Disclosed herein is a method for manufacturing a semiconductor comprising mechanically connecting one or more separate semiconductor components to a common intermediate carrier, arranging the intermediate carrier with respect to a substrate so that, at least for a majority of the semiconductor components, at least one solder pad of a particular semiconductor component lies opposite a solder pad of the substrate associated therewith forming a solder joint, and connecting mutually associated solder pads of the one or more semiconductor components and the substrate by melting and solidifying a solder material arranged between the mutually associated solder pads. A surface tension of the solder material between the mutually associated solder pads of the substrate and the one or more semiconductor components sets a predetermined position of the intermediate carrier relative to the substrate, in which the one or more semiconductor components assume a target position relative to the substrate.

An interconnected semicondcutor subassembly structure and formation thereof. The interconnected semicondcutor subassembly structure includes an interconnect structure, and first and second semicondcutor dies bonded to respective portions of a top surface of the interconnect structure. The interconnected semicondcutor subassembly structure further includes an underfill layer formed within a first gap located between a bottom surface of the first semiconductor die and the first portion the top surface of the interconnect structure, formed within a second gap located between the bottom surface of the second semiconductor die and the second portion of the top surface of the interconnect structure, and formed within a first portion of a third gap located between the first semicondcutor die and the second semicondcutor die. A top surface of the underfill layer formed within the first portion of the third gap located between the first and second semicondcutor dies has a concave meniscus shape.

A package comprises an interposer, comprising an interposer substrate including at least one layer, and a plurality of RDLs formed through at least a portion of the interposer substrate. The package also includes a die device structure comprising at least one device die, and a first test line (TL) structure interposed between the interposer and the die device structure. The first TL structure includes at least one first test line electrically coupled to the at least one device die, at least a portion of the at least one first test line extending beyond a peripheral edge of the die device structure to provide an electrical interface with the at least one device die.

A method of manufacturing an electronic device includes: providing a vapor generating chamber that accommodates a heat transfer fluid; providing a substrate stage within the vapor generating chamber, the substrate stage including a seating surface and suction passages penetrating the substrate stage to be open to the seating surface; loading a substrate on the substrate stage, wherein electronic components are disposed on the substrate via bumps; generating at least a partial vacuum in the suction holes to suction-support the substrate on the seating surface; heating the heat transfer fluid to generate saturated vapor within the vapor generating chamber; and soldering the bumps using the saturated vapor.

A semiconductor chip having at least two electrical contact points which are arranged on a main surface of the semiconductor chip is disclosed, a metallic reservoir layer being applied over the entire surface over or on the electrical contact point. A diffusion barrier layer is applied in direct contact on the metallic reservoir layer, the diffusion barrier layer being arranged offset with respect to the metallic reservoir layer, so that the metallic reservoir layer is partially freely accessible. In this case, the diffusion barrier layer forms an adhesion surface for a solder and/or a first solder component of the solder and/or a second solder component of the solder. Methods for connecting a semiconductor chip to a connection carrier are also given.

A display panel comprising a display substrate having a display area and a pad area disposed around the display area. A connection wire is disposed on the pad area of the display substrate. A signal wire is disposed on the connection wire. A supporter is disposed between the display substrate and the connection wire. The connection wire directly contacts the supporter.

A semiconductor device of an embodiment includes: a first semiconductor element; a first insulating resin that seals the first semiconductor element; a wiring substrate having a pad; a first wiring that extends from the first semiconductor element toward the wiring substrate, and has a first head portion and a first column portion, the first column portion connected to the first semiconductor element and the first head portion exposed on a surface of the first insulating resin; and a first conductive bonding agent that electrically connects the first head portion of the first wiring and the pad. When a surface of the first head portion facing a side of the first insulating resin is defined as a first surface. A surface of the first insulating resin on a side of the wiring substrate is defined as a second surface. A distance from a surface of the wiring substrate on a side of the first insulating resin to the first surface is defined as a first distance, and a distance from a surface of the wiring substrate on the side of the first insulating resin to the second surface is defined as a second distance. The first distance is shorter than the second distance.

The present disclosure relates to a flip-chip based moisture-resistant module, which includes a substrate with a top surface, a flip-chip die, a sheet-mold film, and a barrier layer. The flip-chip die has a die body and a number of interconnects, each of which extends outward from a bottom surface of the die body and is attached to the top surface of the substrate. The sheet-mold film directly encapsulates sides of the die body, extends towards the top surface of the substrate, and directly adheres to the top surface of the substrate, such that an air-cavity with a perimeter defined by the sheet-mold film is formed between the bottom surface of the die body and the top surface of the substrate. The barrier layer is formed directly over the sheet-mold film, fully covers the sides of the die body, and extends horizontally beyond the flip-chip die.

A chip includes a semiconductor substrate, integrated circuits with at least portions in the semiconductor substrate, and a surface dielectric layer over the integrated circuits. A plurality of metal pads is distributed substantially uniformly throughout substantially an entirety of a surface of the chip. The plurality of metal pads has top surfaces level with a top surface of the surface dielectric layer. The plurality of metal pads includes active metal pads and dummy metal pads. The active metal pads are electrically coupled to the integrated circuits. The dummy metal pads are electrically decoupled from the integrated circuits.

A semiconductor device assembly can include an assembly substrate having a top surface, a top semiconductor device having a bottom surface, and a plurality of intermediary semiconductor devices. Each of intermediary semiconductor device can be bonded to both the assembly substrate top surface and the top device bottom surface. Each intermediary semiconductor device can also include a semiconductor substrate, a memory array, a first bond pad, a second bond pad, and a conductive column. The first bond pad can electrically couple the assembly substrate to the intermediary semiconductor device; the second bond pad can electrically couple the top semiconductor device to the intermediary semiconductor device; and the conductive column can electrically couple the first bond pad to the second bond pad, and can be exclusive of any electrical connection to the memory array.