Abstract: In a static memory cell configured using four MOS transistors and two load resistance elements, the MOS transistors are formed on diffusion layers formed on a substrate. The diffusion layers serve as memory nodes. The drain, gate and source of the MOS transistors are arranged in the direction orthogonal to the substrate, and the gate surrounds a columnar semiconductor layer. In addition, the load resistance elements are formed by contact plugs. In this way, it is possible to form a SRAM cell with a small area.

Abstract: Provided is a semiconductor device which is capable of preventing an increase in power consumption of an SGT, i.e., a three-dimensional semiconductor transistor, due to an increase in off-leak current. The semiconductor device comprises: a first-conductive type first silicon pillar: a first dielectric surrounding a side surface of the first silicon pillar; a gate surrounding the dielectric; a second silicon pillar provided underneath the first silicon pillar; and a third silicon pillar provided on a top of the first silicon pillar. The second silicon pillar has a second-conductive type high-concentration impurity region formed in a surface thereof except at least a part of a contact surface region with the first silicon pillar, and a first-conductive type impurity region formed therein and surrounded by the second-conductive type high-concentration impurity region.

Abstract: It is intended to provide a semiconductor device including a MOS transistor, comprising: a semiconductor pillar; a bottom doped region formed in contact with a lower part of the semiconductor pillar; a first gate formed around a sidewall of the semiconductor pillar through a first dielectric film therebetween; and a top doped region formed so as to at least partially overlap a top surface of the semiconductor pillar, wherein the top doped region has a top surface having an area greater than that of the top surface of the semiconductor pillar.

Abstract: The semiconductor device includes: a columnar silicon layer on the planar silicon layer; a first n+ type silicon layer formed in a bottom area of the columnar silicon layer; a second n+ type silicon layer formed in an upper region of the columnar silicon layer; a gate insulating film formed in a perimeter of a channel region between the first and second n+ type silicon layers; a gate electrode formed in a perimeter of the gate insulating film, and having a first metal-silicon compound layer; an insulating film formed between the gate electrode and the planar silicon layer, an insulating film sidewall formed in an upper sidewall of the columnar silicon layer; a second metal-silicon compound layer formed in the planar silicon layer; and an electric contact formed on the second n+ type silicon layer.

Abstract: Each pixel of a solid state imaging device comprises: a first semiconductor layer; a second semiconductor layer; a third semiconductor layer and fourth semiconductor layer formed on the lateral side of the upper region of the second layer not to be in contact with the top surface of the second semiconductor layer; a gate conductor layer formed on the lower side of the second semiconductor layer; a conductor electrode formed on the side of the fourth semiconductor layer via an insulating film; and a fifth semiconductor layer formed on the top surface of the second semiconductor layer, wherein at least the third semiconductor layer, upper region of the second semiconductor layer, fourth semiconductor layer, and fifth semiconductor layer are formed in the shape of an island. A specific voltage is applied to the conductor electrode to accumulate holes in the surface region of the fourth semiconductor layer.

Abstract: In contrast to a conventional planar CMOS technique in design and fabrication for a field-effect transistor (FET), the present invention provides an SGT CMOS device formed on a conventional substrate using various crystal planes in association with a channel type and a pillar shape of an FET, without a need for a complicated device fabrication process. Further, differently from a design technique of changing a surface orientation in each planar FET, the present invention is designed to change a surface orientation in each SGT to achieve improvement in carrier mobility. Thus, a plurality of SGTs having various crystal planes can be formed on a common substrate to achieve a plurality of different carrier mobilities so as to obtain desired performance.

