Abstract: A memory cell including: an active area having a channel provided between a source and a drain, a first gate provided on a first part of the channel, a portion of a first lateral spacer provided against a lateral flank of the first gate, a part of which forms a second gate provided on a second part of the channel, one of two gates forming a storing gate, the memory cell further including a portion of a second lateral spacer provided against a lateral flank of a block provided on the semi-conductor layer, the second lateral spacer being in contact with the first lateral spacer, the first and second lateral spacers being composed of similar materials, said portion of the second lateral spacer forming a part of an electrical contact pad electrically connected to the second gate.

Abstract: A nonvolatile semiconductor memory fabrication method including forming a first insulating film and a floating gate electrode material on a semiconductor substrate; forming a gate insulating film and a floating gate electrode by etching the first insulating film and the floating gate electrode material, respectively, and forming a groove for an element isolation region by etching the semiconductor substrate; and forming an element region and the element isolation region by burying a second insulating film in the groove and planarizing the second insulating film.

Abstract: According to one embodiment, a columnar semiconductor, a floating gate electrode formed on a side surface of the columnar semiconductor via a tunnel dielectric film, and a control gate electrode formed to surround the floating gate electrode via a block dielectric film are provided.

Abstract: A semiconductor device having a dual trench and methods of fabricating the same, a semiconductor module, an electronic circuit board, and an electronic system are provided. The semiconductor device includes a semiconductor substrate having a cell region including a cell trench and a peripheral region including a peripheral trench. The cell trench is filled with a core insulating material layer, and the peripheral trench is filled with a padding insulating material layer conformably formed on an inner surface thereof and a core insulating material layer formed on an inner surface of the padding insulating material layer. The core insulating material layer has a greater fluidity than the padding insulating material layer.

Abstract: Disclosed is a method of forming memory devices employing halogen ion implantation and diffusion processes. In one illustrative embodiment, the method includes forming a plurality of word line structures above a semiconducting substrate, each of the word line structures comprising a gate insulation layer, performing an LDD ion implantation process to form LDD doped regions in the substrate between the word line structures, performing a halogen ion implantation process to implant atoms of halogen into the semiconducting substrate between the word line structures, and performing at least one anneal process to cause at least some of the atoms of halogen to diffuse into the gate insulation layers on adjacent word line structures.

Abstract: A semiconductor device with a nonvolatile memory is provided which has improved characteristics. The semiconductor device includes a control gate electrode, a memory gate electrode disposed adjacent to the control gate electrode, a first insulating film, and a second insulating film including therein a charge storing portion. Among these components, the memory gate electrode is formed of a silicon film including a first silicon region positioned over the second insulating film, and a second silicon region positioned above the first silicon region. The second silicon region contains p-type impurities, and the concentration of p-type impurities of the first silicon region is lower than that of the p-type impurities of the second silicon region.

Abstract: A non-volatile memory device includes gate structures, an insulation layer pattern, and an isolation structure. Multiple gate structures being spaced apart from each other in a first direction are formed on a substrate. Ones of the gate structures extend in a second direction that is substantially perpendicular to the first direction. The substrate includes active regions and field regions alternately and repeatedly formed in the second direction. The insulation layer pattern is formed between the gate structures and has a second air gap therein. Each of the isolation structures extending in the first direction and having a first air gap between the gate structures, the insulation layer pattern, and the isolation structure is formed on the substrate in each field region.

Abstract: An object is to suppress reading error even in the case where writing and erasing are repeatedly performed. Further, another object is to reduce writing voltage and erasing voltage while increase in the area of a memory transistor is suppressed. A floating gate and a control gate are provided with an insulating film interposed therebetween over a first semiconductor layer for writing operation and erasing operation and a second semiconductor layer for reading operation which are provided over a substrate; injection and release of electrons to and from the floating gate are performed using the first semiconductor layer; and reading is performed using the second semiconductor layer.

Abstract: A floating gate type semiconductor memory device includes a tunnel insulating layer, a floating gate formed on the tunnel insulating layer, a control gate electrode formed over the floating gates, a charge blocking layer formed between the floating gates and the control gate electrode, and a barrier layer formed in one or more areas of an area between the charge blocking layer and the control gate electrode and an area between the floating gate and the charge blocking layer and on an area corresponding to the sidewall of the floating gate.

