Abstract: The nonvolatile memory device includes a semiconductor substrate on which a source, a drain, and a channel region are formed, a tunneling oxide film formed on the channel region, a floating gate formed of a transition metal oxide (TMO) on the tunneling oxide, a blocking oxide film formed on the floating gate, a gate electrode formed on the blocking oxide film.

Abstract: A flash memory device and a method for fabricating the same are provided. The flash memory device includes: an active region having a plurality of surface regions and a plurality of recess regions formed lower than the surface regions; a tunnel oxide layer formed over the recess regions; a plurality of recessed floating gates formed over the tunnel oxide layer to be buried into the recess regions; a plurality of dielectric layers over the recessed floating gates; and a plurality of control gates over the dielectric layers.

Abstract: A semiconductor device of an example of the invention comprises a memory cell and a select gate transistor provided for the memory cell. A gate electrode of the select gate transistor has a Tri-gate structure in which an upper surface of a gate insulating film formed above a channel of the select gate transistor is set higher than a portion of an upper surface of an element isolation region of the select gate transistor.

Abstract: The invention relates to semiconductor devices and a method of fabricating the same. In accordance with a method of fabricating a semiconductor device according to an aspect of the invention, a tunnel insulating layer, a first conductive layer, a dielectric layer, a second conductive layer, and a gate electrode layer are sequentially stacked over a semiconductor substrate. The gate electrode layer, the second conductive layer, the dielectric layer, and the first conductive layer are patterned so that the first conductive layer partially remains to prevent the tunnel insulating layer from being exposed. Sidewalls of the gate electrode layer are etched. A first passivation layer is formed on the entire surface including the sidewalls of the gate electrode layer. At this time, a thickness of the first passivation layer formed on the sidewalls of the gate electrode layer is thicker than that of the first passivation layer formed in other areas.

Abstract: According to an aspect of the present invention, there is provided a method for fabricating a nonvolatile semiconductor memory device including a memory cell being formed in a first region of a semiconductor substrate and a periphery circuit being formed in a second region of the semiconductor substrate, including forming a first gate electrode material film over the semiconductor substrate via a first gate insulator in the first region, etching the first gate electrode material film and the first gate insulator using a mask having a first opening in a first element isolation of the first region, etching the semiconductor substrate to a first depth to form a first isolation groove, forming a first insulation isolation layer in the first isolation groove, forming a second insulator on the first insulation isolation layer and on the first gate electrode, removing the second insulator by anisotropic etching, etching an upper portion of the first gate electrode to a second depth to form a first concave portion on

Abstract: A method of forming a micro pattern in a semiconductor device includes: forming an target layer, a hard mask layer and first sacrificial patterns over a semiconductor substrate on which a cell gate region, a selective transistor region and a periphery circuit region are defined; forming an insulating layer and a second sacrificial layer on the hard mask layer and the first sacrificial patterns; removing the insulating layer and the second sacrificial layer formed in the selective transistor region and the periphery circuit region; performing the first etch process so as to allow the second sacrificial layer formed in the cell gate region to remain on the insulating layer between the first sacrificial patterns for forming second sacrificial patterns; removing the insulating layer placed on the first sacrificial patterns and between the first and second sacrificial patterns in the cell gate region; etching the hard mask layer using the second etch process utilizing the first and second sacrificial patterns as t

Abstract: There is provided a nonvolatile storage device including a plurality of component memory layers. The plurality of component memory layers are stacked In a direction perpendicular to a layer surface. Each of the plurality of component memory layers includes a first wiring, a second wiring provided non-parallel to the first wiring and a stacked structure unit provided between the first wiring and the second wiring and including a recording layer. At least one of the first wiring and the second wiring includes a protruding portion provided on a portion opposed to the recording layer and protruding toward the recording layer side.

