A method of manufacturing a semiconductor device having first and second main surfaces opposite to each other. The method includes: forming a first electrode at the first main surface of the semiconductor wafer; applying a first tape to the second main surface of the semiconductor wafer; forming roughness at a portion of a surface of the first tape; applying a second tape to an outer peripheral portion of the semiconductor wafer, so as to cover the portion of the surface of the first tape, with the roughness formed thereon, at the second main surface of the semiconductor wafer, to cover a portion of the first main surface of the semiconductor wafer, and to cover a side surface of the semiconductor wafer; heating the semiconductor wafer after the first and second tapes are applied; and subsequently forming a plated film at the surface of the first electrode by a plating treatment.

A method for manufacturing a semiconductor device includes a step of preparing a semiconductor substrate that has a first main surface on one side and a second main surface on the other side, the semiconductor substrate on which a plurality of device forming regions and an intended cutting line that demarcates the plurality of device forming regions are set, a step of forming a first electrode that covers the first main surface in each of the device forming regions, a step of forming a second electrode that covers the second main surface, a step of partially removing the second electrode along the intended cutting line such that the semiconductor substrate is exposed, and forming a removed portion that extends along the intended cutting line, and a step of cutting the semiconductor substrate along the removed portion.

A method of making a semiconductor device may include providing a large semiconductor die comprising conductive interconnects with a first encapsulant disposed over four side surfaces of the large semiconductor die, over the active surface of the large semiconductor die, and around the conductive interconnects. A first build-up interconnect structure may be formed over the large semiconductor die and over the first encapsulant. Vertical conductive interconnects may be formed over the first build-up interconnect structure and around an embedded device mount site. An embedded device comprising through silicon vias (TSVs) may be disposed over the embedded device mount site. A second encapsulant may be disposed over the build-up structure, and around at least five sides of the embedded device. A second build-up structure may be formed disposed over the planar surface and configured to be electrically coupled to the TSVs of the embedded device and the vertical conductive interconnects.

An electronic device includes a non-conductive die attach film on a side of a conductive lead, a semiconductor die having a first side and a lateral side, the first side on the non-conductive die attach film, and the lateral side including striations, and a package structure enclosing the semiconductor die and a portion of the conductive lead. A method includes singulating portions of a non-conductive die attach film on a carrier, attaching a backside of a wafer to the singulated portions of the non-conductive die attach film, and singulating semiconductor dies of the wafer while the backside of the wafer is attached to the singulated portions of the non-conductive die attach film.

Provided are a semiconductor package, in which an underfill material may enter a gap easily, and a method of manufacturing the semiconductor package. Here, the semiconductor package has a die and a plurality of pillars disposed on one surface of the die, and a thickness of the die corresponding to a region having pillars on the one surface of the die is less than a thickness of the die corresponding to a region without pillars on the one surface of the die.

A semiconductor device including: a first level including a plurality of first metal layers; a second level overlaying the first level, where the second level includes at least one single-crystal silicon layer and a plurality of transistors, where each of the plurality of transistors includes a single-crystal channel, where the second level includes a plurality of second metal layers which includes interconnections between the plurality of transistors, the second level is overlaid by an isolation layer; a connective path from the plurality of transistors to the plurality of first metal layers, where at least one of the plurality of transistors includes a second single-crystal channel overlaying a first single-crystal channel, where each of at least one of the plurality of transistors includes at least a two sided gate, where the first single-crystal channel is self-aligned to the second single-crystal channel being processed following a same lithography step.

A method for producing a laminated film for temporary fixation of a semiconductor member to a support member includes providing a first curable resin layer on one surface of a metal foil and providing a second curable resin layer on the other surface of the metal foil to obtain the laminated film. A laminated film used for temporarily fixing a semiconductor member to a support member includes a first curable resin layer, a metal foil, and a second curable resin layer laminated in sequence.

A manufacturing method of an electronic device including following steps is provided. A first substrate is provided. A thermal release adhesive layer is provided on the first substrate. A thinning process is performed on the first substrate to form a first thinned substrate. A cutting process is performed on the first thinned substrate to form a first sub-substrate. The thermal release adhesive layer is separated from the first thinned substrate or the first sub-substrate. In the manufacturing method of the electronic device provided in one or more embodiments of the disclosure, the manufacturing process of the electronic device may be simplified, and/or defects of the resultant electronic device may be reduced.

A method of manufacturing a transfer die for use in a transfer print process. The manufactured transfer die comprises a semiconductor device suitable for bonding to a silicon-on-insulator wafer. The method comprises the steps of providing a non-conductive isolation region in a semiconductor stack, the semiconductor stack comprising a sacrificial layer above a substrate; and etching an isolation trench into the semiconductor stack from an upper surface thereof, such that the isolation trench extends only to a region of the semiconductor stack above the sacrificial layer. The isolation trench and the non-conductive isolation region together separate a bond pad from a waveguide region in the optoelectronic device.

According to one embodiment, a semiconductor device includes: a circuit board; a first semiconductor chip mounted on a face of the circuit board; a resin film covering the first semiconductor chip; and a second semiconductor chip having a chip area larger than a chip area of the first semiconductor chip, the second semiconductor chip being stuck to an upper face of the resin film and mounted on the circuit board. The resin film entirely fits within an inner region of a bottom face of the second semiconductor chip when viewed in a stacking direction of the first and second semiconductor chips.