Abstract: In a method of making a semiconductor device, a gate dielectric is formed over the semiconductor body. A floating gate is formed over the gate dielectric, an insulating region over the floating gate, and a control gate over the insulating region. The gate dielectric, floating gate, insulating region, and control gate constitute a gate stack. A stress is caused in the gate stack, whereby the band gap of the gate dielectric is changed by the stress.

Abstract: According to one embodiment, a nonvolatile semiconductor memory device includes memory transistors, an interlayer insulating film, a peripheral transistor and a sidewall. The memory transistors are formed on a semiconductor substrate. Each of the memory transistors includes a first stack gate which includes a floating gate electrode, a second gate insulating film, and a control gate electrode. The interlayer insulating film is formed between the first stack gates. The interlayer insulating film includes a first air gap. The peripheral transistor is formed on the substrate. The peripheral transistor includes a second stack gate which includes a first gate electrode, a third gate insulating film, and a second gate electrode. The sidewall is formed on a side surface of the second stack gate and includes a second air gap. An upper end of the second air gap is located at a position lower than the third gate insulating film.

Abstract: According to one embodiment, a memory cell includes a charge storage layer. A first air gap is provided between charge storage layers adjacent in a word line direction. A second air gap is provided between charge storage layers adjacent in a bit line direction.

Abstract: According to one embodiment, a part of a buried insulating film buried in a trench is removed; accordingly, an air gap is formed between adjacent floating gate electrodes in a word line direction, and the air gap is formed continuously along the trench in a manner of sinking below a control gate electrode.

Abstract: A non-volatile memory device is provided, including a substrate formed of a single crystalline semiconductor, pillar-shaped semiconductor patterns extending perpendicular to the substrate, a plurality of gate electrodes and a plurality of interlayer dielectric layers alternately stacked perpendicular to the substrate, and a charge spread blocking layer formed between the plurality of gate electrodes and the plurality of interlayer dielectric layers.

Abstract: A system, method, and layout for a semiconductor integrated circuit device allows for improved scaling down of various back-end structures, which can include contacts and other metal interconnection structures. The resulting structures can include a semiconductor substrate, a buried diffusion region formed on the semiconductor substrate, and at least one of a silicide film, for example tungsten silicide (WSix), and a self-aligned silicide (salicide) film, for example cobalt silicide (CoSi) and/or nickel silicide (NiSi), above the buried diffusion (BD) layer. The semiconductor integrated circuit can also include a memory gate structure formed over at least a portion of the contact layer.

Abstract: A plurality of vertical channels of semiconductor material are formed to extend in a vertical direction through the plurality of insulation layers and the plurality of conductive patterns, a gate insulating layer between the conductive pattern and the vertical channels that insulates the conductive pattern from the vertical channels. Conductive contact regions of the at least two of the conductive patterns are in a stepped configuration. An etch stop layer is positioned on the conductive contact regions, wherein the etch stop layer has a first portion on a first one of the plurality of conductive patterns and has a second portion on a second one of the plurality of conductive patterns, wherein the first portion is of a thickness that is greater than a thickness of the second portion.

Abstract: A method of manufacturing an integrated circuit system includes: providing a substrate having a channel region; forming a gate stack over a portion of the channel region with the gate stack having a floating gate for storing an electrical charge; forming a source recess in the substrate adjacent to the gate stack; and forming a source by layering a first bandgap material in the source recess.

Abstract: A semiconductor memory device includes: a semiconductor substrate; a plurality of device isolation regions being disposed in an upper-layer portion of the semiconductor substrate, and dividing the upper-layer portion into a plurality of semiconductor portions extending in a first direction; a plurality of charge storage films which are disposed on one of the plurality of the semiconductor portions and spaced apart from one another in the first direction; a block insulating film disposed covering the plurality of charge storage films; and a word electrode disposed on the block insulating film for each of rows of the plurality of charge storage films arranged in a second direction intersecting the first direction, wherein the block insulating film is disposed continuously in the first direction and in the second direction.