Abstract: A floating gate is formed on one side of the semiconductor fin on a floating gate dielectric. A control gate dielectric is formed on the opposite side of the semiconductor fin and on the floating gate. A gate conductor is formed on the control gate dielectric across the semiconductor fin. A gate spacer reaching above a gate cap layer and the control gate dielectric thereupon is formed by a conformal deposition of a dielectric layer and a reactive ion etch. The control gate dielectric and the material of the floating gate are removed from exposed portions of the semiconductor fin. The gate spacer is thereafter removed and source and drain regions are formed in the semiconductor fin. The overlap between the drain and the floating gate is extended by the thickness of the gate spacer, resulting in an enhanced efficiency in charge trapping in the floating gate.

Abstract: A method of fabricating a memory cell including forming nanodots over a first dielectric layer and forming a second dielectric layer over the nanodots, where the second dielectric layer encases the nanodots. In addition, an intergate dielectric layer is formed over the second dielectric layer. To form sidewalls of the memory cell, a portion of the intergate dielectric layer and a portion of the second dielectric layer are removed with a dry etch, where the sidewalls include a location where a nanodot has been deposited. A spacing layer is formed over the sidewalls to cover the location where a nanodot has been deposited and the remaining portion of the second dielectric layer and the nanodots can be removed with an isotropic etch selective to the second dielectric layer.

Abstract: Methods of manufacturing a semiconductor device include forming an absorption layer on a surface of a substrate by exposing the surface of the substrate to a first reaction gas at a first temperature. A metal oxide layer is then formed on the surface of the substrate by exposing the absorption layer to a second reaction gas at a second temperature. The first reaction gas may include a precursor containing zirconium (e.g., tetrakis(ethylmethylamino)zirconium) and the second reaction gas may include an oxidizing agent.

Abstract: A semiconductor memory device has side surfaces of neighboring bit lines that do not face each other to reduce a capacitance of a parasitic capacitor formed between adjacent bit lines. The semiconductor memory device includes contact plugs formed on a semiconductor substrate. Each contact plug is disposed between gate patterns. First and second conductive pads extend in different directions and are connected to the contact plugs. First and second pad contact plugs are formed on extended peripheries of the first and second conductive pads, respectively. Each of the first pad contact plugs has a height which differs from a height of each of the second pad contact plugs. First bit lines are connected to the first pad contact plugs, and second bit lines are connected to the second pad contact plugs.

Abstract: In a semiconductor device and a method of manufacturing a semiconductor device, a lower electrode is formed on a semiconductor substrate. A first zirconium oxide layer is formed on the lower electrode by performing a first deposition process using a first zirconium source and a first oxidizing gas. A zirconium carbo-oxynitride layer is formed on the first zirconium oxide layer by performing a second deposition process using a second zirconium source, a second oxidizing gas and a nitriding gas, and an upper electrode is formed on the zirconium carbo-oxynitride layer. A zirconium oxide-based composite layer having a high dielectric constant and a thin equivalent oxide thickness can be obtained.

Abstract: Embodiments of the invention provide memory devices and methods for forming memory devices. In one embodiment, a memory device is provided which includes a floating gate polysilicon layer disposed over source/drain regions of a substrate, a silicon oxynitride layer disposed over the floating gate polysilicon layer, a first aluminum oxide layer disposed over the silicon oxynitride layer, a hafnium silicon oxynitride layer disposed over the first aluminum oxide layer, a second aluminum oxide layer disposed over the hafnium silicon oxynitride layer, and a control gate polysilicon layer disposed over the second aluminum oxide layer. In another embodiment, a memory device is provided which includes a control gate polysilicon layer disposed over an inter-poly dielectric stack disposed over a silicon oxide layer disposed over the floating gate polysilicon layer. The inter-poly dielectric stack contains two silicon oxynitride layers separated by a silicon nitride layer.

Abstract: A semiconductor memory device includes a semiconductor substrate including an insulating layer, a charge storage region of a first conductivity type on the insulating layer, and an insulating film on the insulating layer and surrounding the charge storage region. A body region of the first conductivity type is on an upper surface of the charge storage region, and a gate stack including a gate electrode and a gate insulating film is on the body region. A source region and a drain region of a second conductivity type are on opposite sides of the body region. The charge storage region extends further towards the semiconductor substrate than the source region and/or the drain region. Methods of forming semiconductor memory devices are also disclosed.

