A semiconductor device includes a substrate, a buried doped layer formed on the substrate, a trench gate formed on the buried doped layer, a source region formed adjacent the trench gate, an interlayer dielectric layer formed on the trench gate and the source region, a source contact plug formed to extend and connect to the source region, and a drain contact plug, extending and connecting to the buried doped layer, formed deeper than the source contact plug.

A semiconductor device of the present invention includes: an IGBT including an emitter layer on a first main surface side of a semiconductor substrate and a collector layer on a second main surface side of the semiconductor substrate; a freewheeling diode including an anode layer on the first main surface side of the semiconductor substrate and a cathode layer on the second main surface side of the semiconductor substrate; a well region that is located in a boundary between the IGBT and the freewheeling diode and separates the IGBT and the freewheeling diode; a first electrode located on the first main surface of the semiconductor substrate so as to be connected to the emitter layer, the anode layer, and the well region; a resistance element located between the well region and the first electrode.

A semiconductor device includes a buried insulation layer pattern on a lower substrate. A first semiconductor pattern and a second semiconductor pattern pattern are disposed on on the buried insulation layer pattern. A lower conductive pattern is formed in a lower portion of a first recess between the first and second semiconductor patterns, and the lower conductive pattern may contact lower sidewalls of the first and second semiconductor patterns. A common gate structure formed on the lower conductive pattern fills a remaining portion of the first recess. The first semiconductor pattern may include a first impurity region, a first channel region, and a second impurity region sequentially stacked from an upper surface of the first semiconductor towards the lower substrate. The second semiconductor pattern includes a third impurity region, a second channel region, and a fourth impurity region.

Monolithically stacked VTFET devices having source/drain contacts with increased contact area and dielectric isolation are provided. In one aspect, a stacked VTFET device includes: at least a bottom VTFET below a top VTFET, wherein the bottom VTFET and the top VTFET each includes source/drain regions interconnected by a vertical fin channel, and a gate stack alongside the vertical fin channel; and source/drain contacts to the source/drain regions, wherein at least one of the source/drain contacts is in direct contact with more than one surface of a given one of the source/drain regions. A stacked VTFET device having at least a bottom VTFET1 below a top VTFET1, and a bottom VTFET2 below a top VTFET2, and a method of forming a stacked VTFET device are also provided.

Some embodiments include an integrated assembly having an access device between a storage element and a conductive structure. The access device has channel material which includes semiconductor material. The channel material has a first end and an opposing second end, and has a side extending from the first end to the second end. The first end is adjacent the conductive structure, and the second end is adjacent the storage element. Conductive gate material is adjacent the side of the channel material. A first domed metal-containing cap is over the conductive structure and under the channel material and/or a second domed metal-containing cap is over the channel material and under the storage element. Some embodiments include methods of forming integrated assemblies.

A semiconductor device of the present invention includes a semiconductor layer of a first conductivity type having a cell portion and an outer peripheral portion disposed around the cell portion, formed with a gate trench at a surface side of the cell portion, and a gate electrode buried in the gate trench via a gate insulating film, forming a channel at a portion lateral to the gate trench at ON-time, the outer peripheral portion has a semiconductor surface disposed at a depth position equal to or deeper than a depth of the gate trench, and the semiconductor device further includes a voltage resistant structure having a semiconductor region of a second conductivity type formed in the semiconductor surface of the outer peripheral portion.

A silicon carbide semiconductor device includes an ohmic electrode and a Schottky electrode that are in contact with the drain electrode respectively on the drain electrode and are next to each other; a first conductivity type first withstand voltage holding region in contact with the ohmic electrode on the ohmic electrode; a second conductivity type second withstand voltage holding region in contact with the Schottky electrode on the Schottky electrode and is next to the first withstand voltage holding region; a second conductivity type well region in contact onto the first and second withstand voltage holding regions; a first conductivity type source region selectively provided on a surface layer of the well region; and a gate electrode opposite to a channel region defined by the well region sandwiched between the source region and the first withstand voltage holding region, with a gate oxide film interposed therebetween.

A semiconductor device according to the present invention includes a semiconductor layer, a gate trench defined in the semiconductor layer, a first insulating film arranged on the inner surface of the gate trench, a gate electrode arranged in the gate trench via the first insulating film, and a source layer, a body layer, and a drain layer arranged laterally to the gate trench, in which the first insulating film includes, at least at the bottom of the gate trench, a first portion and a second portion with a film elaborateness lower than that of the first portion from the inner surface of the gate trench in the film thickness direction.

The disclosed technology generally relates to semiconductor devices, and more particularly to a static random access memory (SRAM) having vertical channel transistors and methods of forming the same. In an aspect, a semiconductor device includes a semiconductor substrate and a semiconductor bottom electrode region formed on the substrate and including a first region, a second region and a third region arranged side-by-side. The second region is arranged between the first and the third regions. A first vertical channel transistor, a second vertical channel transistor and a third vertical channel transistor are arranged on the first region, the second region and the third region, respectively. The first, second and third regions are doped such that a first p-n junction is formed between the first and the second regions and a second p-n junction is formed between the second and third regions. A connection region is formed in the bottom electrode region underneath the first, second and third regions, wherein the connection region and the first and third regions are doped with a dopant of a same type. A resistance of a path extending between the first and the third regions through the connection region is lower than a resistance of a path extending between the first and the third regions through the second region. A second aspect is a method of forming the semiconductor device of the first aspect.

A static random access memory (SRAM) cell has first to sixth transistors that are vertical nanowire (VNW) FETs. The second and fifth transistors are placed side by side sequentially on one side in the X direction of the first transistor. The fourth and sixth transistors are placed side by side sequentially on the other side in the X direction of the third transistor. The first and third transistors are placed side by side in the Y direction.