Provided are: a laminated semiconductor which enables curbing of manufacturing cost; a wafer laminate; a method for manufacturing the laminated semiconductor; an assistance device; and a program. This laminated semiconductor formed by laminating a plurality of chips is provided with: a logic chip; and a memory part that is stacked on the logic chip and has at least one memory chip communicable with the logic chip. The memory chip has: at least two memory bodies that have memory circuits and that are arranged side by side in a direction intersecting the stacking direction; and a connection part which is provided with a prescribed width between the memory bodies and which connects the memory bodies arranged side by side.

Provided is a DRAM including a substrate, first bit line structures, second bit line structures, and word line structures. The substrate has active regions each including pillar structures arranged along a first direction. Two first bit line structures extended along the first direction and buried in the substrate are disposed between the active regions arranged along a second direction. Each second bit line structure is located between the pillar structures and extended through the active regions along the second direction to be disposed on the first bit line structures and electrically connected to the first bit line structures. The word line structures are disposed on and spaced apart from the second bit line structures. Each word line structure extended along the second direction is located between the pillar structures and passes through the active regions arranged along the second direction. A manufacturing method of the DRAM is also provided.

A semiconductor device with high reliability is provided. The semiconductor device includes a first oxide; a first conductor, a second conductor, and a first insulator over the first oxide; and a third conductor over the first insulator. The first conductor includes a first crystal. The second conductor includes a crystal having the same crystal structure as the first crystal. The first crystal has (111) orientation with respect to a surface of the first oxide. The first oxide includes a second crystal. The second crystal has c-axis alignment with respect to a surface where the first oxide is formed. The lattice mismatch degree of the first crystal with respect to the second crystal is lower than or equal to 8 percent.

A semiconductor memory device includes a plurality of memory cell transistors arranged along a common semiconductor layer. Each of the plurality of memory cell transistors comprises a first source/drain region and a second source/drain region formed in the common semiconductor layer; a gate stack formed on a portion of the common semiconductor layer between the first source/drain region and the second source/drain region; and an electrical floating portion in the portion of the common semiconductor layer, a charge state of the electrical floating portion being adapted to adjust a threshold voltage and a channel conductance of the memory cell transistor. The plurality of memory cell transistors connected in series with each other along the common semiconductor layer provide a memory string.

A semiconductor device includes a substrate including a cell area and a background area, the background area surrounding the cell area, a plurality of active patterns in the cell area along a first direction, the active patterns being defined by a device isolation layer, and a background pattern filling the background area to surround the cell area, wherein the active patterns include a first active pattern most adjacent to an edge of the cell area, and a second active pattern separated from the first active pattern in a second direction intersecting the first direction, the second active pattern being separated from the background area.

A method of forming fine patterns includes forming pillars arrayed in rows and columns on an underlying layer and forming a spacer layer on the underlying layer to cover the pillars. Portions of the spacer layer respectively covering the pillars arrayed in each row or in each column are in contact with each other to provide first interstitial s paces disposed between the pillars arrayed in a diagonal direction between a row direction and a column direction as well as to provide cleavages at corners of each of the first interstitial spaces in a plan view. A healing layer is formed on the spacer layer to fill the cleavages of the first interstitial spaces. The healing layer is formed to provide second interstitial spaces respectively located in the first interstitial spaces as well as to include a polymer material.

Examples herein relate to a memory device comprising an eDRAM memory cell, the eDRAM memory cell can include a write circuit formed at least partially over a storage cell and a read circuit formed at least partially under the storage cell; a compute near memory device bonded to the memory device; a processor; and an interface from the memory device to the processor. In some examples, circuitry is included to provide an output of the memory device to emulate output read rate of an SRAM memory device comprises one or more of: a controller, a multiplexer, or a register. Bonding of a surface of the memory device can be made to a compute near memory device or other circuitry. In some examples, a layer with read circuitry can be bonded to a layer with storage cells. Any layers can be bonded together using techniques described herein.

A method of manufacturing a semiconductor memory device and a semiconductor memory device, the method including providing a substrate that includes a cell array region and a peripheral circuit region; forming a mask pattern that covers the cell array region and exposes the peripheral circuit region; growing a semiconductor layer on the peripheral circuit region exposed by the mask pattern such that the semiconductor layer has a different lattice constant from the substrate; forming a buffer layer that covers the cell array region and exposes the semiconductor layer; forming a conductive layer that covers the buffer layer and the semiconductor layer; and patterning the conductive layer to form conductive lines on the cell array region and to form a gate electrode on the peripheral circuit region.

An active region array formation method is provided, including: providing a substrate, and forming a first hard mask layer on a surface of the substrate; patterning the first hard mask layer by using a composite etching process to form an active region shielding layer in the first hard mask layer, a pattern of the active region shielding layer being matched with a pattern of a to-be-formed active region array, wherein the composite etching process includes at least two patterning processes and at least one pattern transfer process; removing the remaining first hard mask layer; and forming the active region array in the substrate through the active region shielding layer.

The disclosed technology is generally directed to semiconductor integrated circuit devices and more particularly to a three-transistor random access memory (3T RAM) device, and a method of fabricating and operating the same. In one aspect, a 3T RAM cell includes a ferroelectric-based field effect transistor (FeFET) having a first gate connected as a storage node and a second transistor connected between the FeFET and a read bit line having a second gate connected to a read word line. The 3T RAM cell also includes a third transistor connected between the storage node and a write bit line having a third gate connected to a write word line.