Abstract: A method of making a monolithic three dimensional NAND string including forming a stack of alternating layers of a first material and a second material over a substrate. The first material comprises an electrically insulating material and the second material comprises a semiconductor or conductor material. The method also includes etching the stack to form a front side opening in the stack, forming a blocking dielectric layer over the stack of alternating layers of a first material and a second material exposed in the front side opening, forming a semiconductor or metal charge storage layer over the blocking dielectric, forming a tunnel dielectric layer over the charge storage layer, forming a semiconductor channel layer over the tunnel dielectric layer, etching the stack to form a back side opening in the stack, removing at least a portion of the first material layers and portions of the blocking dielectric layer.

Abstract: A system and method for manufacturing a memory device is provided. A preferred embodiment comprises manufacturing a flash memory device with a tunneling layer. The tunneling layer is formed by introducing a bonding agent into the dielectric material to bond with and reduce the number of dangling bonds that would otherwise be present. Further embodiments include initiating the formation of the tunneling layer without the bonding agent and then introducing a bonding agent containing precursor and also include a reduced concentration region formed in the tunneling layer adjacent to a substrate.

Abstract: A method of making a monolithic three dimensional NAND string, including providing a stack of alternating first material layers and second material layers different from the first material layer over a substrate, the stack comprising at least one opening containing a charge storage material comprising a silicide layer, a tunnel dielectric on the charge storage material in the at least one opening, and a semiconductor channel on the tunnel dielectric in the at least one opening, selectively removing the second material layers without removing the first material layers from the stack and forming control gates between the first material layers.

Abstract: According to one embodiment, a memory cell string stacked body includes first memory cell transistors above a semiconductor substrate, and second memory cell transistors below a first channel semiconductor film, and one of the first memory cell transistors and one of the second memory cell transistors share with a control gate electrode. The control gate electrodes of the first memory cell transistors cover an upper surface of a first charge storage layer and at least a part of a side surface in a second direction via a first insulating film in the one of the first memory cell transistors. The control gate electrodes of the second memory cell transistors cover only a lower surface of a second charge storage layer via a second insulating film in one of the second memory cell transistors.

Abstract: A non-volatile memory and a manufacturing method thereof are provided. The non-volatile memory includes a substrate, a gate structure, a first doped region, a second doped region and a pair of isolation structures. The gate structure is disposed on the substrate. The gate structure includes a charge storage structure, a gate and spacers. The charge storage structure is disposed on the substrate. The gate is disposed on the charge storage structure. The spacers are disposed on the sidewalls of the gate and the charge storage structure. The first doped region and the second doped region are respectively disposed in the substrate at two sides of the charge storage structure and at least located under the spacers. The isolation structures are respectively disposed in the substrate at two sides of the gate structure.

Abstract: Nanostructure-based charge storage regions are included in non-volatile memory devices and integrated with the fabrication of select gates and peripheral circuitry. One or more nanostructure coatings are applied over a substrate at a memory array area and a peripheral circuitry area. Various processes for removing the nanostructure coating from undesired areas of the substrate, such as target areas for select gates and peripheral transistors, are provided. One or more nanostructure coatings are formed using self-assembly based processes to selectively form nanostructures over active areas of the substrate in one example. Self-assembly permits the formation of discrete lines of nanostructures that are electrically isolated from one another without requiring patterning or etching of the nanostructure coating.

Abstract: A nonvolatile memory device includes a floating gate formed over a semiconductor substrate, an insulator formed on a first sidewall of the floating gate, a dielectric layer formed on a second sidewall and an upper surface of the floating gate, and a control gate formed over the dielectric layer.

Abstract: A method of forming a semiconductor structure is provided. A substrate having a cell area and a periphery area is provided. A stacked structure including a gate oxide layer, a floating gate and a first spacer is formed on the substrate in the cell area and a resistor is formed on the substrate in the periphery area. At least two doped regions are formed in the substrate beside the stacked structure. A dielectric material layer and a conductive material layer are sequentially formed on the substrate. A patterned photoresist layer is formed on the substrate to cover the stacked structure and a portion of the resistor. The dielectric material layer and the conductive material layer not covered by the patterned photoresist layer are removed, so as to form an inter-gate dielectric layer and a control gate on the stacked structure, and simultaneously form a salicide block layer on the resistor.