Abstract: The present invention provides a FinFET flash memory device and the method for manufacturing the same. The flash memory device is on an insulating layer, comprising: a first fin and a second fin, wherein the second fin is a control gate of the device; a gate dielectric layer, at side walls and top of the first fin and the second fin; source/drain regions, inside the first fin at both sides of a floating gate.

Abstract: Provided are three-dimensional semiconductor devices. The device includes conductive patterns stacked on a substrate, and an active pattern penetrating the conductive patterns to be connected to the substrate. The active pattern includes a first doped region disposed adjacent to at least one of the conductive patterns, and a diffusion-resistant doped region overlapped with at least a portion of the first doped region. The diffusion-resistant doped region may be a region doped with carbon.

Abstract: A semiconductor device includes a semiconductor substrate, a first insulating film formed on the semiconductor substrate, a charge storage layer formed on the first insulating film, a second insulating film formed on the charge storage layer, and a control electrode formed on the second insulating film, the second insulating film including a lower silicon nitride film, a lower silicon oxide film formed on the lower silicon nitride film, an intermediate insulating film formed on the lower silicon oxide film and containing a metal element, the intermediate insulating film having a relative dielectric constant of greater than 7, an upper silicon oxide film formed on the intermediate insulating film, and an upper silicon nitride film formed on the upper silicon oxide film.

Abstract: Disclosed are methods for manufacturing floating gate memory devices and the floating gate memory devices thus manufactured. In one embodiment, the method comprises providing a monocrystalline semiconductor substrate, forming a tunnel oxide layer on the substrate, and depositing a protective layer on the tunnel oxide layer to form a stack of the tunnel oxide layer and the protective layer. The method further includes forming at least one opening in the stack, thereby exposing at least one portion of the substrate, and cleaning the at least one exposed portion with a cleaning liquid. The method still further includes loading the substrate comprising the stack into a reactor and, thereafter, performing an in-situ etch to remove the protective layer, using the at least one exposed portion as a source to epitaxially grow a layer comprising the monocrystalline semiconductor material, and forming the layer into at least one columnar floating gate structure.

Abstract: A semiconductor memory device includes: a semiconductor substrate; a first impurity region; a second impurity region; a channel region; a first gate formed on a main surface on a side of the first impurity region; a second gate formed on the main surface on a side of the second impurity region, with a second insulating film being interposed; and a third insulating film formed on a side surface of the first gate. An interface between the third insulating film and the semiconductor substrate directly under the third insulating film is located above an interface between the second insulating film and the main surface of the semiconductor substrate directly under the second insulating film. The total number of steps can thus be reduced, and lower cost is achieved.

Abstract: Floating-gate memory cells having a floating gate with a conductive portion and a dielectric portion facilitate increased levels of charge trapping sites within the floating gate. The conductive portion includes a continuous component providing bulk conductivity to the floating gate. The dielectric portion is discontinuous within the conductive portion and may include islands of dielectric material and/or one or more contiguous layers of dielectric material having discontinuities.

Abstract: A semiconductor device includes a device isolation layer defining a plurality of active regions of a semiconductor substrate, floating gates and a control gate electrode in which the lowermost part of the electrode is constituted by a metal layer. The control gate electrode crosses over the active regions. The floating gates are disposed between the control gate electrode and the active regions. The tops of the floating gates are disposed at a level above the level of the top of the device isolation layer such that a gap is defined between adjacent ones of the floating gates. A region of the gap is filled with the metal layer of the control gate electrode.

Abstract: The present invention discloses an embedded non-volatile memory cell, an operation method and a memory array thereof. The method includes using a gate of a selection transistor as a floating gate of a memory, and using a source electrode and a drain electrode of the selection transistor as a source electrode and a drain electrode of the memory; and then changing a threshold of the device by varying the electrode voltages, thereby realizing a storage and change of information. The invention has advantages of a small area, a low operating voltage, high operating speed and high reliability.

Abstract: A method for fabricating a semiconductor device comprises: performing a thermal process to expanding a local doped region formed between gate patterns on a semiconductor substrate; and etching a central region of an expanded local doped region so that the expanded local doped region remains at the total area of sidewalls of floating bodies isolated from each other.

