Abstract: A non-volatile memory device having a vertical structure includes a semiconductor layer, a sidewall insulation layer extending in a vertical direction on the semiconductor layer, and having one or more protrusion regions, first control gate electrodes arranged in the vertical direction on the semiconductor layer, and respectively contacting one of portions of the sidewall insulation layer where the one or more protrusion regions are not formed and second control gate electrodes arranged in the vertical direction on the semiconductor layer, and respectively contacting one of the one or more protrusion regions.

Abstract: In one embodiment there is set forth a method comprising providing a semiconductor structure having an electrode, wherein the providing includes providing a phase transition material region and wherein the method further includes imparting energy to the phase transition material region to induce a phase transition of the phase transition material region. By inducing a phase transition of the phase transition material region, a state of the semiconductor structure can be changed. There is further set forth an apparatus comprising a structure including an electrode and a phase transition material region, wherein the apparatus is operative for imparting energy to the phase transition material region to induce a phase transition of the phase transition material region without the phase transition of the phase transition material region being dependent on electron transport through the phase transition material region.

Abstract: A three dimensional (3-D) non-volatile memory device includes a pipe gate including a first pipe gate, a second pipe gate formed on the first pipe gate, and a first interlayer insulating layer interposed between the first pipe gate and the second pipe gate, word lines alternately stacked with second interlayer insulating layers on the pipe gate, a pipe channel buried within the pipe gate, and memory cell channels coupled to the pipe channel and arranged to pass through the word lines and the second interlayer insulating layers.

Abstract: A mask-defined read-only memory array is formed on a substrate, and includes a first ROM bit and a second ROM bit of opposite polarities. The first ROM bit has a first MOS transistor and a first block layer formed over a first region of the substrate. A second source/drain region of the first MOS transistor and a first diffusion region are formed in a first region of the substrate on opposite sides of the first block layer. The second ROM bit includes a second MOS transistor.

Abstract: The present invention provides a floating-gate non-volatile semiconductor memory device and a method of making the same. The floating-gate non-volatile semiconductor memory device comprises a semiconductor substrate, a source, a drain, a first insulator layer, a first polysilicon layer, a second insulator layer, a second polysilicon layer, a protective layer and sidewalls. The source and drain are disposed on the semiconductor substrate. The first insulator layer is disposed over a region of the semiconductor substrate other than regions corresponding to the source and drain. The first polysilicon layer is disposed over the first insulator layer, forming a floating gate. The second insulator layer is disposed over the first polysilicon layer. The second polysilicon layer is disposed over the second insulator layer, forming a control gate and a wordline. The sidewalls are disposed on two sides of the wordline, and the protective layer is disposed over the second polysilicon layer.

Abstract: A semiconductor device includes: a memory cell transistor which has a floating gate, a control gate, and a source and a drain formed in a semiconductor substrate on both sides of the floating gate via a channel area; and a selecting transistor which has a select gate and a source and a drain formed in the semiconductor substrate on both sides of the select gate, wherein the source of the selecting transistor is connected to the drain of the memory cell transistor, the source of the memory cell transistor has an N-type first impurity diffusion layer, an N-type second impurity diffusion layer deeper than the first impurity diffusion layer, and an N-type third impurity diffusion layer which is shallower than the second impurity diffusion layer, and an impurity density of the second impurity diffusion layer is lower than that of the third impurity diffusion layer.

Abstract: A method of fabricating a non-volatile memory device is provided. A substrate including a first region and a second region is provided. Then, an uneven surface is formed on the substrate in the second region. Thereafter, a doped layer is formed in the substrate in the second region, and the doped layer is served as a control gate. Afterward, a dielectric layer is formed on the substrate in the first region and on the uneven surface of the substrate in the second region. Next, a floating gate is formed on the dielectric layer, and the floating gate is extended from the first region to the second region. Source and drain regions are formed in the substrate at opposite sides of the floating gate in the first region.

Abstract: Monolithic three dimensional NAND strings and methods of making. The method includes both front side and back side processing. Using the combination of front side and back side processing, a NAND string can be formed that includes an air gap between the floating gates in the NAND string. The NAND string may be formed with a single vertical channel. Alternatively, the NAND string may have a U shape with two vertical channels connected with a horizontal channel.