Abstract: A method of making a monolithic three dimensional NAND string including forming a stack of alternating layers of a first material and a second material over a substrate. The first material comprises an electrically insulating material and the second material comprises a semiconductor or conductor material. The method also includes etching the stack to form a front side opening in the stack, forming a blocking dielectric layer over the stack of alternating layers of a first material and a second material exposed in the front side opening, forming a semiconductor or metal charge storage layer over the blocking dielectric, forming a tunnel dielectric layer over the charge storage layer, forming a semiconductor channel layer over the tunnel dielectric layer, etching the stack to form a back side opening in the stack, removing at least a portion of the first material layers and portions of the blocking dielectric layer.

Abstract: A method for fabrication a memory having a memory area and a periphery area is provided. The method includes forming a gate insulating layer over a substrate in the periphery area. Thereafter, a first conductive layer is formed in the memory area, followed by forming a buried diffusion region in the substrate adjacent to the sides of the first conductive layer. An inter-gate dielectric layer is then formed over the first conductive layer followed by forming a second conductive layer over the inter-gate dielectric layer. A transistor gate is subsequently formed over the gate insulating layer in the periphery area.

Abstract: A nonvolatile semiconductor memory device includes a plurality of nonvolatile memory cells formed on a semiconductor substrate, each memory cell including source and drain regions separately formed on a surface portion of the substrate, buried insulating films formed in portions of the substrate that lie under the source and drain regions and each having a dielectric constant smaller than that of the substrate, a tunnel insulating film formed on a channel region formed between the source and drain regions, a charge storage layer formed of a dielectric body on the tunnel insulating film, a block insulating film formed on the charge storage layer, and a control gate electrode formed on the block insulating film.

Abstract: A fin field effect transistor and method of forming the same. The fin field effect transistor includes a semiconductor substrate having a fin structure and between two trenches with top portions and bottom portions. The fin field effect transistor further includes shallow trench isolations formed in the bottom portions of the trenches and a gate electrode over the fin structure and the shallow trench isolation, wherein the gate electrode is substantially perpendicular to the fin structure. The fin field effect transistor further includes a gate dielectric layer along sidewalls of the fin structure and source/drain electrode formed in the fin structure.

Abstract: A split gate flash cell device with floating gate transistors is provided. Each floating gate transistor is formed by providing a floating gate transistor substructure including an oxide disposed over a polysilicon gate disposed over a gate oxide disposed on a portion of a common source. Nitride spacers are formed along sidewalls of the floating gate transistor substructure and cover portions of the gate oxide that terminate at the sidewalls. An isotropic oxide etch is performed with the nitride spacers intact. The isotropic etch laterally recedes opposed edges of the oxide inwardly such that a width of the oxide is less than a width of the polysilicon gate. An inter-gate dielectric is formed over the floating gate transistor substructure and control gates are formed over the inter-gate dielectric to form the floating gate transistors.

Abstract: The present disclosure relates to methods of forming a self-aligned contact and related apparatus. In some embodiments, the method forms a plurality of gate lines interspersed between a plurality of dielectric lines, wherein the gate lines and the dielectric lines extend in a first direction over an active area. One or more of the plurality of gate lines are into a plurality of gate line sections aligned in the first direction. One or more of the plurality of dielectric lines are cut into a plurality of dielectric lines sections aligned in the first direction. A dummy isolation material is deposited between adjacent dielectric sections in the first direction and between adjacent gate line sections in the first direction. One or more self-aligned metal contacts are then formed by replacing a part of one or more of the plurality of dielectric lines over the active area with a contact metal.

Abstract: A stack can be patterned by a first etch process to form an opening defining sidewall surfaces of a patterned material stack. A masking layer can be non-conformally deposited on sidewalls of an upper portion of the patterned material stack, while not being deposited on sidewalls of a lower portion of the patterned material stack. The sidewalls of a lower portion of the opening can be laterally recessed employing a second etch process, which can include an isotropic etch component. The sidewalls of the upper portion of the opening can protrude inward toward the opening to form an overhang over the sidewalls of the lower portion of the opening. The overhang can be employed to form useful structures such as an negative offset profile in a floating gate device or vertically aligned control gate electrodes for vertical memory devices.

