconductor die including a side surface bonded to the first semiconductor die, such that the second semiconductor die is perpendicular to the first semiconductor die, and a junction circuit for connecting the first semiconductor die to the second semiconductor die.

A semiconductor package includes: a base substrate structure; and a plurality of die groups disposed on a top surface of the based substrate structure, the plurality of die groups comprising a first die group and a second die group neighboring to each other. The first die group includes a plurality of first dies stacked parallel to each other and parallel to a front surface of the first die group, the front surface of the first die group and the top surface intersect at a first edge extending in a first direction. The second die group includes a plurality of second dies stacked parallel to each other and parallel to a front surface of the second die group, the front surface of the second die group and the top surface intersect at a second edge extending in a second direction not parallel to the first direction.

Effective use is achieved of a region in a proximity of a joining plane of semiconductor substrates in a semiconductor device including a stacked semiconductor substrate in which multilayer wiring layers of a plurality of semiconductor substrates are electrically connected to each other. The stacked semiconductor substrate includes plural semiconductor substrates on each of which a multilayer wiring layer is formed. In this stacked semiconductor substrate, the multilayer wiring layers are joined together and electrically connected to each other. In the proximity of a joining plane of the plurality of semiconductor substrates, a conductor is formed. This conductor is formed such that it is electrified in a direction of the joining plane.

A microelectromechanical system (MEMS) structure and method of forming the MEMS device, including forming a first metallization structure over a complementary metal-oxide-semiconductor (CMOS) wafer, where the first metallization structure includes a first sacrificial oxide layer and a first metal contact pad. A second metallization structure is formed over a MEMS wafer, where the second metallization structure includes a second sacrificial oxide layer and a second metal contact pad. The first metallization structure and second metallization structure are then bonded together. After the first metallization structure and second metallization structure are bonded together, patterning and etching the MEMS wafer to form a MEMS element over the second sacrificial oxide layer. After the MEMS element is formed, removing the first sacrificial oxide layer and second sacrificial oxide layer to allow the MEMS element to move freely about an axis.

A method includes bonding a first and a second device die to a third device die, forming a plurality of gap-filling layers extending between the first and the second device dies, and performing a first etching process to etch a first dielectric layer in the plurality of gap-filling layers to form an opening. A first etch stop layer in the plurality of gap-filling layers is used to stop the first etching process. The opening is then extended through the first etch stop layer. A second etching process is performed to extend the opening through a second dielectric layer underlying the first etch stop layer. The second etching process stops on a second etch stop layer in the plurality of gap-filling layers. The method further includes extending the opening through the second etch stop layer, and filling the opening with a conductive material to form a through-via.

A microelectromechanical system (MEMS) structure and method of forming the MEMS device, including forming a first metallization structure over a complementary metal-oxide-semiconductor (CMOS) wafer, where the first metallization structure includes a first sacrificial oxide layer and a first metal contact pad. A second metallization structure is formed over a MEMS wafer, where the second metallization structure includes a second sacrificial oxide layer and a second metal contact pad. The first metallization structure and second metallization structure are then bonded together. After the first metallization structure and second metallization structure are bonded together, patterning and etching the MEMS wafer to form a MEMS element over the second sacrificial oxide layer. After the MEMS element is formed, removing the first sacrificial oxide layer and second sacrificial oxide layer to allow the MEMS element to move freely about an axis.

A package structure including a first semiconductor die, a second semiconductor die, first conductive pillars and a first insulating encapsulation is provided. The first semiconductor die includes a semiconductor substrate, an interconnect structure and a first redistribution circuit structure. The semiconductor substrate includes a first portion and a second portion disposed on the first portion. The interconnect structure is disposed on the second portion, the first redistribution circuit structure is disposed on the interconnect structure, and the lateral dimension of the first portion is greater than the lateral dimension of the second portion. The second semiconductor die is disposed on the first semiconductor die. The first conductive pillars are disposed on the first redistribution circuit structure of the first semiconductor die. The first insulating encapsulation is disposed on the first portion. The first insulating encapsulation laterally encapsulates the second semiconductor die, the first conductive pillars and the second portion.

A semiconductor package includes a first semiconductor chip including a first wiring layer including a first wiring structure and providing a first rear surface, and a first through via for first through via for power electrically connected to the first wiring structure; and a second semiconductor chip including a second wiring layer including a second wiring structure and providing a second rear surface, and a second through via for second through via for power electrically connected to the second wiring structure, wherein the first and second semiconductor chips have different widths, wherein the first semiconductor chip receives power through the first wiring structure and the first through via for first through via for power, wherein the second semiconductor chip receives power through the second wiring structure and the second through via for second through via for power.

A semiconductor device includes a semiconductor chip, pads provided on the semiconductor chip, and insulating patterns provided on the semiconductor chip. The insulating patterns having openings exposing the pads, and conductive patterns are provided in the openings and coupled to the pads. When viewed in a plan view, two opposite ends of the pads are spaced apart from the conductive patterns and two opposite ends of the conductive patterns are spaced apart from the pads. Additionally, when viewed in a plan view, the conductive patterns include a first conductive pattern whose length is parallel to a first direction and a second conductive pattern whose length is parallel to a second direction. The first and second directions are oblique to each other.