Abstract: A semiconductor memory device according to an embodiment of the present invention includes a resistance element which is constructed with a first conductor which extends in a first direction and is connected to a first contact; a second conductor which extends in said first direction and is connected to a second contact; and a first insulation film which exists between said first conductor and said second conductor, said first insulation film also having an opening in which a third conductor which connects said first conductor and said second conductor is arranged.

Abstract: The present invention provides a flash memory integrated circuit and a method for fabricating the same. The method includes etching a gate stack that includes an initial oxide layer directly in contact with a silicon layer, defining an oxide-silicon interface therebetween. By exposing the etched gate stack to elevated temperatures and a dilute steam ambient, additional oxide material is formed substantially uniformly along the oxide-silicon interface. Polysilicon grain boundaries at the interface are thereby passivated after etching. In the preferred embodiment, the interface is formed between a tunnel oxide and a floating gate, and passivating the grain boundaries reduces erase variability due to enhanced charge transfer along grain boundaries. At the same time, oxide in an upper storage dielectric layer (oxide -nitride-oxide or ONO) is enhanced in the dilute steam oxidation.

Abstract: Disclosure is semiconductor device of a selective gate region, comprising a semiconductor layer, a first insulating film formed on the semiconductor layer, a first electrode layer formed on the first insulating layer, an element isolating region comprising an element isolating insulating film formed to extend through the first electrode layer and the first insulating film to reach an inner region of the semiconductor layer, the element isolating region isolating a element region and being self-aligned with the first electrode layer, a second insulating film formed on the first electrode layer and the element isolating region, an open portion exposing a surface of the first electrode layer being formed in the second insulating film, and a second electrode layer formed on the second insulating film and the exposed surface of the first electrode layer, the second electrode layer being electronically connected to the first electrode layer via the open portion.

Abstract: Semiconductor devices and methods of fabricating the same are provided. A gate insulating film is provided on a semiconductor substrate. A polymetal gate electrode is provided on the gate insulating film. The polymetal gate electrode includes a conductive polysilicon film on the gate insulating film, a first metal silicide film on the conductive polysilicon film, a barrier film on the first metal silicide film, and a metal film on the barrier film. The barrier film includes a titanium nitride (TiN) film on the first metal silicide film and a buffer layer between the TiN film and the metal film.

Abstract: A dual CESL process includes: (1) providing a substrate having thereon a first device region, a second device region and a shallow trench isolation (STI) region between the first and second device regions; (2) forming a first-stress imparting film with a first stress over the substrate, wherein the first-stress imparting film does not cover the second device region; and (3) forming a second-stress imparting film with a second stress over the substrate, wherein the second-stress imparting film does not cover the first device region, an overlapped boundary between the first- and second-stress imparting films is created directly above the STI region, and wherein the overlapped boundary is placed in close proximity to the second device region in order to induce the first stress to a channel region thereof in a transversal direction.

Abstract: The present invention provides a semiconductor device in which the gate is self-aligned to the device isolation film and a fabricating method thereof. A device isolation film restricting an active region is disposed on a portion of a semiconductor substrate, and a word line is across over the device isolation film. A gate pattern is disposed between the word line and the active region, and a tunnel oxide film is disposed between the gate pattern and the active region. The gate pattern comprises a floating gate pattern, a gate interlayer dielectric film pattern and a control gate electrode pattern deposited in the respective order, and has a sidewall self-aligned to the device isolation film. To form the gate pattern having the sidewall self-aligned to the device isolation film, a gate insulation film and a gate material film are formed in the respective order on the semiconductor substrate.

Abstract: A method of manufacturing a nonvolatile memory device includes forming a plurality of device isolation regions in a semiconductor substrate, forming a tunneling insulation layer on the semiconductor substrate, forming a first preliminary polysilicon layer in communication with the tunneling insulation layer and the device isolation regions, forming a preliminary amorphous silicon layer on the first preliminary silicon layer, forming a second preliminary polysilicon layer on the preliminary amorphous silicon layer, and patterning the second preliminary polysilicon layer, the preliminary amorphous silicon layer, and the first preliminary polysilicon layer to form a floating gate layer.