Abstract: According to example embodiments of inventive concepts, a non-volatile memory device includes a substrate including a second impurity region crossing a first impurity region, and channel regions extending in a vertical direction on the substrate. Gate electrodes may be separated from each other in a vertical direction and a horizontal direction along outer walls of the channel regions. A first insulating interlayer may be on the gate electrodes and the channel regions, where the first insulating interlayer defines a contact hole between at least one adjacent pair gate electrodes and a contact plug is formed in the contact hole to be electrically connected to the second impurity region. An etch stop layer pattern may be on the contact plug and the first insulating interlayer.

Abstract: A floating gate device is provided. A tunnel oxide layer is formed over the channel. A floating gate is formed over the tunnel oxide layer. A high-k dielectric layer is formed over the floating gate. A control gate is formed over the high-k dielectric layer. At least one of the control gate and/or the floating gate includes an oxygen scavenging element. The oxygen scavenging element is configured to decrease an oxygen density at least one of at a first interface between the control gate and the high-k dielectric layer, at a second interface between the high-k dielectric layer and the floating gate, at a third interface between the floating gate and the tunnel oxide layer, and at a fourth interface between the tunnel oxide layer and the channel responsive to annealing.

Abstract: A semiconductor device with an n-type transistor and a p-type transistor having an active region is provided. The active region further includes two adjacent gate structures. A portion of a dielectric layer between the two adjacent gate structures is selectively removed to form a contact opening having a bottom and sidewalls over the active region. A bilayer liner is selectively provided within the contact opening in the n-type transistor and a monolayer liner is provided within the contact opening in the p-type transistor. The contact opening in the n-type transistor and p-type transistor is filled with contact material. The monolayer liner is treated to form a silicide lacking nickel in the p-type transistor.

Abstract: A method of making a monolithic three dimensional NAND string including providing a stack of alternating first material layers and second material layers over a substrate. The first material layers comprise an insulating material and the second material layers comprise sacrificial layers. The method also includes forming a back side opening in the stack, selectively removing the second material layers through the back side opening to form back side recesses between adjacent first material layers and forming a blocking dielectric inside the back side recesses and the back side opening. The blocking dielectric has a clam shaped regions inside the back side recesses. The method also includes forming a plurality of copper control gate electrodes in the respective clam shell shaped regions of the blocking dielectric in the back side recesses.

Abstract: A three-dimensional semiconductor device and a method of fabricating the same, the device including a lower insulating layer on a top surface of a substrate; an electrode structure sequentially stacked on the lower insulating layer, the electrode structure including conductive patterns; a semiconductor pattern penetrating the electrode structure and the lower insulating layer and being connected to the substrate; and a vertical insulating layer interposed between the semiconductor pattern and the electrode structure, the vertical insulating layer crossing the conductive patterns in a vertical direction and being in contact with a top surface of the lower insulating layer.

Abstract: An embodiment relates to a memory device that includes a semiconductor channel, a tunnel dielectric located over the semiconductor channel, a charge storage region located over the tunnel dielectric, a blocking dielectric located over the charge storage region, and a control gate located over the blocking dielectric. An interface between the blocking dielectric and the control gate substantially prevents oxygen diffusion from the blocking dielectric into the control gate.

Abstract: The present disclosure relates to a method of manufacturing a semiconductor memory device, the method including: forming isolation layers in trenches dividing active regions of a substrate; depositing a tunnel insulating layer and a charge storing layer on an entire structure including the isolation layers; forming mask patterns on the charge storing layer to cover the active regions and to expose the isolation layers; and etching the charge storing layer by using the mask patterns as an etch barrier, thereby forming charge storing layer patterns on the active regions.

Abstract: An electronic device can include a tunnel structure that includes a first electrode, a second electrode, and tunnel dielectric layer disposed between the electrodes. In a particular embodiment, the tunnel structure may or may not include an intermediate doped region that is at the primary surface, abuts a lightly doped region, and has a second conductivity type opposite from and a dopant concentration greater than the lightly doped region. In another embodiment, the electrodes have opposite conductivity types. In a further embodiment, an electrode can be formed from a portion of a substrate or well region, and the other electrode can be formed over such portion of the substrate or well region.