Abstract: A three dimensional non-volatile memory structure according to an aspect of this disclosure includes a plurality of interlayer dielectric layers and a plurality of control gates alternately stacked over a substrate, a channel formed to penetrate the plurality of interlayer dielectric layers and the plurality of control gates, a tunnel insulating layer formed to surround the channel, a plurality of floating gates disposed between the plurality of interlayer dielectric layers and the tunnel insulating layer, wherein the plurality of floating gates each have a thickness greater than a corresponding one of the interlayer dielectric layers, and a charge blocking layer disposed between the plurality of control gates and the plurality of floating gates.

Abstract: The invention relates to a nonvolatile two-transistor semiconductor memory cell and an associated fabrication method, source and drain regions (2 ) for a selection transistor (AT) and a memory transistor (ST) being formed in a substrate (1). The memory transistor (ST) has a first insulation layer (3 ), a charge storage layer (4), a second insulation layer (5) and a memory transistor control layer (6), while the selection transistor (AT) has a first insulation layer (3 ?) and a selection transistor control layer (4*). By using different materials for the charge storage layer (4) and the selection transistor control layer (4*), it is possible to significantly improve the charge retention properties of the memory cell by adapting the substrate doping with electrical properties remaining the same.

Abstract: A device, comprising: a first layer and a second layer wherein both said first layer and said second layer are mono-crystalline, wherein said first layer comprises first transistors, wherein said second layer comprises second transistors, wherein at least one of said second transistors substantially overlays one of said first transistors, and wherein both said first transistors and said second transistors are processed following the same lithography step.

Abstract: A nonvolatile memory includes a semiconductor substrate having a body member and a step member formed on the body member, a highly doped first well layer formed on the step member, a control electrode formed on the step member, a first and a second diffusion layers in the substrate, lightly doped second well layers formed on the main surface of the substrate between the first or the second diffusion layer and the first well layer, and a first and a second charge-storage multi-layers sandwiching the step member and the control electrode, each of the first and the second charge-storage multi-layers including a bottom oxide layer, a charge-storage film, a top oxide layer and a floating electrode which are formed in that order.

Abstract: A nonvolatile semiconductor memory includes a memory cell string having a plurality of memory cell transistors connected in series, a selection gate transistor connected in series with one end of the memory cell string, and having a gate electrode provided on a gate insulating film on a semiconductor substrate, and an element isolation insulating layer which is provided in the semiconductor substrate. The gate electrode includes a first gate electrode provided on the gate insulating film, a first and second insulating films provided on the first gate electrode, and a second gate electrode provided on the second insulating film and the element isolation insulating layer, and electrically connected to the first gate electrode. An first upper surface portion of the element isolation insulating layer below the second gate electrode is leveled with an upper surface of the first gate electrode.

Abstract: A nonvolatile semiconductor memory includes memory cell transistors and resistors. Each memory cell transistor has source/drain diffusion layers provided in a semiconductor substrate, a first gate insulating film located between the source/drain diffusion layers, a floating gate electrode layer located on the first gate insulating film, a first inter-gate insulating film located on the floating gate electrode layer, a control gate electrode layer located on the first inter-gate insulating layer, and a first low-resistance layer located on the control gate electrode layer. Each resistor has a second gate insulating film located on the semiconductor substrate, a first electrode layer located on the second gate insulating film, a second inter-gate insulating film located on the first electrode layer, a second electrode layer located on the second inter-gate insulating film, a second low-resistance layer located on the second electrode layer, and a contact plug connected to the second low-resistance layer.

Abstract: In some embodiments, a gate structure with a spacer on its side may be used as a mask to form self-aligned trenches in a microelectronic memory, such as a flash memory. A first portion of the gate structure may be used to form the mask, together with sidewall spacers, in some embodiments. Then, after forming the shallow trench isolations, a second portion of the gate structure may be added to form a mushroom shaped gate structure.