Abstract: A method of manufacturing a memory cell 200. The method comprises forming a memory stack 215. Forming the memory stack includes pre-treating an insulating layer 210 in a substantially ammonia atmosphere for a period of more than 5 minutes to thereby form a pre-treated insulating layer 310. Forming the memory stack also includes depositing a silicon nitride layer on the pre-treated insulating layer.

Abstract: A first dielectric layer is formed on a substrate in a transistor region and an NVM region, a first conductive layer is formed on the first dielectric layer, a second dielectric layer is formed on the first conductive layer, and a second conductive layer is formed over the second dielectric layer. A patterned etch is performed to remove at least a portion of the second conductive layer in the transistor region and to expose an extension portion of the first conductive layer. A first mask is formed over the transistor region having a first pattern, wherein the first pattern is of a gate stack of the MOSFET and an extension in the extension portion extending from the gate stack, and a second mask over the NVM region having a second pattern, wherein the second pattern is of a gate stack of the NVM cell. A patterned etch is then performed.

Abstract: A semiconductor device includes a tunnel insulating film formed on a semiconductor substrate, a charge storage insulating film formed on the tunnel insulating film and including at least two separated low oxygen concentration portions and a high oxygen concentration portion positioned between the adjacent low oxygen concentration portions and having a higher oxygen concentration than the low oxygen concentration portions, a charge block insulating film formed on the charge storage insulating film, and control gate electrodes formed on the charge block insulating film and above the low oxygen concentration portions.

Abstract: Non-volatile storage elements having a P?/metal floating gate are disclosed herein. The floating gate may have a P? region near the tunnel oxide, and may have a metal region near the control gate. A P? region near the tunnel oxide helps provide good data retention. A metal region near the control gate helps to achieve a good coupling ratio between the control gate and floating gate. Therefore, programming of non-volatile storage elements is efficient. Also, erasing the non-volatile storage elements may be efficient. In some embodiments, having a P? region near the tunnel oxide (as opposed to a strongly doped p-type semiconductor) may improve erase efficiency relative to P+.

Abstract: According to one embodiment, the storage device further includes: a first electrode that is formed in a reverse convex and in contact with an upper surface of a first region, parts of a side and an upper surface of a first isolation region that face a second isolation region, and parts of a side and an upper surface of the second isolation region that face the first isolation region; and a third electrode that is positioned in a different direction from a second direction with respect to the first electrode, formed in a reverse convex and in contact with an upper surface of a second region, parts of a side and the upper surface of the second isolation region that face a third isolation region, and parts of a side and an upper surface of the third isolation region that face the second isolation region.

Abstract: A method of making a nanoparticle array that includes replicating a dimension of a self-assembled film into a dielectric film, to form a porous dielectric film, conformally depositing a material over said porous dielectric film, and anisotropically and selectively etching said deposited material.

Abstract: A nonvolatile semiconductor memory device, includes: a stacked body including a plurality of insulating films alternately stacked with a plurality of electrode films, the electrode films being divided to form a plurality of control gate electrodes aligned in a first direction; a plurality of semiconductor pillars aligned in a stacking direction of the stacked body, the semiconductor pillars being arranged in a matrix configuration along the first direction and a second direction intersecting the first direction to pierce the control gate electrodes; and a connection member connecting a lower end portion of one of the semiconductor pillars to a lower end portion of one other of the semiconductor pillars, an upper end portion of the one of the semiconductor pillars being connected to a source line, an upper end portion of the one other of the semiconductor pillars being connected to a bit line.

Abstract: A semiconductor structure is provided. The semiconductor structure includes a first floating gate on the semiconductor substrate, the floating gate having a concave side surface; a first control gate on the first floating gate; a first spacer adjacent to the first control gate; a first word line adjacent a first side of the first floating gate with a first distance; and an erase gate adjacent a second side of the first floating gate with a second distance less than the first distance, the second side being opposite the first side.

Abstract: A NAND flash memory device and method of manufacturing the same is disclosed. Source and drain select transistor gates are recessed lower than an active region of a semiconductor substrate. A valid channel length of the source and drain select transistor gates is longer than a channel length of memory cell gates. Accordingly, an electric field between a source region and a drain region of the select transistor can be reduced. It is thus possible to prevent program disturbance from occurring in edge memory cells adjacent to the source and drain select transistors in non-selected cell strings.