Abstract: According to one embodiment, a method includes forming first and second gate patterns each including a structure stacked in order of a first insulating layer, a floating gate layer, a charge trap layer, a second insulating layer and a dummy layer on a semiconductor layer, implanting impurities in the semiconductor layer by an ion implantation using the first and second gate patterns as a mask, forming a third insulating layer on the semiconductor layer, the third insulating layer covering side surfaces of the first and second gate patterns, and forming first and second concave portions, the first concave portion formed by removing the dummy layer of the first gate pattern, the second concave portion formed by removing the dummy layer, the second insulating layer, the charge trap layer and the floating gate layer of the second gate pattern.

Abstract: A method for forming a surrounding stacked gate fin FET nonvolatile memory structure includes providing a silicon-on-insulator (SOI) substrate of a first conductivity type, patterning a fin active region on a region of the substrate, forming a tunnel oxide layer on the fin active region, and depositing a first gate electrode of a second conductivity type on the tunnel oxide layer and upper surface of the substrate. The method further includes forming a dielectric composite layer on the first gate electrode, depositing a second gate electrode on the dielectric composite layer, patterning the first and second gate electrodes to define a surrounding stacked gate area, forming a spacer layer on a sidewall of the stacked gate electrode, and forming elevated source/drain regions in the fin active region on both sides of the second gate electrode.

Abstract: A memory cell comprising: a semiconductor substrate with a surface with a source region and a drain region disposed below the surface of the substrate and separated by a channel region; a tunneling barrier dielectric structure with an effective oxide thickness of greater than 3 nanometers disposed above the channel region; a conductive layer disposed above the tunneling barrier dielectric structure and above the channel region; a charge trapping structure disposed above the conductive layer and above the channel region; a top dielectric structure disposed above the charge trapping structure and above the channel region; and a top conductive layer disposed above the top dielectric structure and above the channel region are described along with devices thereof and methods for manufacturing.

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: A process for forming reversible resistance-switching memory cells having resistance-switching nano-particles which provide a reduced contact area to top and bottom electrodes of the memory cells, thereby limiting a peak current. Recesses are formed in a layered semiconductor material above the bottom electrodes, and one or more coatings of nano-particles are applied. The nano-particles self-assemble in the recesses so that they are positioned in a controlled manner. A top electrode material is then deposited. In one approach, the recesses are formed by spaced-apart trenches, and the nano-particles self-assemble along the spaced-apart trenches. In another approach, the recesses for each resistance-switching memory cell are separate from one another, and the resistance-switching memory cells are pillar-shaped. The coatings can be provided in one layer, or in multiple layers which are separated by an insulation layer.

Abstract: A nonvolatile memory device includes a floating gate formed over a semiconductor substrate, an insulator formed on a first sidewall of the floating gate, a dielectric layer formed on a second sidewall and an upper surface of the floating gate, and a control gate formed over the dielectric layer.

Abstract: A nonvolatile memory device includes a floating gate formed over a semiconductor substrate, an insulator formed on a first sidewall of the floating gate, a dielectric layer formed on a second sidewall and an upper surface of the floating gate, and a control gate formed over the dielectric layer.

Abstract: A mechanism is provided for a spin torque transfer random access memory device. A tunnel barrier is disposed on a reference layer, and a free layer is disposed on the tunnel barrier. The free layer includes an iron layer as a top part of the free layer. A metal oxide layer is disposed on the iron layer, and a cap layer is disposed on the metal oxide layer.

Abstract: Methods of forming multi-tiered semiconductor devices are described, along with apparatuses that include them. In one such method, a silicide is formed in a tier of silicon, the silicide is removed, and a device is formed at least partially in a void that was occupied by the silicide. One such apparatus includes a tier of silicon with a void between tiers of dielectric material. Residual silicide is on the tier of silicon and/or on the tiers of dielectric material and a device is formed at least partially in the void. Additional embodiments are also described.

Abstract: A method for manufacturing a semiconductor device includes the steps of forming a flash memory cell provided with a floating gate, an intermediate insulating film, and a control gate, forming first and second impurity diffusion regions, thermally oxidizing surfaces of a silicon substrate and the floating gate, etching a tunnel insulating film in a partial region through a window of a resist pattern; forming a metal silicide layer on the first impurity diffusion region in the partial region, forming an interlayer insulating film covering the flash memory cell, and forming, in a first hole of the interlayer insulating film, a conductive plug connected to the metal silicide layer.

