Systems, apparatuses, and methods using wire bonds and direct chip attachment (DCA) features in stacked die packages are described. A stacked die package includes a substrate and at least a first semiconductor die and a second semiconductor die that are vertically stacked above the substrate. An active surface of the first semiconductor die faces an upper surface of the substrate and the first semiconductor die is operably coupled to the substrate by direct chip attachment DCA features. A back side surface of the second semiconductor die faces a back side surface of the first semiconductor die. The second semiconductor die is operably coupled to the substrate by wire bonds extending between an active surface thereof and the upper surface of the substrate.

A method includes providing a first wafer including a first substrate, a first dielectric layer disposed over the first substrate and a first component formed within the first dielectric layer; providing a second wafer including a second substrate, a second dielectric layer disposed over the second substrate, and a second component formed within the second dielectric layer; removing a first portion of the first dielectric layer to form a first recess; removing a second portion of the second dielectric layer to form a second recess; disposing the second wafer over the first wafer to bond the first dielectric layer to the second dielectric layer; removing a third portion of the second substrate and the second dielectric layer to form a third recess coupled to the second recess; and disposing a conductive material to fill the first recess, the second recess and the third recess to form a conductive structure.

A description is given of a power semiconductor module 10 which can be transferred from a normal operating mode to an explosion-free robust short-circuit failure mode. Said power semiconductor module 10 comprises a power semiconductor 1 having metallizations 3 which form potential areas and are separated by insulations and passivations on the top side 2 of said power semiconductor. Furthermore, an electrically conductive connecting layer is provided, on which at least one metal shaped body 4 which has a low lateral electrical resistance and is significantly thicker than the connecting layer is arranged, said at least one metal shaped body being applied by sintering of the connecting layer such that said metal shaped body is cohesively connected to the respective potential area. The metal shaped body 4 is embodied and designed with means for laterally homogenizing a current flowing through it in such a way that a lateral current flow component 5 is maintained until this module switches off in order to avoid an explosion, wherein the metal shaped body 4 has connections 6 having high-current capability. A transition from the operating mode to the robust failure mode then takes place in an explosion-free manner by virtue of the fact that the connections 6 are contact-connected and dimensioned in such a way that in the case of overload currents of greater than a multiple of the rated current of the power semiconductor 1, the operating mode changes to the short-circuit failure mode with connections 6 remaining on the metal shaped body 4 in an explosion-free manner without the formation of arcs.

A semiconductor package includes a leadframe, a semiconductor die attached to the leadframe, and a passive component electrically connected to the semiconductor die through the leadframe. The leadframe includes a cavity in a side of the leadframe opposite the semiconductor die, and at least a portion of the passive component resides within the cavity in a stacked arrangement.

A thermosetting composition for use as an underfill material contains: a mono- or bifunctional acrylic compound; a thermo-radical polymerization initiator; silica; and an elastomer including a 1,2-vinyl group. The thermosetting composition is liquid and has a property of turning, when cured thermally, into a cured product having a relative dielectric constant of 3.2 or less at 25° C. and a dielectric loss tangent of 0.013 or less at 25° C.

The present invention relates to a method for manufacturing an insulating layer which can minimize the degree of warpage caused by polymer shrinkage at the time of curing and secure the stability of a semiconductor chip located therein, and a method for manufacturing a semiconductor package using an insulating layer obtained from the manufacturing method of the insulating layer.

A data processing system includes a first wafer comprising a plurality of first chips, and kerf and crack-stop structures around perimeters of the first chips, and a second wafer comprising a plurality second chips, a plurality of interconnect structures through a connection zone between the second chips, and a plurality of thru silicon vias, wherein the first wafer and the second wafer are bonded face-to-face such that the interconnect structures of the second wafer electrically connect adjacent chip sites of the first wafer and where a pitch of the chips on the first and second wafer are equal.

A MEMS device formed in a first semiconductor substrate is sealed using a second semiconductor substrate. To achieve this, an Aluminum Germanium structure is formed above the first substrate, and a polysilicon layer is formed above the second substrate. The first substrate is covered with the second substrate so as to cause the polysilicon layer to contact the Aluminum Germanium structure. Thereafter, eutectic bonding is performed between the first and second substrates so as to cause the Aluminum Germanium structure to melt and form an AlGeSi sealant thereby to seal the MEMS device. Optionally, the Germanium Aluminum structure includes, in part, a layer of Germanium overlaying a layer of Aluminum.

Devices and methods that can facilitate hybrid under-bump metallization components are provided. According to an embodiment, a device can comprise an under-bump metallization component that can comprise a superconducting interconnect component and a solder wetting component. The device can further comprise a solder bump that can be coupled to the superconducting interconnect component and the solder wetting component. In some embodiments, the superconducting interconnect component can comprise a hermetically sealed superconducting interconnect component.

A semiconductor package includes a leadframe, a semiconductor die attached to the leadframe, and a passive component electrically connected to the semiconductor die through the leadframe. The leadframe includes a cavity in a side of the leadframe opposite the semiconductor die, and at least a portion of the passive component resides within the cavity in a stacked arrangement.