Abstract: Methods for forming split gate flash cell structures provide for symmetrical cells that are immune to misalignment of the photoresist pattern when forming the control gates. Spacers are utilized to form the floating gates in the floating gate transistors used in the flash cells. The spacers may be oxide spacers used to mask a polysilicon layer that will form the floating gates or the spacers may be polysilicon spacers that will themselves form the floating gates. The inter-gate oxide of the floating gate transistors may be formed using HTO or may be deposited. Hard mask spacers are used in conjunction with the control gate photoresist patterning operation to control the size and configuration of the control gate and the channel length.

Abstract: Non-volatile storage elements having a PN floating gate are disclosed herein. The floating gate may have a P? region near the tunnel oxide, and may have an N+ region near the control gate. In some embodiments, a P? region near the tunnel oxide helps provide good data retention. In some embodiments, an N+ region near the control gate helps to achieve a good coupling ratio between the control gate and floating gate. Therefore, programming of non-volatile storage elements is efficient. Also erasing the non-volatile storage elements may be efficient. In some embodiments, having a P? region near the tunnel oxide (as opposed to a strongly doped p-type semiconductor) may improve erase efficiency relative to P+.

Abstract: The present invention provides a semiconductor device that has a shorter distance between the bit lines and easily achieves higher storage capacity and density, and a method of manufacturing such a semiconductor device. The semiconductor device includes: first bit lines formed on a substrate; an insulating layer that is provided between the first bit lines on the substrate, and has a higher upper face than the first bit lines; channel layers that are provided on both side faces of the insulating layer, and are coupled to the respective first bit lines; and charge storage layers that are provided on the opposite side faces of the channel layers from the side faces on which the insulating layers are formed.

Abstract: A method for forming a split gate flash cell memory device provides for establishing a floating gate region then using spacers or other hard mask materials that cover opposed edges of a gate electrode material in the gate region, to serve as hard masks during an etching operation that partially etches the gate electrode material which may be polysilicon. The gate electrode so produced serves as a floating gate electrode and includes a recessed central portion flanked by a pair of opposed upwardly extending fins which may terminate upwardly at an apex. A floating gate oxide is then formed by thermal oxidation and/or oxide deposition techniques.

Abstract: A nonvolatile memory device includes bit and source lines alternately arranged parallel to each other and even strings and odd strings alternately arranged between the bit lines and the source lines and each including drain selection transistors, memory transistors, and a source selection transistor. The drain selection transistors include a first drain selection transistor with the same structure as the memory transistors and a second drain selection transistor with the same structure as the source selection transistor. The nonvolatile memory device further includes an even drain selection line connected to the first drain selection transistors of the even strings and the second drain selection transistors of the odd strings and an odd drain selection line connected to the second drain selection transistors of the even strings and the first drain selection transistors of the odd strings.

Abstract: There is provided a monolithic three dimensional array of charge storage devices which includes a plurality of device levels, wherein at least one surface between two successive device levels is planarized by chemical mechanical polishing.

Abstract: Disclosed are methods for manufacturing a floating gate memory device and the floating gate memory device thus obtained. In one embodiment, a method is disclosed that includes providing a semiconductor-on-insulator substrate, forming at least two trenches in the semiconductor-on-insulator substrate, and, as a result of forming the at least two trenches, forming at least one elevated structure. The method further includes forming isolation regions at a bottom of the at least two trenches by partially filling the at least two trenches, thermally oxidizing sidewall surfaces of at least a top portion of the at least one elevated structure, thereby providing a gate dielectric layer on at least the exposed sidewall surfaces; and forming a conductive layer over the at least one elevated structure, the gate dielectric layer, and the isolation regions to form at least one floating gate semiconductor memory device.