Abstract: A diblock copolymer layer comprising at least two polymers and having a lamellar structure perpendicularly to a substrate is deposited on a first gate insulator formed on the substrate. One of the polymers of the diblock copolymer layer is then eliminated to form parallel grooves in the copolymer layer. The grooves are filled by a first metallic or semi-conductor material and the rest of the copolymer layer is eliminated. A second dielectric material is deposited to form a second gate insulator. The second gate insulator of the floating gate then comprises an alternation of parallel first and second lines respectively of the first and second materials, the second material encapsulating the lines of the first material.

Abstract: Non-volatile memory devices and a method of manufacturing the same, wherein data storage of two bits per cell is enabled and the devices can pass the limit in terms of layout, whereby channel length can be controlled. The non-volatile memory device includes gate lines formed in one direction on a semiconductor substrate in which trenches are formed, wherein the gate lines gap-fill the trenches, a dielectric layer formed between the semiconductor substrate and the gate lines, bit separation insulating layers formed between the semiconductor substrate and the dielectric layer under the trenches, and isolation structures formed by etching the trenches, and the dielectric layer and the semiconductor substrate between the trenches in a line form vertical to the gate lines and gap-filling an insulating layer.

Abstract: A non-volatile semiconductor memory device includes: a nonvolatile memory area including gate electrodes, each including stack of a floating gate, an inter-electrode insulating film and a control gate, and having first insulating side walls formed on side walls of the gate electrode; a peripheral circuit area including single-layer gate electrodes made of the same layer as the control gate; and a first border area including: a first isolation region formed in the semiconductor substrate for isolating the non-volatile memory area and peripheral circuit area; a first conductive pattern including a portion made of the same layer as the control gate and formed above the isolation region; and a first redundant insulating side wall made of the same layer as the first insulating side wall and formed on the side wall of the first conductive pattern on the side of the non-volatile memory area.

Abstract: Nonvolatile memory devices are provided including an integrated circuit substrate and a charge storage pattern on the integrated circuit substrate. The charge storage pattern has a sidewall and a tunnel insulating layer is provided between the charge storage pattern and the integrated circuit substrate. A gate pattern is provided on the charge storage pattern. A blocking insulating layer is provided between the charge storage pattern and the gate pattern. The sidewall of the charge storage pattern includes a first nitrogen doped layer. Related methods of fabricating nonvolatile memory devices are also provided herein.

Abstract: A memory device includes a semiconductor substrate, a first gate insulator on a first portion of a semiconductor substrate, a storage node on the first gate insulator, a tunnel junction barrier on the storage node and a data electrode on the layer tunnel junction barrier. The device further includes a second gate insulator layer on a sidewall of the tunnel junction barrier, a third gate insulator on a second portion of the substrate adjacent the tunnel junction barrier and a gate electrode on the second gate insulator and the third gate insulator. First and second impurity-doped regions are disposed in the substrate and are coupled by a channel through the first and second portions of the substrate. Fabrication of such a device is also describes.

Abstract: A method for forming a gate electrode of a semiconductor device is provided wherein a hard mask layer which is a nitride film is deposited and subjected to an additional surface deposition process so that a matrix structure of a nitride film surface becomes more compact to reduce an etching ratio of the hard mask layer thereby increasing a thickness of the residual hard mask layer.

Abstract: Electronic apparatus and methods of forming the electronic apparatus include a hafnium lanthanide oxynitride film on a substrate for use in a variety of electronic systems. The hafnium lanthanide oxynitride film may be structured as one or more monolayers. Metal electrodes may be disposed on a dielectric containing a hafnium lanthanide oxynitride film.

