In a described example, a device includes an overcoat layer covering an interconnect; an opening in the overcoat layer exposing a portion of a surface of the interconnect; a stud on the exposed portion of the surface of the interconnect in the opening; a surface of the stud approximately coplanar with a surface of the overcoat layer; and a conductive pillar covering the stud and covering a portion of the overcoat layer surrounding the stud, the conductive pillar having a planar and un-dished surface facing away from the stud and the overcoat layer.

An integrated fan-out package includes a die, an encapsulant, a redistribution structure, a seed layer, conductive pillars, and a buffer layer. The encapsulant encapsulates the die. The redistribution structure is over the die and the encapsulant. The redistribution structure includes dielectric layers and conductive patterns. The dielectric layers are sequentially stacked and the conductive patterns are sandwiched between the dielectric layers. The seed layer and the conductive pillars are sequentially stacked over the redistribution structure. The seed layer is directly in contact with the conductive patterns closest to the conductive pillars. The buffer layer is disposed over the redistribution structure. The dielectric layer closest to the conductive pillars and the buffer layer are sandwiched between the seed layer and the conductive patterns closest to the conductive pillars. A Young's modulus of the buffer layer is higher than a Young's modulus of each of the dielectric layers of the redistribution structure.

An integrated circuit isolation product includes a first integrated circuit die. The first integrated circuit die includes a first terminal and a second terminal adjacent to the first terminal. The first terminal and the second terminal are configured as a differential pair of terminals configured to communicate a differential signal across an isolation barrier. The first integrated circuit die includes at least one additional terminal adjacent to the differential pair of terminals. The at least one additional terminal is disposed symmetrically with respect to the differential pair of terminals. The first terminal may have a first parasitic capacitance and the second terminal may have a second parasitic capacitance. The first parasitic capacitance may be substantially the same as the second parasitic capacitance. The at least one additional terminal may be disposed symmetrically with respect to a line of symmetry for the differential pair of terminals.

A method for forming a chip package structure is provided. The method includes bonding a chip to a first surface of a first substrate. The method includes forming a dummy bump over a second surface of the first substrate. The first surface is opposite the second surface, and the dummy bump is electrically insulated from the chip. The method includes cutting through the first substrate and the dummy bump to form a cut substrate and a cut dummy bump. The cut dummy bump is over a corner portion of the cut substrate, a first sidewall of the cut dummy bump is substantially coplanar with a second sidewall of the cut substrate, and a third sidewall of the cut dummy bump is substantially coplanar with a fourth sidewall of the cut substrate.

A method for manufacturing a semiconductor device having an SiC-IGBT and an SiC-MOSFET in a single semiconductor chip, including forming a second conductive-type SiC base layer on a substrate, and selectively implanting first and second conductive-type impurities into surfaces of the substrate and base layer to form a collector region, a channel region in a surficial portion of the SiC base layer, and an emitter region in a surficial portion of the channel region, the emitter region serving also as a source region of the SiC-MOSFET.

Semiconductor packages are provided. One of the semiconductor packages includes a first chip, a second chip, a first adhesive layer, a second adhesive layer and a molding layer. The first adhesive layer is disposed on a first surface of the first chip and a second adhesive layer is disposed on a second surface of the second chip, wherein the first adhesive layer and the second adhesive layer have different thickness, and a total thickness of the first chip and the first adhesive layer is substantially equal to a total thickness of the second chip and the second adhesive layer. The molding layer encapsulates the first chip, the second chip, the first adhesive layer and the second adhesive layer.

A chip on glass package assembly includes a glass substrate, a first type chip, a second type chip and a plurality of connecting lines. The glass substrate includes an active area and a peripheral area connected to the active area. The first type chip is mounted on the peripheral area and including a processor. The second type chip is mounted on the peripheral area and located on a side of the first type chip, wherein the second type chip is different from the first type chip. The connecting lines are disposed on the peripheral area and connecting the first type chip and the second type chip.

An auxiliary carrier and a silicon carbide substrate are provided. The silicon carbide substrate includes an idle layer and a device layer between a main surface at a front side of the silicon carbide substrate and the idle layer. The device layer includes a plurality of laterally separated device regions. Each device region extends from the main surface to the idle layer. The auxiliary carrier is structurally connected with the silicon carbide substrate at the front side. The idle layer is removed. A mold structure is formed that fills a grid-shaped groove that laterally separates the device regions. The device regions are separated, and parts of the mold structure form frame structures laterally surrounding the device regions.

A semiconductor device is provided. The semiconductor device includes an electric field (E-field) suppression layer formed over a termination region. The E-field suppression layer is patterned with openings over metal contact areas. The E-field suppression layer has a thickness such that an electric field strength above the E-field suppression layer is below a dielectric strength of an adjacent material when the semiconductor device is operating at or below a maximum voltage.

Methods of fabricating a semiconductor device are provided. The method includes providing a plurality of semiconductor devices. The method further includes disposing a dielectric dry film on the plurality of semiconductor devices, wherein the dielectric dry film is patterned such that openings in the patterned dielectric dry film are aligned with conductive pads of each of the plurality of semiconductor devices.