Abstract: There is provided a nonvolatile semiconductor memory device, including, a tunnel insulator, a floating gate electrode including a first floating gate electrode and a second floating gate electrode being constituted with a nondegenerate state semiconductor, an intergate insulating film formed to cover at least continuously an upper and a portion of a side surface of the floating gate electrode, and a control gate electrode in order, and an isolation insulating film, a lower portion of the isolation insulating film being embedded in the semiconductor substrate in both sides of the floating gate electrode along a channel width direction, an upper portion of the isolation insulating film contacting with a side surface of the first floating gate electrode and protruding to a level between an upper surface of the semiconductor substrate and an upper surface of the first floating gate electrode.

Abstract: Monolithic, three dimensional NAND strings include a semiconductor channel, at least one end portion of the semiconductor channel extending substantially perpendicular to a major surface of a substrate, a plurality of control gate electrodes having a strip shape extending substantially parallel to the major surface of the substrate, the blocking dielectric comprising a plurality of blocking dielectric segments, a plurality of discrete charge storage segments, and a tunnel dielectric located between each one of the plurality of the discrete charge storage segments and the semiconductor channel.

Abstract: A nonvolatile semiconductor memory device includes: a semiconductor member; a memory film provided on a surface of the semiconductor member and being capable of storing charge; and a plurality of control gate electrodes provided on the memory film, spaced from each other, and arranged along a direction parallel to the surface. Average dielectric constant of a material interposed between one of the control gate electrodes and a portion of the semiconductor member located immediately below the control gate electrode adjacent to the one control gate electrode is lower than average dielectric constant of a material interposed between the one control gate electrode and a portion of the semiconductor member located immediately below the one control gate electrode.

Abstract: A method of making a uniform nanoparticle array, including performing diblock copolymer thin film self assembly over a first dielectric on silicon, creating a porous polymer film, transferring a pattern into the first dielectric, selectively growing epitaxial silicon off a silicon substrate from within pores to create a silicon nanoparticle array.

Abstract: An asymmetric non-volatile memory bitcell is described. The bitcell comprises source and drain regions comprising carriers of the same conductivity type. A floating gate rests on top of the well, and extends over a channel region, and at least a portion of the source and drain regions. The drain region comprises additional carriers of a second conductivity type, allowing band to band tunneling. The source region comprises additional carriers of a first conductivity type, thereby increasing source-gate capacitance. Thus, the bitcell incorporates a select device, thereby decreasing the overall size of the bitcell. The bitcell may be created without any additional CMOS process steps, or through the addition of a single extra mask step.

Abstract: A nonvolatile memory device with a blocking layer controlling the transfer of electric charges in a charge storage layer includes the blocking layer having a first blocking layer in contact with the charge storage layer and a second blocking layer over the first blocking layer, wherein the first blocking layer has a greater energy band gap than the second blocking layer and the second blocking layer has a greater permittivity than the first blocking layer.

Abstract: A system and method is disclosed for providing a low voltage high density multi-bit storage flash memory. A dual bit memory cell of the invention comprises a substrate having a common source, a first drain and first channel, and a second drain and a second channel. A common control gate is located above the source. A first floating gate and a second floating gate are located on opposite sides of the control gate. Each floating gate is formed with a sharp tip adjacent to the control gate and an upper curved surface that follows a contour of the surface of the control gate. The sharp tips of the floating gates efficiently discharge electrons into the control gate when the memory cell is erased. The curved surfaces increase capacitor coupling between the control gate and the floating gates.

Abstract: Provided is a method for fabricating a nonvolatile memory device capable of improving charge retention characteristics. The method for fabricating a nonvolatile memory device includes forming a charge trapping layer with a memory region and a charge blocking region on a semiconductor substrate, and trapping charges in the charge blocking region of the charge trapping layer.

Abstract: A method for manufacturing an integrated circuit structure includes providing a semiconductor substrate and forming two trenches in the semiconductor substrate to define an active region therebetween. An implanted source region is formed in one of the trenches on one side of the active region. An implanted drain region is formed in the other trench on the other side of the active region. Shallow trench isolations are then formed in the trenches. One or more gates are formed over the active region, and contacts to the implanted source region and the implanted drain region are formed.

