The semiconductor memory device includes: a first substrate including a peripheral circuit, first conductive contact patterns connected to the peripheral circuit, and a first upper insulating layer having grooves exposing the first conductive contact patterns; a second substrate including a memory cell array, a second upper insulating layer disposed on the memory cell array, the second upper insulating layer formed between the memory cell array and the first upper insulating layer, second conductive contact patterns protruding through the second upper insulating layer into an opening of the grooves; and conductive adhesive patterns filling the grooves to connect the second conductive contact patterns to the first conductive contact patterns.

Electronic assemblies may be fabricated with interconnects of different types present in multiple locations and comprising fused copper nanoparticles. Each interconnect or a portion thereof comprises a bulk copper matrix formed from fusion of copper nanoparticles or a reaction product formed from copper nanoparticles. The interconnects may comprise a copper-based wire bonding assembly, a copper-based flip chip connection, a copper-based hermetic seal assembly, a copper-based connector between an IC substrate and a package substrate, a copper-based component interconnect, a copper-based interconnect comprising via copper for establishing electrical communication between opposite faces of a package substrate, a copper-based interconnect defining a heat channel formed from via copper, and any combination thereof.

Electronic assemblies may be fabricated with interconnects of different types present in multiple locations and comprising fused copper nanoparticles. Each interconnect or a portion thereof comprises a bulk copper matrix formed from fusion of copper nanoparticles or a reaction product formed from copper nanoparticles. The interconnects may comprise a copper-based wire bonding assembly, a copper-based flip chip connection, a copper-based hermetic seal assembly, a copper-based connector between an IC substrate and a package substrate, a copper-based component interconnect, a copper-based interconnect comprising via copper for establishing electrical communication between opposite faces of a package substrate, a copper-based interconnect defining a heat channel formed from via copper, and any combination thereof.

A semiconductor device having a semiconductor module that includes a first conductor layer and a second conductor layer facing each other, a group of semiconductor elements that are formed between the first and second conductor layers, and are connected to the second conductor layer respectively via a group of conductor blocks, and a circuit board having one end portion thereof located in a space between the semiconductor elements and the second conductor layer. Each semiconductor element includes first and second main electrodes respectively formed on first and second main surfaces thereof, and a control electrode that is formed on the second main surface. The first main electrode is electrically connected to the first conductor layer. The second main electrode is electrically connected to the second conductor layer via the respective conductor block. The circuit board includes a first wiring layer electrically connected to the control electrodes of the semiconductor elements.

A semiconductor device having a semiconductor module that includes a first conductor layer and a second conductor layer facing each other, a group of semiconductor elements that are formed between the first and second conductor layers, and are connected to the second conductor layer respectively via a group of conductor blocks, and a circuit board having one end portion thereof located in a space between the semiconductor elements and the second conductor layer. Each semiconductor element includes first and second main electrodes respectively formed on first and second main surfaces thereof, and a control electrode that is formed on the second main surface. The first main electrode is electrically connected to the first conductor layer. The second main electrode is electrically connected to the second conductor layer via the respective conductor block. The circuit board includes a first wiring layer electrically connected to the control electrodes of the semiconductor elements.

Provided is connection wiring capable of inhibiting connection defects between bumps and pads at the time of semiconductor chip mounting and also allowing an increase in the number of pads. In an area between a pad row in any stage and a pad row in an adjacent stage, a first line 31 is disposed so as to pass under an adjacent second line 32, or a second line 32 is disposed so as to pass over an adjacent first line 31. In this case, three lines are disposed in any area between pads 20 in each stage such that the three lines include a first line 31 situated in the middle, and second lines 32 are situated so as to have the first line 31 positioned therebetween. Thus, the pitch between the pads 20 can be further reduced without reducing the width of the pads 20.

Provided is connection wiring capable of inhibiting connection defects between bumps and pads at the time of semiconductor chip mounting and also allowing an increase in the number of pads. In an area between a pad row in any stage and a pad row in an adjacent stage, a first line 31 is disposed so as to pass under an adjacent second line 32, or a second line 32 is disposed so as to pass over an adjacent first line 31. In this case, three lines are disposed in any area between pads 20 in each stage such that the three lines include a first line 31 situated in the middle, and second lines 32 are situated so as to have the first line 31 positioned therebetween. Thus, the pitch between the pads 20 can be further reduced without reducing the width of the pads 20.

There are provided a semiconductor memory device and a method for manufacturing the same. The semiconductor memory device includes: a first substrate including a peripheral circuit, first conductive contact patterns connected to the peripheral circuit, and a first upper insulating layer having grooves exposing the first conductive contact patterns; a second substrate including a memory cell array, a second upper insulating layer disposed on the memory cell array, the second upper insulating layer formed between the memory cell array and the first upper insulating layer, a second conductive contact patterns protruding through the second upper insulating layer into an opening of the grooves; and conductive adhesive patterns filling the grooves to connect the second conductive contact patterns to the first conductive contact patterns.

There are provided a semiconductor memory device and a method for manufacturing the same. The semiconductor memory device includes: a first substrate including a peripheral circuit, first conductive contact patterns connected to the peripheral circuit, and a first upper insulating layer having grooves exposing the first conductive contact patterns; a second substrate including a memory cell array, a second upper insulating layer disposed on the memory cell array, the second upper insulating layer formed between the memory cell array and the first upper insulating layer, a second conductive contact patterns protruding through the second upper insulating layer into an opening of the grooves; and conductive adhesive patterns filling the grooves to connect the second conductive contact patterns to the first conductive contact patterns.

A semiconductor-mounted product includes a semiconductor package, a wiring substrate, four or more soldered portions, and a resin-reinforced portion. Each of the soldered portions electrically connects the semiconductor package to the wiring of the wiring substrate. The resin-reinforced portion is formed on a side surface of each of the soldered portions. Each of the soldered portions has a first solder region formed closer to the semiconductor package than the wiring substrate and a second solder region formed closer to the wiring substrate than the semiconductor package. A proportion of a void present in a polygon connecting centers of soldered portions located at outermost positions among the soldered portions to a sum of the void and the resin-reinforced portion is from 10% to 99%, inclusive.