A semiconductor device includes a chip carrier and a semiconductor die with a semiconductor portion and a conductive structure. A soldered layer mechanically and electrically connects the chip carrier and the conductive structure at a soldering side of the semiconductor die. At the soldering side an outermost surface portion along an edge of the semiconductor die has a greater distance to the chip carrier than a central surface portion. The conductive structure covers the central surface portion and at least a section of an intermediate surface portion tilted to the central surface portion. Solder material is effectively prevented from coating such semiconductor surfaces that are prone to damages and solder-induced contamination is significantly reduced.

A semiconductor device includes a chip carrier and a semiconductor die with a semiconductor portion and a conductive structure. A soldered layer mechanically and electrically connects the chip carrier and the conductive structure at a soldering side of the semiconductor die. At the soldering side an outermost surface portion along an edge of the semiconductor die has a greater distance to the chip carrier than a central surface portion. The conductive structure covers the central surface portion and at least a section of an intermediate surface portion tilted to the central surface portion. Solder material is effectively prevented from coating such semiconductor surfaces that are prone to damages and solder-induced contamination is significantly reduced.

A semiconductor module comprises a semiconductor device; a substrate, on which the semiconductor device is attached; a molded encasing, into which the semiconductor device and the substrate are molded; at least one power terminal partially molded into the encasing and protruding from the encasing, which power terminal is electrically connected with the semiconductor device; and an encased circuit board at least partially molded into the encasing and protruding over the substrate in an extension direction of the substrate, wherein the encased circuit board comprises at least one receptacle for a pin, the receptacle being electrically connected via the encased circuit board with a control input of the semiconductor device.

An ESD protection device may include: a first vertically integrated ESD protection structure comprising a first semiconductor portion, a first contact region disposed on a first side of the first semiconductor portion and a first terminal exposed on a second side of the first semiconductor portion opposite the first side of the first semiconductor portion, a second vertically integrated ESD protection structure comprising a second semiconductor portion, a second contact region disposed on a first side of the second semiconductor portion and a second terminal exposed on a second side of the second semiconductor portion opposite the first side of the second semiconductor portion, an electrical connection layer, wherein the first vertically integrated ESD protection structure and the second vertically integrated ESD protection structure are disposed on the electrical connection layer laterally separated from each other and are electrically connected with each other anti-serially via the electrical connection layer.

An ESD protection device may include: a first vertically integrated ESD protection structure comprising a first semiconductor portion, a first contact region disposed on a first side of the first semiconductor portion and a first terminal exposed on a second side of the first semiconductor portion opposite the first side of the first semiconductor portion, a second vertically integrated ESD protection structure comprising a second semiconductor portion, a second contact region disposed on a first side of the second semiconductor portion and a second terminal exposed on a second side of the second semiconductor portion opposite the first side of the second semiconductor portion, an electrical connection layer, wherein the first vertically integrated ESD protection structure and the second vertically integrated ESD protection structure are disposed on the electrical connection layer laterally separated from each other and are electrically connected with each other anti-serially via the electrical connection layer.

An apparatus including a carrier substrate configured to move a microelectronic device. The apparatus further includes a rotatable body configured to receive the microelectronic device. Additionally, the apparatus includes a second substrate configured to receive the microelectronic device from the rotatable body.

An apparatus including a carrier substrate configured to move a microelectronic device. The apparatus further includes a rotatable body configured to receive the microelectronic device. Additionally, the apparatus includes a second substrate configured to receive the microelectronic device from the rotatable body.

An insulated gate turn-off thyristor has a layered structure including a p+ layer (e.g., a substrate), an n-epi layer, a p-well, vertical insulated gate regions formed in the p-well, and an p-layer over the p-well and between the gate regions, so that vertical npn and pnp transistors are formed. The p-well has an intermediate highly doped portion. When the gate regions are sufficiently biased, an inversion layer surrounds the gate regions, causing the effective base of the npn transistor to be narrowed to increase its beta. When the product of the betas exceeds one, controlled latch-up of the thyristor is initiated. The p-well's highly doped intermediate region enables improvement in the npn transistor efficiency as well as enabling more independent control over the characteristics of the n-type layer (emitter), the emitter-base junction characteristics, and the overall dopant concentration and thickness of the p-type base.

A 3D semiconductor device including: a first level including a first single-crystal layer, a plurality of first transistors, a first metal layer (includes interconnection of first transistors), and a second metal layer, where first transistors' interconnection includes forming logic gates; a plurality of second transistors disposed atop, at least in part, of logic gates; a plurality of third transistors disposed atop, at least in part, of the second transistors; a third metal layer disposed above, at least in part, the third transistors; a global grid to distribute power and overlaying, at least in part, the third metal layer; a local grid to distribute power to the logic gates, the local grid is disposed below, at least in part, the second transistors, where the second transistors are aligned to the first transistors with less than 40 nm misalignment, where at least one of the second transistors includes a metal gate.

A 3D semiconductor device including: a first level including a single crystal layer and plurality of first transistors; a first metal layer including interconnects between first transistors, where the interconnects between the first transistors includes forming logic gates; a second metal layer atop at least a portion of the first metal layer, second transistors which are vertically oriented, are also atop a portion of the second metal layer; where at least eight of the first transistors are connected in series forming at least a portion of a NAND logic structure, where at least one of the second transistors is at least partially directly atop of the NAND logic structure; and a third metal layer atop at least a portion of the second transistors, where the second metal layer is aligned to the first metal layer with a less than 150 nm misalignment.