Abstract: According to one embodiment, a method is disclosed for manufacturing a nonvolatile memory device. The method can include forming a second stacked body, removing the second stacked body formed in a region where a first memory unit will be formed, forming a first stacked body, and removing the first stacked body formed in a region where a second memory unit will be formed. The method can include simultaneously processing the first stacked body formed in a region where the first memory unit will be formed and the second stacked body formed in a region where the second memory unit will be formed to form a memory cell of the first memory unit from the first stacked body and form a memory cell of the second memory unit from the second stacked body.

Abstract: According to one embodiment, there is provided a method of manufacturing a semiconductor storage device. In the method, any one of Ge, Sn, C, and N is introduced as impurity to a surface of a semiconductor substrate. In the method, the semiconductor substrate is thermally oxidized so that a tunnel insulating film is formed on the surface of the semiconductor substrate to which the impurity is introduced. In the method, a gate having a charge accumulation layer is formed on the tunnel insulating film. In the method, impurity diffusion regions are formed in the semiconductor substrate in a self-aligned manner using the gate.

Abstract: Methods for fabricating control gates in non-volatile storage are disclosed. When forming stacks for floating gate memory cells and transistor control gates, a sacrificial material may be formed at the top of the stacks. After insulation is formed between the stacks, the sacrificial material may be removed to reveal openings. In some embodiments, cutouts are then formed in regions in which control gates of transistors are to be formed. Metal is then formed in the openings, which may include the cutout regions. Therefore, floating gate memory cells having at least partially metal control gates and transistors having at least partially metal control gates may be formed in the same process. A barrier layer may be formed prior to depositing the metal in order to prevent silicidation of polysilicon in the control gates.

Abstract: Strings of memory cells having a string select gate configured to selectively couple ends of a string to a data line and a source line concurrently, memory devices incorporating such strings and methods for accessing and forming such strings are provided. For example, non-volatile memory devices are disclosed that utilize vertical structure NAND strings of serially-connected non-volatile memory cells. One such string including two or more serially-connected non-volatile memory cells where each end of the string shares a string select gate with the other end of the string is disclosed.

Abstract: According to one embodiment, a multi-dot flash memory includes an active area, a floating gate arranged on the active area via a gate insulating film and having a first side and a second side facing each other in a first direction, a word line arranged on the floating gate via an inter-electrode insulating film, a first bit line arranged on the first side of the floating gate via a first tunnel insulating film and extending in a second direction intersecting the first direction, and a second bit line arranged on the second side of the floating gate via a second tunnel insulating film and extending in the second direction. The active area has a width in the first direction narrower than that between a center of the first bit line and a center of the second bit line.

Abstract: A nonvolatile semiconductor storage device including a number of memory cells formed on a semiconductor substrate, each of the memory cells has a tunnel insulating film, a charge storage layer, a block insulating film, and a gate electrode which are formed in sequence on the substrate. The gate electrode is structured such that at least first and second gate electrode layers are stacked. The dimension in the direction of gate length of the second gate electrode layer, which is formed on the first gate electrode layer, is smaller than the dimension in the direction of gate length of the first gate electrode layer.

Abstract: Multilayer floating gate field-effect transistor (FET) devices and related methods are provided. A multilayer floating gate FET device can include a first floating gate separated via a first dielectric layer from a channel of the device and a second floating gate separated via a second dielectric layer from the first floating gate. The second dielectric layer between the first floating gate and the second floating gate permits a redistribution of charge between the first and second floating gates from one of the floating gates to the other when under the influence of a first electrical field from a first voltage. In some embodiments, a redistribution of charge between the first and second floating gates with electrons being supplied through a channel to the first and second floating gates can occur when under the influence of a second electrical field from a second voltage that is greater than the first voltage.

Abstract: A semiconductor device includes a bit line formed over a substrate, an insulation layer formed over the bit line, a gate line crossing the bit line and formed over the insulation layer, and a channel layer formed on both sidewalls of the gate line and coupled to the bit line.

Abstract: Briefly, embodiments of non-volatile memory and embodiments of fabrication thereof are disclosed. For example, a non-volatile memory device having a gate assembly with a floating gate and a control gate assembly is described. The control gate assembly includes a non-metal conductive control gate and a metal control gate in one embodiment. Additional embodiments are described, including use of a sacrificial nitride layer and forming contact recesses to create source or drain contacts, as other examples.

