A switching device includes a semiconductor substrate having a first element range including first trenches for gates, and an ineffective range not including the first trenches. In an interlayer insulating film, a contact hole is provided within the first element range, and a wide contact hole is provided within the inactive range. The first metal layer contacts the semiconductor substrate within the contact hole and the wide contact hole. The insulating protective film covers an outer peripheral side portion of a bottom surface of a second recess which is provided in a surface of the first metal layer above the wide contact hole. A side surface of an opening provided in a portion of the insulating protective film that includes the first element range is disposed in the second recess. The second metal layer contacts the first metal layer and the side surface of the opening.

A power electronics assembly includes a semiconductor device stack having a wide bandgap semiconductor device, a semiconductor cooling chip thermally coupled to the wide bandgap semiconductor device, and a first electrode electrically coupled to the wide bandgap semiconductor device and positioned between the wide bandgap semiconductor device and the semiconductor cooling chip. The semiconductor cooling chip is positioned between a substrate layer and the wide bandgap semiconductor device. The substrate layer includes a substrate inlet port and a substrate outlet port. An integrated fluid channel system extends between the substrate inlet port and the substrate outlet port and includes a substrate fluid inlet channel extending from the substrate inlet port into the substrate layer, a substrate fluid outlet channel extending from the substrate outlet port into the substrate layer, and one or more cooling chip fluid channels extending into the semiconductor cooling chip.

A semiconductor device according to the present disclosure includes a semiconductor substrate, a first electrode provided on the semiconductor substrate, an insulating layer including a first part provided on an upper surface of the first electrode, a second electrode including a main portion and an eaves portion, the main portion being provided on the upper surface of the first electrode, the eaves portion extending over the first part and solder covering an upper surface of the main portion and a part of an upper surface of the eaves portion wherein the insulating layer includes a second part covering a part of the upper surface of the eaves portion, the part being closer to an end portion of the eaves portion than the part covered by the solder and a third part connecting the first part and the second part and covering the end portion of the eaves portion.

A method of fabricating a semiconductor device is provided, including providing a base substrate and a die stacking unit mounted on the base substrate. Conductive joints are connected between two adjacent dies of the die stacking unit. The method further includes providing dummy micro bumps and dummy pads between the two adjacent dies and between the conductive joints. The dummy micro bumps and the dummy pads are connected to one of the two adjacent dies but not to the other, and the dummy micro bumps are formed on some of the dummy pads but not on all of the dummy pads. In addition, the method includes filling the gaps between the base substrate, all dies of the die stacking unit, the conductive joints, the dummy micro bumps, and the dummy pads with an underfill material by capillary attraction.

The present technology relates to a solid-state image pickup element, electronic equipment, and a semiconductor apparatus that make it possible to reduce a surface reflection in an area in which a slit is formed and improve flare characteristics. A solid-state image pickup element includes a pixel area in which a plurality of pixels is two-dimensionally arranged in a matrix, a chip mounting area in which a chip is flip-chip mounted, and a dam area that is arranged around the chip mounting area and in which one or more slits that block an outflow of a resin are formed. In the dam area, the same OCL as that in the pixel area is formed. The present technology can be applied to a solid-state image pickup element etc. in which a chip is flip-chip mounted, for example.

A technique capable of improving a performance of a semiconductor detector is provided. The semiconductor detector is made based on injection of an underfill into a gap between a first semiconductor chip and a second semiconductor chip in a flip-chip connection state, but the underfill is not formed in periphery of a connection structure connecting a reading electrode pad and a gate terminal through a bump electrode.

Embodiments described herein may be related to apparatuses, processes, and techniques related to hydrophobic features to block or slow the spread of epoxy. These hydrophobic features are placed either on a die surface or on a substrate surface to control epoxy spread between the die in the substrate to prevent formation of fillets. Packages with these hydrophobic features may include a substrate, a die with a first side and a second side opposite the first side, the second side of the die physically coupled with a surface of the substrate, and a hydrophobic feature coupled with the second side of the die or the surface of the substrate to reduce a flow of epoxy on the substrate or die. In embodiments, these hydrophobic features may include a chemical barrier or a laser ablated area on the substrate or die. Other embodiments may be described and/or claimed.

A method for manufacturing a structure includes: supplying an active element provided with a front and rear face connected by a contour; assembling the front face and a main face of a support; filling a space of interconnections between the front face and the main face with glue. The method also includes, before the assembling, forming, by a method other than a plasma method, a first passivation layer covering the contour, and made from a first compound that makes it possible to limit the wetting of said contour by the glue regarding the front face and the main face.

A semiconductor package includes a base substrate having a first semiconductor substrate, and a first protective layer covering a top side thereof. A first semiconductor chip is on the first protective layer. A first fillet layer fills a space between the first protective layer and the first semiconductor chip. A first side surface of the base substrate extends in a first direction, and second and third side surfaces extend in a second direction. The base substrate includes two corner regions and a side region between the corner regions. A first protective layer in the side region includes a first side trench which overlaps the first semiconductor chip. A part of the first fillet layer fills the first side trench.

A method for fabricating a bridge chip assembly for interconnecting two or more IC dies is provided. Each of the IC dies has a first region including first connections having a first pitch and has a second region including second connections or connection pads having a second pitch, the first pitch being greater than the second pitch. The method includes: attaching a non-conductive underfill film on an upper surface of at least the second region of each of the IC dies; bonding the second connections/connection pads of a first IC die to corresponding first connection pads/connections of a bridge chip; and bonding the second connections/connection pads of a second IC die to the bridge chip. The bridge chip assembly includes the bridge chip bonded with the first and second IC dies, and the non-conductive underfill film disposed between the bridge chip and the IC dies.