A semiconductor memory device includes a conductive layer on a source side; a first electrode layer provided on the conductive layer; a second electrode layer provided between the conductive layer and the first electrode layer; a semiconductor layer extending through the first electrode in a first direction from the conductive layer to the first electrode layer; a first semiconductor body provided between the conductive layer and the semiconductor layer, the first semiconductor body including first impurities; and a second semiconductor body provided between the conductive layer and the first semiconductor body, the second semiconductor body including second impurities with a higher concentration than a concentration of the first impurities in the first semiconductor body. A diffusion coefficient of the second impurities in the second semiconductor body is smaller than a diffusion coefficient of the second impurities in the first semiconductor body.

An active matrix display device having a pixel structure in which pixel electrodes, gate wirings and source wirings are suitably arranged in the pixel portions to realize a high numerical aperture without increasing the number of masks or the number of steps. The device comprises a gate electrode and a source wiring on an insulating surface, a first insulating layer on the gate electrode and on the source wiring, a semiconductor layer on the first insulating film, a second insulating layer on the semiconductor film, a gate wiring connected to the gate electrode on the second insulating layer, a connection electrode for connecting the source wiring and the semiconductor layer together, and a pixel electrode connected to the semiconductor layer.

A semiconductor device includes a substrate having a memory array region and a peripheral region, isolation layers formed in the peripheral region to define an active region, offset insulating layers separated from each other and formed in the active region, and a gate electrode having edges overlapping with the offset insulating layers and arranged in the active region between the offset insulating layers.

Memory devices, methods of manufacturing the same, and methods of accessing the same are provided. In one embodiment, the memory device may include a substrate, a back gate formed on the substrate, and a transistor. The transistor may include fins formed on opposite sides of the back gate on the substrate and a gate stack formed on the substrate and intersecting the fins. The memory device may further include a back gate dielectric layer formed on side and bottom surfaces of the back gate. The back gate dielectric layer may have a thickness reduced portion at a region facing the fins on one side of the gate stack.

A semiconductor arrangement includes: a substrate; fins formed on the substrate and extending in a first direction; gate stacks formed on the substrate and each extending in a second direction crossing the first direction to intersect at least one of the fins, and dummy gates composed of a dielectric and extending in the second direction; spacers formed on sidewalls of the gate stacks and the dummy gates; and dielectric disposed between first and second ones of the gate stacks in the second direction to electrically isolate the first and second gate stacks. The dielectric is disposed in a space surrounded by respective spacers of the first and second gate stacks which extend integrally. At least a portion of an interval between the first and second gate stacks in the second direction is less than a line interval achievable by lithography in a process of manufacturing the semiconductor arrangement.

A semiconductor device includes a semiconductor substrate having a first region and a second region. The first region includes a first set of fin structures, the first set of fin structures comprising a first set of epitaxial anti-punch-through features of a first conductivity type. The first region further includes a first set of transistors formed over the first set of fin structures. The second region includes a second set of fin structures, the second set of fin structures comprising a second set of epitaxial anti-punch-through features of a second conductivity type opposite to the first conductivity type. The second region further includes a second set of transistors formed over the second set of fin structures. The first set of epitaxial anti-punch-through features and the second set of epitaxial anti-punch-through features are substantially co-planar.

A semiconductor device includes a first source region, a second source region, and a drain region. The first source region includes a first conductivity type that is formed in a semiconductor layer. The second source region includes a second conductivity type that is adjacent to a gate region and formed in the first source region, the second source region being electrically connected to the first source region, and configured such that one end of a first face of the second source region abuts a gate insulating film formed in the gate region and at least a portion of a second face opposite to the first face abuts the first source region. The drain region includes the first conductivity type that is formed adjacent to the gate region in the semiconductor layer with the gate region interposed with the second source region and the drain region.

An integrated circuit having field effect transistors and manufacturing method. One embodiment provides an integrated circuit including a first FET and a second FET. At least one of source, drain, gate of the first FET is electrically connected to the corresponding one of source, drain, gate of the second FET. At least one further of source, drain, gate of the first FET and the corresponding one further of source, drain, gate of the second FET are connected to a circuit element, respectively. A dopant concentration of a body along a channel of each of the first and second FETs has a peak at a peak location within the channel.

Short channel, horizontal gate-all-around (GAA) nanostructure (e.g., nanosheet, nanowire, or the like) transistors, methods of manufacturing and devices formed with the GAA transistors are disclosed herein. According to some methods, the GAA transistors are formed with a guard band for preventing diffusion of APT doping into the channel region, with shallow source/drain depths, and/or with epitaxial growth of the device channel regions after well and APT implantation in the substrate. As such, the GAA transistors are formed to mitigate issues such as bottom sheet voltage threshold (Vt) shift, junction leakage, APT dopant out-diffusion, well proximity effect, APT implant contamination that may be induced by anti-punch through (APT) doping diffusion during fabrication of gate all-around (GAA) transistors. The GAA transistors and methods of manufacturing, however, may be utilized in a wide variety of ways, and may be integrated into a wide variety of devices and technologies.

A method of independently forming source/drain regions in NMOS regions including nanosheet field-effect transistors (NSFETs), NMOS regions including fin field-effect transistors (FinFETs) PMOS regions including NSFETs, and PMOS regions including FinFETs and semiconductor devices formed by the method are disclosed. In an embodiment, a device includes a semiconductor substrate; a first nanostructure over the semiconductor substrate; a first epitaxial source/drain region adjacent the first nanostructure; a first inner spacer layer adjacent the first epitaxial source/drain region, the first inner spacer layer comprising a first material; a second nanostructure over the semiconductor substrate; a second epitaxial source/drain region adjacent the second nanostructure; and a second inner spacer layer adjacent the second epitaxial source/drain region, the second inner spacer layer comprising a second material different from the first material.