Abstract: A method of manufacturing a NAND flash memory device, wherein isolation layers are formed in a semiconductor substrate, and an upper side of each of the isolation layers is made to have a negative profile. A polysilicon layer is formed on the entire surface. At this time, a seam is formed within the polysilicon layer due to the negative profile. A post annealing process is performed in order to make the seam to a void. Accordingly, an electrical interference phenomenon between cells can be reduced and a threshold voltage (Vt) shift value can be lowered.

Abstract: A semiconductor device including an oxide-nitride-oxide (ONO) structure having a multi-layer charge storing layer and methods of forming the same are provided. Generally, the method involves: (i) forming a first oxide layer of the ONO structure; (ii) forming a multi-layer charge storing layer comprising nitride on a surface of the first oxide layer; and (iii) forming a second oxide layer of the ONO structure on a surface of the multi-layer charge storing layer. Preferably, the charge storing layer comprises at least two silicon oxynitride layers having differing stoichiometric compositions of Oxygen, Nitrogen and/or Silicon. More preferably, the ONO structure is part of a silicon-oxide-nitride-oxide-silicon (SONOS) structure and the semiconductor device is a SONOS memory transistor. Other embodiments are also disclosed.

Abstract: A new SONOS memory device is provided, in which a conventional planar surface of multi-dielectric layers (ONO layers) is instead formed with a curved surface such as a cylindrical shape, and included is a method for fabricating the same. A radius of curvature of the upper surface of a blocking oxide can be designed to be larger than that of the lower surface of a tunneling oxide, which restrains electrons from passing through the blocking oxide by back-tunneling on erasing. As a result, a SONOS memory device shows an improvement in erasing speed.

Abstract: Method and device embodiments are described for fabricating MOSFET transistors in a semiconductor also containing non-volatile floating gate transistors. MOSFET transistor gate dielectric smiling, or bird's beaks, are adjustable by re-oxidation processing. An additional re-oxidation process is performed by opening a poly-silicon layer prior to forming an inter-poly oxide dielectric provided for the floating gate transistors.

Abstract: A semiconductor device according to an embodiment of the present invention has a bit line and a word line. The device includes a substrate which is provided with first trenches extending in a bit-line direction and has side surfaces forming sidewalls of the first trenches, the substrate being provided with bird's beaks at upper edges of the side surfaces, a first gate insulator formed on the substrate between the first trenches, a floating gate formed on the first gate insulator between the first trenches and located between second trenches extending in a word-line direction, the floating gate not being provided with bird's beaks at lower edges of side surfaces facing the first trenches, a second gate insulator formed on the floating gate between the second trenches, and a control gate formed on the second gate insulator between the second trenches.

Abstract: A method of fabricating a non-volatile memory device, A tunnel insulating layer, a floating gate, and a pad nitride layer is formed on a semiconductor substrate. A isolation region of the semiconductor substrate is formed by etching to a predetermined depth, and a liner insulating layer is formed on an entire surface of the resulting trench for device isolation. A filling insulation layer is formed on the liner insulating layer to fill the trench and a first etching process is performed on the filling insulation layer and the liner insulating layer. The surface of semiconductor is recessed by performing a second etching process on the filling insulation layer. A capping layer is formed on an entire surface of the result formed by the second etching process. The device isolation layer of a concave shape is formed by performing an etching process on the capping layer.

Abstract: A non-volatile memory device includes isolation layers, a cell trench, a floating gate, a common source region and a word line. The isolation layers define an active region of a substrate. The cell trench is formed in the active region. The cell trench extends in a first direction. The floating gate is formed on the active region and in the cell trench. The common source region is formed on the active region adjacent a second side face of the floating gate and extends in a second direction substantially perpendicular to the first direction. The word line is formed on the active region, which is adjacent to a first side face of the floating gate opposite to the second side face, and the isolation layers and in the cell trench. The word line extends in the second direction.

Abstract: A NOR flash memory has a plurality of memory cell transistors, wherein each memory cell transistor shares the source diffusion layer with another memory cell transistor adjacent thereto on one side thereof in the column direction and shares the drain diffusion layer with another memory cell transistor adjacent thereto on the other side thereof in the column direction, and the width of the source diffusion layer in the column direction is narrower than the width of the drain diffusion layer in the column direction.