Abstract: It is intended to provide a method of producing a semiconductor device, comprising the steps of: providing a substrate on one side of which at least one semiconductor pillar stands; forming a first dielectric film to at least partially cover a surface of the at least one semiconductor pillar; forming a conductive film on the first dielectric film; removing by etching a portion of the conductive film located on a top surface and along an upper portion of a side surface of the semiconductor pillar; forming a protective film on at least a part of the top surface and the upper portion of the side surface of the semiconductor pillar; etching back the protective film to form a protective film-based sidewall on respective top surfaces of the conductive film and the first dielectric film each located along the side surface of the semiconductor pillar; forming a resist pattern for forming a gate line in such a manner that at least a portion of the resist pattern is formed on the top surface of the semiconductor pillar

Abstract: A method for producing a semiconductor device includes a step of forming a conductor layer and a first semiconductor layer containing a donor impurity or an acceptor impurity on a first semiconductor substrate; a step of forming a second insulating layer so as to cover the first semiconductor layer; a step of thinning the first semiconductor substrate to a predetermined thickness; a step of forming, from the first semiconductor substrate, a pillar-shaped semiconductor having a pillar-shaped structure on the first semiconductor layer; a step of forming a first semiconductor region in the pillar-shaped semiconductor by diffusing the impurity from the first semiconductor layer; and a step of forming a pixel of a solid-state imaging device with the pillar-shaped semiconductor into which the impurity has been diffused.

Abstract: A nonvolatile semiconductor memory transistor includes an island-shaped semiconductor having a source region, a channel region, and a drain region formed in this order from the silicon substrate side, a floating gate arranged so as to surround the outer periphery of the channel region with a tunnel insulating film interposed between the floating gate and the channel region, a control gate arranged so as to surround the outer periphery of the floating gate with an inter-polysilicon insulating film interposed between the control gate and the floating gate, and a control gate line electrically connected to the control gate and extending in a predetermined direction. The inter-polysilicon insulating film is arranged so as to be interposed between the floating gate and the lower and inner side surfaces of the control gate and between the floating gate and the lower surface of the control gate line.

Abstract: A method for producing a semiconductor device includes preparing a structure having a substrate, a planar semiconductor layer and a columnar semiconductor layer, forming a second drain/source region in the upper part of the columnar semiconductor layer, forming a contact stopper film and a contact interlayer film, and forming a contact layer on the second drain/source region. The step for forming the contact layer includes forming a pattern and etching the contact interlayer film to the contact stopper film using the pattern to form a contact hole for the contact layer and removing the contact stopper film remaining at the bottom of the contact hole by etching. The projection of the bottom surface of the contact hole onto the substrate is within the circumference of the projected profile of the contact stopper film formed on the top and side surface of the columnar semiconductor layer onto the substrate.

Abstract: A semiconductor device according to the present invention comprises a first transistor and a second transistor, and functions as an inverter. The first transistor includes an island semiconductor layer, a first gate insulating film surrounding the periphery of the island semiconductor layer, a gate electrode surrounding the periphery of the first gate insulating film, p+-type semiconductor layers formed in the upper and lower part of the island semiconductor layer, respectively. The second transistor includes the gate electrode, a second gate insulating film surrounding a part of the periphery of the gate electrode, an arcuate semiconductor layer contacting a part of the periphery of the second gate insulating film, n+-type semiconductor layers formed in the upper and lower part of the arcuate semiconductor layer, respectively. A first contact electrically connects the p+-type semiconductor layer in the first transistor and the n+-type semiconductor layer in the second transistor.

Abstract: A pixel includes at least first to fourth semiconductor tiers. The first semiconductor tier includes a first semiconductor region that is electrically connected to a first external circuit, a second semiconductor region, and a third semiconductor region that is isolated from the first semiconductor region by the second semiconductor region and that is electrically connected to a second external circuit. The second semiconductor tier includes a MOS transistor that has insulating films and gate conductive electrodes that are electrically connected to a third external circuit. The third semiconductor tier includes a photodiode formed of the second and fourth semiconductor regions. A junction transistor is formed in which the fourth semiconductor region serves as a gate and in which one of the first and fifth semiconductor regions serves as a drain and the other serves as a source.