Abstract: According to one embodiment, a semiconductor device is provided. The semiconductor is provided with a MEMS switch element having a control terminal and a pair of signal terminals, and a non-volatile memory unit having first and second non-volatile semiconductor elements. The first non-volatile semiconductor element has a first source, a first drain and a first control gate terminal. The first drain is electrically connected to the control terminal of the MEMS switch element. The second non-volatile semiconductor element has a second source, a second drain and a second control gate terminal. The second drain gate terminal is electrically connected to the control terminal of the MEMS switch element.

Abstract: Provided are a three-dimensional semiconductor device and a method of operating the same. The three-dimensional semiconductor device includes: a plurality of word line structures on a substrate; active semiconductor patterns between the plurality of word line structures; and information storage elements between the plurality of word line structures and the active semiconductor patterns. Each of the plurality of word line structures includes a plurality of word lines spaced apart from each other and stacked, and the active semiconductor patterns include electrode regions and channel regions, the electrode regions and the channel regions having different conductive types and being alternately arranged.

Abstract: A memory device, and method of making the same, in which a trench is formed into a substrate of semiconductor material. The source region is formed under the trench, and the channel region between the source and drain regions includes a first portion that extends substantially along a sidewall of the trench and a second portion that extends substantially along the surface of the substrate. The floating gate is disposed in the trench, and is insulated from the channel region first portion for controlling its conductivity. The control gate is disposed over and insulated from the channel region second portion, for controlling its conductivity. The erase gate is disposed at least partially over and insulated from the floating gate. The erase gate includes a notch, and the floating gate includes an edge that directly faces and is insulated from the notch.

Abstract: A method of manufacturing a semiconductor device including forming a plurality of gate structures spaced apart from each other on a substrate; forming a first insulation layer covering the gate structures, the first insulation layer including a void between the gate structures; removing an upper portion of the first insulation layer to form a first insulation layer pattern on sidewalls of lower portions of the gate structures and on the substrate between the gate structures, the first insulation layer pattern including a first recess thereon; forming a conductive layer on upper portions of the gate structures exposed by the first insulation layer pattern; reacting the conductive layer with the gate structures; and forming a second insulation layer on the upper portions of the gate structures, the second insulation layer including a second recess therebeneath in fluid communication with the first recess.

Abstract: A method of forming a device is disclosed. The method includes providing a substrate prepared with a cell area separated by other active areas by isolation regions. First and second gates of first and second transistors in the cell area are formed. The first gate includes first and second sub-gates separated by a first intergate dielectric layer. The second gate includes a second sub-gate surrounding a first sub-gate. The first and second sub-gates of the second gate are separated by a second intergate dielectric layer. First and second junctions of the first and second transistors are formed. The method also includes forming a first gate terminal coupled to the second sub-gate of the first transistor and a second gate terminal coupled to at least the first sub-gate of the second transistor.

Abstract: A method of forming a device is disclosed. The method includes providing a substrate prepared with a cell area and forming first and second gates of first and second transistors in the cell area. The first gate includes a second sub-gate surrounding a first sub-gate. The first and second sub-gates of the first gate are separated by a first intergate dielectric layer. The second gate includes a second sub-gate surrounding a first sub-gate. The first and second sub-gates of the second gate are separated by a second intergate dielectric layer. The method also includes forming first and second junctions of the first and second transistors. A first gate terminal is formed and coupled to the second sub-gate of the first transistor. A second gate terminal is formed and coupled to at least the first sub-gate of the second transistor.

Abstract: A nonvolatile memory device comprises a gate insulating layer, a floating gate and a dielectric layer sequentially formed over a semiconductor substrate, a capping layer formed over the dielectric layer, and a control gate formed over the capping layer, wherein the control gate includes nitrogen or carbon as an additive.

Abstract: A non-volatile memory device having a split gate type cell structure, a method for fabricating the same, and a method for fabricating a semiconductor device by using the same are provided. A non-volatile memory device includes a substrate, a plurality of patterned tunnel insulation layers formed on the substrate, a plurality of floating gates formed on the patterned tunnel insulation layers, a plurality of patterned dielectric layers to cover upper portions and sidewalls of the floating gates, a plurality of selection gates formed on sidewalls of the patterned dielectric layers, and a plurality of source/drain regions formed in the substrate exposed at one sides of the selection gates and one sides of the floating gates.

