A semiconductor package includes a lower semiconductor chip having a first surface and a second surface, an upper semiconductor chip on the first surface, a first insulating layer between the first surface and the upper semiconductor chip, a second insulating layer between the first insulating layer and the upper semiconductor chip, and a connection structure penetrating the first insulating layer and the second insulating layer and being connected to the lower semiconductor chip and the upper semiconductor chip. The connection structure includes a first connecting portion and a second connecting portion, which are respectively disposed in the first insulating layer and the second insulating layer. A width of the second connecting portion is greater than a width of the first connecting portion. A thickness of the second connecting portion is greater than a thickness of the first connecting portion.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a first semiconductor structure, a second semiconductor structure, a through semiconductor via, and an insulation layer. The first semiconductor structure includes a first circuit layer and a first main bonding layer in the first circuit layer and substantially coplanar with a front face of the first circuit layer. The second semiconductor structure includes a second circuit layer on the first circuit layer and a second main bonding layer in the second circuit layer, and topologically aligned with and contacted to the first main bonding layer. The through semiconductor via is along the second semiconductor structure and the first and second main bonding layer, and extending to the first circuit layer. The insulation layer is positioned on a sidewall of the through semiconductor via.

A semiconductor structure is provided. The semiconductor structure includes a first semiconductor device. The first semiconductor device includes a first bonding layer formed below a first substrate, a first bonding via formed through the first oxide layer and the first bonding layer, a first dummy pad formed in the first bonding layer. The semiconductor structure includes a second semiconductor device. The second semiconductor device includes a second bonding layer formed over a second substrate, a second bonding via formed through the second bonding layer, and a second dummy pad formed in the second bonding layer. The semiconductor structure includes a bonding structure between the first substrate and the second substrate, wherein the bonding structure includes the first bonding via bonded to the second bonding via and the first dummy pad bonded to the second dummy pad.

A package structure including a semiconductor die, a redistribution layer and a plurality of conductive elements is provided. At least one joint of the joints in the redistribution layer or on the semiconductor die is connected with the conductive element for electrically connecting the redistribution layer, the semiconductor die and the conductive elements. The fabrication methods for forming a package structure are provided.

A semiconductor device comprises a semiconductor chip having a radio-frequency circuit and a radio-frequency terminal, an external radio-frequency terminal, and a non-galvanic connection arranged between the radio-frequency terminal of the semiconductor chip and the external radio-frequency terminal, wherein the non-galvanic connection is designed to transmit a radio-frequency signal.

A memory device including at least one dummy word line over a substrate; a plurality of word lines over the dummy word line; and a plurality of vertical holes extending through the at least one dummy word line and the plurality of word lines in a direction perpendicular to the substrate and classified into channel holes and dummy holes, each of the channel holes being connected to a bit line. The method including performing an erase operation on dummy cells formed as the dummy word line and the dummy holes; verifying the erase operation; and performing a program operation on at least one of the dummy cells such that the at least one dummy cell has a higher threshold voltage than main cells formed as the dummy word line and the channel holes.

A memory device including at least one dummy word line over a substrate; a plurality of word lines over the dummy word line; and a plurality of vertical holes extending through the at least one dummy word line and the plurality of word lines in a direction perpendicular to the substrate and classified into channel holes and dummy holes, each of the channel holes being connected to a bit line. The method including performing an erase operation on dummy cells formed as the dummy word line and the dummy holes; verifying the erase operation; and performing a program operation on at least one of the dummy cells such that the at least one dummy cell has a higher threshold voltage than main cells formed as the dummy word line and the channel holes.

A semiconductor device includes an insulation layer, wires, a semiconductor element, and an encapsulation resin. The insulation layer includes a main surface and a back surface facing opposite in a thickness-wise direction and a side surface formed between the main surface and the back surface in the thickness-wise direction. The wires include an embedded portion embedded in the insulation layer and a redistribution portion formed of a metal film joined to the embedded portion and formed from the back surface to the side surface. The semiconductor element is mounted on the main surface and includes electrodes joined to at least part of the embedded portion of the wires. The encapsulation resin contacts the main surface and covers the semiconductor element.

An interfacial structure, along with methods of forming such, are described. The structure includes a first interfacial layer having a first dielectric layer, a first conductive feature disposed in the first dielectric layer, and a first thermal conductive layer disposed on the first dielectric layer. The structure further includes a second interfacial layer disposed on the first interfacial layer. The second interfacial layer is a mirror image of the first interfacial layer with respect to an interface between the first interfacial layer and the second interfacial layer. The second interfacial layer includes a second thermal conductive layer disposed on the first thermal conductive layer, a second dielectric layer disposed on the second thermal conductive layer, and a second conductive feature disposed in the second dielectric layer.

A first wafer, a method of fabricating thereof and a wafer stack are disclosed. The first wafer includes a first substrate, a first dielectric layer on the first substrate, first metal layers embedded in the first dielectric layer, first switching holes extending partially through the first dielectric layer and exposing the first metal layers, a first interconnection layer filling up the first switching holes and electrically connected to the first metal layers, a first insulating layer residing on surfaces of both the first dielectric layer and the first interconnection layer, first contact holes extending through the first insulating layer and exposing the first interconnection layer, and a second interconnection layer filling up the first contact holes and electrically connected to the first interconnection layer. Filling the first contact holes and the first switching holes with different interconnection layers reduces the difficulty in fabricating interconnection structures for the first metal layers.