Abstract: In a solid-state imaging device, a pixel has a first island-shaped semiconductor (P11) formed on a substrate (1) and a drive output circuit has second island-shaped semiconductors (4a to 4c) formed on the substrate at the same height as that of the first island-shaped semiconductor (P11). The first island-shaped semiconductor (P11) has a first gate insulating layer (6b) formed on an outer periphery thereof and a first gate conductor layer (105a) surrounding the first gate insulating layer (6b). The second island-shaped semiconductors (4a to 4c) have a second gate insulating layer (6a) formed on an outer periphery thereof and a second gate conductor layer (7a) surrounding the second gate insulating layer (6a). The first gate conductor layer (105a) and the second gate conductor layer (7a) have bottom portions located on the same plane.

Abstract: It is an object to provide an SGT production method capable of obtaining a structure for reducing a resistance of a gate, a desired gate length, desired source and drain configurations and a desired diameter of a pillar-shaped semiconductor.

Abstract: It is intended to achieve a sufficiently-small SRAM cell area and a stable operation margin in a CMOS 6T-SRAM comprising a vertical transistor SGT. In a static type memory cell made up using six MOS transistors, each of the MOS transistor constituting the memory cell is formed on a planar silicon layer formed on a buried oxide film, to have a structure where a drain, a gate and a source are arranged in a vertical direction, wherein the gate is formed to surround a pillar-shaped semiconductor layer. The planar silicon layer comprises a first active region having a first conductive type, and a second active region having a second conductive type. The first and second active regions are connected to each other through a silicide layer formed in a surface of the planar silicon layer to achieve an SRAM cell having a sufficiently-small area.

Abstract: An island-shaped semiconductor constituting a pixel includes a first semiconductor N+-region formed on a substrate, a second semiconductor P-region formed on the region, third semiconductor N-regions formed on upper lateral sides of the region, insulating layers formed on the outer periphery of the regions and lower lateral sides of the region, gate conductive layers formed on the outer periphery of the insulating layers and functioning as gate electrodes forming a channel in a lower area of the region, light-reflection conductive layers formed on the outer periphery of the N regions and a portion of the insulating layers where the gate conductive layers are not formed, a fifth semiconductor P+-region formed on the region and the regions, and a microlens formed on the region and whose focal point is located near the upper surface of the region.

Abstract: In a static memory cell comprising six MOS transistors, the MOS transistors have a structure in which the drain, gate and source formed on the substrate are arranged in the vertical direction and the gate surrounds the columnar semiconductor layer, the substrate comprises a first active region having a first conductive type and a second active region having a second conductive type, and diffusion layers constructing the active regions are mutually connected via a silicide layer formed on the substrate surface, thereby realizing an SRAM cell with small surface area. In addition, drain diffusion layers having the same conductive type as a first well positioned on the substrate are surrounded by a first anti-leak diffusion layer and a second anti-leak diffusion layer having a conductive type different from the first well and being shallower than the first well, and thereby controlling leakage to the substrate.

Abstract: A method of producing a semiconductor device including a MOS transistor includes steps of forming a plurality of pillar semiconductor layers and forming a gate electrode formed around each of the pillar-shaped semiconductor layers. The method also includes steps of forming a source or drain region in an upper portion of each of the pillar-shaped semiconductor layers and forming a first silicide layer for connecting at least a part of a surface of a drain or source region formed in a planar semiconductor layer.

Abstract: A nonvolatile semiconductor memory transistor includes an island-shaped semiconductor having a source region, a channel region, and a drain region formed in this order from the Si substrate side, a floating gate surrounding the outer periphery of the channel region with a tunnel insulating film interposed therebetween, a control gate surrounding the outer periphery of the floating gate with an inter-polysilicon insulating film interposed therebetween, and a control gate line connected to the control gate and extending in a predetermined direction. The floating gate extends to regions below and above the control gate and to a region below the control gate line. The inter-polysilicon insulating film is interposed between the floating gate and the upper surface, lower surface, and inner side surface of the control gate and between the control gate line and a portion of the floating gate that extends to the region below the control gate line.

Abstract: A method of producing a semiconductor device including a MOS transistor, includes the steps of forming, on a top surface of at least one of semiconductor pillars, an epitaxial layer having a top surface larger in area than the top surface of the at least one of the semiconductor pillars and forming a source region or a drain region so as to be at least partially in the epitaxial layer.