Abstract: Methods of forming non-volatile memory cell structures are described that facilitate the use of band-gap engineered gate stacks with asymmetric tunnel barriers in reverse and normal mode floating node memory cells that allow for direct tunnel programming and erase, while maintaining high charge blocking barriers and deep carrier trapping sites for good charge retention. The low voltage direct tunneling program and erase capability reduces damage to the gate stack and the crystal lattice from high energy carriers, reducing write fatigue and enhancing device lifespan. The low voltage direct tunnel program and erase capability also enables size reduction through low voltage design and further device feature scaling. Such memory cells also allow multiple bit storage. These characteristics allow such memory cells to operate within the definition of a universal memory, capable of replacing both DRAM and ROM in a system.

Abstract: A method of fabricating a semiconductor device according to present invention includes forming a stack layers on a semiconductor substrate having a first area and a second area; forming first gates on the semiconductor substrate of the first area by patterning the stack layers, wherein the first gates are formed a first distance apart from each other; forming a first impurity injection area in the semiconductor substrate of the first area exposed at both sides of each of the first gates; filling a space between the first gates with an insulating layer; forming second gates on the semiconductor substrate of the second area by patterning the stack layers, wherein the second gates are formed a second distance apart from each other, and wherein the second distance is larger than the first distance; and forming a second impurity injection area in the semiconductor device of the second area exposed between the second gates.

Abstract: A semiconductor device including a semiconductor substrate; a memory cell region formed in the semiconductor substrate and including a plurality of memory cells; a peripheral circuit region formed in the semiconductor substrate; a first element isolation trench with a first width formed in the memory cell region; a second element isolation trench with a second width greater than the first width formed in the peripheral circuit region; a first oxide film formed along an inner surface of the first element isolation trench; a first coating oxide film formed along the first oxide film and filling the first element isolation trench; a second oxide film formed along a sidewall of the second element isolation trench; a third oxide film formed above a bottom of the second element isolation trench; and a second coating oxide film formed above the third oxide film and filling the second element isolation trench.

Abstract: A NAND device including a source, a drain and a channel located between the source and drain. The NAND device also includes a plurality of floating gates located over the channel and a plurality of electrically conducting fins. Each of the plurality of electrically conducting fins is located over one of the plurality of floating gates. The plurality of electrically conducting fins include a material other than polysilicon. The NAND device also includes a plurality of control gates. Each of the plurality of control gates is located adjacent to each of the plurality of floating gates and each of the plurality of electrically conducting fins.

Abstract: A semiconductor device having a line-type active region and a method for manufacturing the same are disclosed. The semiconductor device includes an active region configured in a successive line type, at least one active gate having a first width and crossing the active region, and an isolation gate having a second width different from the first width and being formed between the active gates. The isolation gate's width and the active gate's width are different from each other to guarantee a large storage node contact region, resulting in increased device operation characteristics (write characteristics).

Abstract: In one embodiment, a nonvolatile semiconductor memory includes a memory cell array, a first silicon nitride film and a second silicon nitride film. The memory cell array includes NAND cell units. Each of the NAND cell units has memory cell transistors, a source-side select gate transistor and a drain-side select gate transistor. The source-side select gate transistors is disposed in such a manner as to face each other and the drain-side select gate transistors is disposed in such a manner as to face each other. The first silicon nitride film is present in a region between the source-side select gate transistors and is disposed at a position lowest from the upper surface of the semiconductor substrate. The second silicon nitride film is formed in a region between the drain-side select gate transistors and is disposed at a position lowest from the upper surface of the semiconductor substrate.

Abstract: Some embodiments include memory cells that contain floating bodies and diodes. The diodes may be gated diodes having sections doped to a same conductivity type as the floating bodies, and such sections of the gated diodes may be electrically connected to the floating bodies. The floating bodies may be adjacent channel regions, and spaced from the channel regions by a dielectric structure. The dielectric structure of a memory cell may have a first portion between the floating body and the diode, and may have a second portion between the floating body and the channel region. The first portion may be more leaky to charge carriers than the second portion. The diodes may be formed in semiconductor material that is different from a semiconductor material that the channel regions are in. The floating bodies may have bulbous lower regions. Some embodiments include methods of making memory cells.

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.