Abstract: Methods of forming a gate structure for an integrated circuit memory device include forming a first dielectric layer having a dielectric constant of under 7 on an integrated circuit substrate. Ions of a selected element from group 4 of the periodic table and having a thermal diffusivity of less than about 0.5 centimeters per second (cm2/s) are injected into the first dielectric layer to form a charge storing region in the first dielectric layer with a tunnel dielectric layer under the charge storing region. A metal oxide second dielectric layer is formed on the first dielectric layer, the second dielectric layer. The substrate including the first and second dielectric layers is thermally treated to form a plurality of discrete charge storing nano crystals in the charge storing region and a gate electrode layer is formed on the second dielectric layer. Gate structures for integrated circuit devices and memory cells are also provided.

Abstract: Non-volatile memory devices according to embodiments of the present invention include an EEPROM transistor in a first portion of a semiconductor substrate, an access transistor in a second portion of the semiconductor substrate and an erase transistor in a third portion of the semiconductor substrate. The second portion of the semiconductor substrate extends adjacent a first side of the first portion of the semiconductor substrate and the third portion of the semiconductor substrate extends adjacent a second side of the first portion of the semiconductor substrate. The first and second sides of the first portion of the semiconductor substrate may be opposite sides of the first portion of the semiconductor substrate. The access transistor has a first source/drain terminal electrically connected to a first source/drain terminal of the EEPROM transistor and the erase transistor has a first source/drain terminal electrically connected to a second source/drain terminal of the access transistor.

Abstract: A method for forming a semiconductor device includes forming a gate dielectric layer over a substrate; forming a first conductive layer over the substrate; forming a dielectric layer over the first conductive layer; forming a second conductive layer over the dielectric layer; forming a sacrificial layer over the second conductive layer; patterning the sacrificial and other layers to form a plurality of gate electrode patterns; forming a buried oxide layer over and between the gate electrode patterns; and removing the sacrificial layer to form a plurality of trenches surrounded by the buried oxide layer. A metal layer is formed within the trench to form a plurality of metal gate structures, the metal layer contacting the second conductive layer that is exposed by the removal of the sacrificial layer.

Abstract: A method of fabricating a silicon nitride layer is described. First, a substrate is provided. Then, a silicon nitride layer is formed on the substrate. The silicon nitride layer is UV-cured in an atmosphere lower than the standard atmospheric pressure. Through the UV curing treatment, the tensile stress of the silicon nitride layer is increased.

Abstract: Electronic apparatus and methods of forming the electronic apparatus include a tantalum lanthanide oxynitride film on a substrate for use in a variety of electronic systems. The tantalum lanthanide oxynitride film may be structured as one or more monolayers. Metal electrodes may be disposed on a dielectric containing a tantalum lanthanide oxynitride film.

Abstract: A method of manufacturing a semiconductor device according to one aspect of the present invention comprises: forming a gate insulation film on a semiconductor substrate in which element separation regions are formed; depositing a gate lower layer material on the semiconductor substrate via the gate insulation film; depositing a gate upper layer material, which is composed of a material different from the gate lower layer material, on the gate lower layer material; forming a gate comprising a gate upper layer and a gate lower layer by selectively processing the gate upper layer material and the gate lower layer material; increasing the size of the gate upper layer in a horizontal direction with respect to the semiconductor substrate by carrying out a chemical reaction processing treatment to which the gate upper layer has a higher reaction speed than the gate lower layer; forming an impurity implantation region by implanting ions into the semiconductor substrate using the gate upper layer as a mask; and formin

Abstract: A semiconductor device comprises a semiconductor substrate, and a non-volatile memory cell provided on the semiconductor substrate, the non-volatile memory cell comprising a tunnel insulating film having a film thickness periodically and continuously changing in a channel width direction of the non-volatile memory cell, a floating gate electrode provided on the tunnel insulating film, a control gate electrode provided above the floating gate electrode, and an interelectrode insulating film provided between the control gate electrode and the floating gate electrode.