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: It is made possible to provide a method for manufacturing a semiconductor device that has a high-quality insulating film in which defects are not easily formed, and experiences less leakage current. A method for manufacturing a semiconductor device, includes: forming an amorphous silicon layer on an insulating layer; introducing oxygen into the amorphous silicon layer; and forming a silicon oxynitride layer by nitriding the amorphous silicon layer having oxygen introduced thereinto.

Abstract: A substrate supporting thin film transistors thereon, each including a semiconductor layer and source-drain electrodes, wherein the source-drain electrodes are formed from a nitrogen-containing layer or oxygen/nitrogen-containing layer and a thin film of pure copper or copper alloy. The nitrogen-containing layer or oxygen/nitrogen-containing layer has respectively part or all of its nitrogen or part or all of its oxygen or nitrogen connected to silicon in the semiconductor layer of the thin film transistor, and the thin film of pure copper or copper alloy is connected to the semiconductor layer of said thin film transistor through the nitrogen-containing layer or oxygen/nitrogen-containing layer.

Abstract: A semiconductor device includes a first source layer; at least one of a second source layer, the second source layer formed substantially in the first source layer; a plurality of conductive layers stacked substantially over the first source layer; channel layers that pass through the plurality of conductive layers and couple to the second source layer; and at least one of a third source layer, the third source layer formed substantially in the second source layer, wherein the third source layer passes through the second source layer and is coupled to the first source layer.

Abstract: In one aspect, a disclosed method of fabricating a split gate memory device includes forming a gate dielectric layer overlying an channel region of a semiconductor substrate and forming an electrically conductive select gate overlying the gate dielectric layer. The method further includes forming a counter doping region in an upper region of the substrate. A proximal boundary of the counter doping region is laterally displaced from a proximal sidewall of the select gate. The method further includes forming a charge storage layer comprising a vertical portion adjacent to the proximal sidewall of the select gate and a lateral portion overlying the counter doping region and forming an electrically conductive control gate adjacent to the vertical portion of the charge storage layer and overlying the horizontal portion of the charge storage layer.

Abstract: A semiconductor device including a low-concentration impurity region formed on the drain side of an n-type MIS transistor, in a non-self-aligned manner with respect to an end portion of the gate electrode. A high-concentration impurity region is placed with a specific offset from the gate electrode and a sidewall insulating film. The semiconductor device enables the drain breakdown voltage to be sufficient and the on-resistance to decrease. A silicide layer is also formed on the surface of the gate electrode, thereby achieving gate resistance reduction and high frequency characteristics improvement.

Abstract: A non-volatile memory and a manufacturing method thereof are provided. The non-volatile memory includes a substrate, word lines, select lines, and doped regions. The substrate includes a memory cell region and two select line regions located at two opposite sides of the memory cell region. The word lines are disposed in the memory cell region. The select lines are disposed in the select line regions. A line width of each of the word lines is equal to a line width of each of the select lines. A distance between the adjacent word lines, a distance between the adjacent select lines, and a distance between the adjacent select line and word line are equal to one another. The doped regions are located in the substrate at two sides of each of the word lines and at two sides of each of the select line regions.

Abstract: A non-volatile memory structure includes a source and a drain. The memory structure includes a substrate and a dielectric layer on the substrate. The memory structure further has a gate, which can be a floating gate, on the dielectric layer. A recess is on the drain side and nearest to the bottom corner of the dielectric layer. The recess is configured to reduce the electric field density around the bottom corner nearest to the drain in order to reduce the damage on the dielectric layer when the memory is under a bias.

Abstract: Semiconductor devices include one or more transistors having a floating gate and a control gate. In at least one embodiment, the floating gate comprises an intermediate portion extending between two end portions. The intermediate portion has an average cross-sectional area less than one or both of the end portions. In some embodiments, the intermediate portion may comprise a single nanowire. In additional embodiments, semiconductor devices have one or more transistors having a control gate and a floating gate in which a surface of the control gate opposes a lateral side surface of a floating gate that defines a recess in the floating gate. Electronic systems include such semiconductor devices. Methods of forming semiconductor devices include, for example, forming a floating gate having an intermediate portion extending between two end portions, and configuring the intermediate portion to have an average cross-sectional area less than one or both of the end portions.