Abstract: According to an embodiment, a semiconductor memory device includes a plurality of multi-level memory cells provided on a major surface of a semiconductor substrate of a first conductivity type. A first semiconductor region of a second conductivity type is selectively provided in the surface of the semiconductor substrate between the multi-level memory cells. A second semiconductor region is provided deeper than the first semiconductor region and includes a first conductivity type impurity. A plurality of binary memory cells are provided on the major surface of the semiconductor substrate, and a third semiconductor region of the second conductivity type is selectively provided in the surface of the semiconductor substrate between the binary memory cells. Amount of the first conductivity type impurity compensating a second conductivity type impurity of the first semiconductor region is larger than that of the third semiconductor region.

Abstract: An EEPROM memory cell that includes a dual-gate MOS transistor in which the two gates are separated by an insulation layer, wherein the insulation layer includes a first portion and a second portion having lower insulation properties than the first one, the second portion being located at least partially above a channel area of the transistor.

Abstract: An improvement is achieved in the performance of semiconductor device including a nonvolatile memory. In a split-gate nonvolatile memory, between a memory gate electrode and a p-type well and between a control gate electrode and the memory gate electrode, an insulating film is formed. Of the insulating film, the portion between the lower surface of the memory gate electrode and the upper surface of a semiconductor substrate has silicon oxide films, and a silicon nitride film interposed between the silicon oxide films. Of the insulating film, the portion between a side surface of the control gate electrode and a side surface of the memory gate electrode is formed of a silicon oxide film, and does not have the silicon nitride film.

Abstract: According to one embodiment, a semiconductor device includes a semiconductor region, a tunnel insulating film provided on the semiconductor region, a charge storage insulating film provided on the tunnel insulating film and having a hafnium oxide including a cubic region, a block insulating film provided on the charge storage insulating film, and a control gate electrode provided on the block insulating film.

Abstract: According to one embodiment, a semiconductor device, includes an element unit including a vertical-type MOSFET, the vertical-type MOSFET in including a first semiconductor layer, a second semiconductor layer, a third semiconductor layer, a fourth semiconductor layer, a fifth semiconductor layer sequentially stacked in order, an impurity concentration of the second semiconductor layer being lower than the first semiconductor layer, an insulator covering inner surfaces of a plurality of trenches, the adjacent trenches being provided with a first interval in between, and a diode unit including basically with the units of the element unit, the adjacent trenches being provided with a second interval in between, the second interval being larger than the first interval.

Abstract: A semiconductor device includes horizontal patterns on a substrate and the horizontal patterns have at least one opening therein, a pad pattern in an upper region of the opening, an insulating gap fill structure in the opening, the insulating gap fill structure is between the pad pattern and the substrate, and the insulating gap fill structure includes a first gap fill pattern and a second gap fill pattern. The first gap fill pattern includes a first oxide and the second gap fill pattern includes a second oxide, and the second oxide has a different etching selectivity from that of the first oxide. The device further includes a semiconductor pattern that is between a sidewall of the gap fill structure and sidewalls of the horizontal patterns and between a sidewall of the pad pattern and the sidewalls of the horizontal patterns.

Abstract: The nonvolatile memory device includes a semiconductor substrate, and a device isolation layer defining an active region in the semiconductor substrate. The device isolation layer includes a top surface lower than a top surface of the semiconductor substrate, such that a side-upper surface of the active region is exposed. A sense line crosses both the active region and the device isolation layer, and a word line, spaced apart from the sense line, crosses both the active region and the device isolation layer.

Abstract: A non-volatile memory device may include a semiconductor substrate and an isolation layer on the semiconductor substrate wherein the isolation layer defines an active region of the semiconductor substrate. A tunnel insulation layer may be provided on the active region of the semiconductor substrate, and a charge storage pattern may be provided on the tunnel insulation layer. An interface layer pattern may be provided on the charge storage pattern, and a blocking insulation pattern may be provided on the interface layer pattern. Moreover, the block insulation pattern may include a high-k dielectric material, and the interface layer pattern and the blocking insulation pattern may include different materials. A control gate electrode may be provided on the blocking insulating layer so that the blocking insulation pattern is between the interface layer pattern and the control gate electrode. Related methods are also discussed.