Abstract: In a semiconductor device manufacturing method of the invention, a metal film, for forming a gate electrode, is formed on a gate insulating film. Subsequently, when the metal film is processed, part of the metal film is removed by a wet etching process using a given chemical liquid.

Abstract: Embodiments relate to a semiconductor device that may include a semiconductor substrate including a cell area and a pad area, a first insulating layer on and/or over the semiconductor substrate, and a first interconnection trench formed in the first insulating layer on and/or over a cell area having a first width. It may also include a first pad trench formed in the first insulating layer on and/or over the pad area and having a second width wider than the first width, and a first metal interconnection formed in the first interconnection trench and a first pad formed in the first pad trench. It may further include a second insulating layer on and/or over the first insulating layer, a second interconnection trench, exposing the first metal interconnection, and a second pad exposing the first pad and having a position and width substantially identical to that of the first pad trench.

Abstract: In a method of forming a conductive pattern in a semiconductor device, a conductive layer including a metal is formed on a substrate. A mask including carbon is provided on the conductive layer, and the conductive pattern is formed on the substrate by etching the conductive layer using the mask as an etching mask. The mask is removed from the conductive pattern by an oxygen plasma ashing process. An oxidized portion of the conductive pattern is reduced. The conductive pattern may have a desired resistance by reducing the oxidized portion to improve electrical characteristics and reliability of the semiconductor device.

Abstract: A memory structure including a semiconductor substrate, an insulator layer formed on the semiconductor substrate and a gate layer formed on the insulator layer is disclosed. The insulator layer includes a first nanocrystal implanted region proximate to the gate layer and a second nanocrystal implanted region proximate to the semiconductor substrate, wherein the first nanocrystal implanted region has an average nanocrystal concentration which is higher than an average nanocrystal concentration of the second nanocrystal implanted region.

Abstract: Methods of forming a semiconductor device may include forming a tunnel oxide layer on a semiconductor substrate, forming a gate structure on the tunnel oxide layer, forming a leakage barrier oxide, and forming an insulating spacer. More particularly, the tunnel oxide layer may be between the gate structure and the substrate, and the gate structure may include a first gate electrode on the tunnel oxide layer, an inter-gate dielectric on the first gate electrode, and a second gate electrode on the inter-gate dielectric with the inter-gate dielectric between the first and second gate electrodes. The leakage barrier oxide may be formed on sidewalls of the second gate electrode. The insulating spacer may be formed on the leakage barrier oxide with the leakage barrier oxide between the insulating spacer and the sidewalls of the second gate electrode. In addition, the insulating spacer and the leakage barrier oxide may include different materials. Related structures are also discussed.

Abstract: A semiconductor memory device comprises a plurality of transistors having a stacked-gate structure. Each transistor includes a semiconductor substrate, a gate insulator formed on the semiconductor substrate, a lower gate formed on the semiconductor substrate with the gate insulator interposed, an intergate insulator formed on the lower gate, and an upper gate formed and silicided on the lower gate with the intergate insulator interposed. A portion of the transistors has an aperture formed through the intergate insulator to connect the lower gate with the upper gate and further includes a block film composed of an insulator and formed smaller than the upper gate and larger than the aperture above the upper gate to cover the aperture.

Abstract: Provided is a flash memory device and a method of manufacturing the same. In the method, a tunnel oxide layer pattern and a first polysilicon pattern are formed on a semiconductor substrate. A first dielectric layer including a first oxide layer, a first nitride layer, a second oxide layer, a second nitride layer and a third oxide layer is formed on the semiconductor substrate including the first polysilicon pattern. A second polysilicon pattern is formed on the dielectric layer pattern. The flash memory device includes a tunnel oxide layer pattern and a first polysilicon pattern on a semiconductor substrate; a dielectric layer on the first polysilicon pattern, including a first oxide layer pattern, a first nitride layer pattern, a second oxide layer pattern, a second nitride layer pattern and a third oxide layer pattern; and a second polysilicon pattern on the dielectric layer pattern.