Abstract: A method of fabricating a memory device includes providing multiple coatings of nanodots on a tunnel dielectric layer to form a floating gate layer having a high nanodot density. The memory device may have a nanodot-containing floating gate layer with a density greater than 4×1012 dots/cm2. Further methods include forming an oxidation barrier layer, such as a silicon nitride shell, over a surface of the nanodots, and depositing a dielectric material over the nanodots to form a floating gate layer.

Abstract: Embodiments described herein generally relate to methods of manufacturing charge-trapping memory by patterning the high voltage gates before other gates are formed. One advantage of such an approach is that a thin poly layer may be used to form memory and low voltage gates while protecting high voltage gates from implant penetration. One approach to accomplishing this is to dispose the layer of poly, and then dispose a mask and a thick resist to pattern the high voltage gates. In this manner, the high voltage gates are formed before either the low voltage gates or the memory cells.

Abstract: A memory cell including a control gate located over a floating gate region. The floating gate region includes discrete doped semiconducting or conducting regions separated by an insulator and the discrete doped semiconducting or conducting regions have a generally cylindrical shape or a quasi-cylindrical shape.

Abstract: A semiconductor device including a first isolation region dividing a semiconductor substrate into first regions; memory cells each including a tunnel insulating film, a charge storing layer, an interelectrode insulating film, and a control gate electrode above the first region; a second isolation region dividing the substrate into second regions in a peripheral circuit region; and a peripheral circuit transistor including a gate insulating film and a gate electrode above the second region. The first isolation region includes a first trench, a first element isolation insulating film filled in a bottom portion of the first trench, and a first gap formed between the first element isolation insulating film and the interelectrode insulating film. The second isolation region includes a second trench and a second element isolation insulating film filled in the second trench. The first and the second element isolation insulating films have different properties.

Abstract: A semiconductor device and method of making such device is presented herein. The semiconductor device includes a plurality of memory cells, a plurality of p-n junctions, and a metal trace of a first metal layer. Each of the plurality of memory cells includes a first gate disposed over a first dielectric, a second gate disposed over a second dielectric and adjacent to a sidewall of the first gate, a first doped region in the substrate adjacent to the first gate, and a second doped region in the substrate adjacent to the second gate. The plurality of p-n junctions are electrically isolated from the doped regions of each memory cell. The metal trace extends along a single plane between a via to the second gate of at least one memory cell in the plurality of memory cells, and a via to a p-n junction within the plurality of p-n junctions.

Abstract: A nonvolatile memory electronic device including nanowire channel and nanoparticle-floating gate nodes, in which the nonvolatile memory electronic device, which comprises a semiconductor nanowire used as a charge transport channel and nanoparticles used as a charge trapping layer, is configured by allowing the nanoparticles to be adsorbed on a tunneling layer deposited on a surface of the semiconductor nanowire, whereby charge carriers moving through the nanowire are tunneled to the nanoparticles by a voltage applied to a gate, and then, the charge carriers are tunneled from the nanoparticles to the nanowire by the change of the voltage that has been applied to the gate, whereby the nonvolatile memory electronic device can be operated at a low voltage and increase the operation speed thereof.

Abstract: A method of making a monolithic three dimensional NAND string includes forming a stack of alternating layers of a first material and a second material, etching the stack to form a front side opening in the stack, selectively forming a plurality of discrete semiconductor, metal or silicide charge storage regions on portions of the second material layers exposed in the front side opening, forming a tunnel dielectric layer and semiconductor channel layer in the front side opening, etching the stack to form a back side opening in the stack, removing at least a portion of the second material layers through the back side opening to form back side recesses between the first material layers, forming a blocking dielectric in the back side recesses through the back side opening, and forming control gates over the blocking dielectric in the back side recesses through the back side opening.

Abstract: Nonvolatile charge trap memory devices with deuterium passivation of charge traps and methods of forming the same are described. In one embodiment, the device includes a channel formed from a semiconducting material overlying a surface on a substrate connecting a source and a drain of the memory device. A gate stack overlies the channel, the gate stack comprising a tunneling layer, a trapping layer, a blocking layer, a gate layer; and a deuterated gate cap layer. The gate cap layer has a higher deuterium concentration at an interface with the gate layer than at surface of the gate cap layer distal from the gate layer. In certain embodiments, the channel comprises polysilicon or recrystallized polysilicon. Other embodiments are also described.