Abstract: In forming an element isolation trench, an insulating film formed above a semiconductor substrate is etched such that relatively thin insulating film situated in the memory cell region is fully removed whereas relatively thick insulating film situated in the peripheral circuit region is etched so as to leave a remainder insulating film. Then, using the remainder insulating film in the peripheral circuit region as an etch stopper, the semiconductor substrate is etched, whereafter the remainder insulating film in the peripheral circuit region is fully removed to subsequently etch the semiconductor substrate.

Abstract: A non-volatile semiconductor memory device capable of more efficiently trapping charges in a charge storage layer without increasing the thickness of the charge storage layer, as well as a manufacturing method thereof. In the non-volatile semiconductor memory device a tunnel insulating film, a charge storage layer, a block insulating film, and a gate electrode are disposed successively between a first source/drain region and a second source/drain region above a semiconductor substrate. The charge storage layer has a first layer and second layers, the first layer has a first nitrogen atom concentration, each of the second layers has a second nitrogen atom concentration, higher than the first nitrogen atom concentration and faces one of the tunnel insulating film and the block insulator.

Abstract: A method for fabricating a semiconductor device includes forming a hard mask pattern over a substrate, forming a protection layer by transforming a portion of a sidewall of the hard mask pattern, forming a trench by etching the substrate using the hard mask pattern and the protection layer as an etch barrier, forming an isolation layer by filling the trench with an insulation material, removing the hard mask pattern, and performing a cleaning process. By forming the protection layer, it is possible to prevent the isolation layer from being lost during the removing of the hard mask pattern and the cleaning process and thus prevent generation of a moat.

Abstract: A semiconductor integrated circuit device is provided. The semiconductor integrated circuit device includes a plurality of isolation regions which are formed within a semiconductor substrate and define active regions. A tunnel layer and a trap seed layer are formed in each of the active regions and are sequentially stacked between the isolation regions. A trap layer is formed on the trap seed layer and protrudes further than a top surface of each of the isolation regions. A blocking layer is formed on the trap layer. A gate electrode is formed on the blocking layer.

Abstract: A method for manufacturing a semiconductor device includes: forming a stacked body of a dielectric layer including a silicon oxide and a conductive layer including silicon above a substrate; and forming a hole penetrating through the dielectric layer and the conductive layer in the stacked body, the forming the hole including: forming a first mask layer including a silicon oxide above the stacked body; etching the conductive layer while using the first mask layer as a mask; and forming a second mask layer having more silicon content than the dielectric layer above the first mask layer to etch the dielectric layer while using the second mask layer as a mask.

Abstract: A non-volatile semiconductor memory device of small size and high reliability includes a semiconductor substrate; a charge storage film disposed on the semiconductor substrate; a first gate electrode disposed on the charge storage film; a gate insulating film disposed on the semiconductor substrate; a second gate electrode disposed on the gate insulating film; and an inter-gate insulating film disposed between the first gate electrode and the second gate electrode. The length of the first gate electrode is smaller than the length of the second gate electrode. The top surface of the first gate electrode is neither curved nor inclined with respect to the semiconductor substrate.

Abstract: An insulating layer formed by deposition is annealed in the presence of radical oxygen to reduce bond defects. A substrate is provided. An oxide layer is deposited overlying the substrate. The oxide layer has a plurality of bond defects. The oxide layer is annealed in the presence of radical oxygen to modify a substantial portion of the plurality of bond defects by using oxygen atoms. The anneal, in one form, is an in-situ steam generation (ISSG) anneal. In one form, the insulating layer overlies a layer of charge storage material, such as nanoclusters, that form a gate structure of a semiconductor storage device. The ISSG anneal repairs bond defects by oxidizing defective silicon bonds in the oxide layer when the oxide layer is silicon dioxide.

Abstract: Disclosed are embodiments of semiconductor wafer structures and associated methods of forming the structures with balanced reflectance and absorption characteristics. The reflectance and absorption characteristics are balanced by manipulating thin film interferences. Specifically, thin film interferences are manipulated by selectively varying the thicknesses of the different films. Alternatively, reflectance and absorption characteristics can be balanced by incorporating an additional reflectance layer into the wafer structure above the substrate.

Abstract: The method for fabricating the dielectric layer of the present invention is described as follows. A substrate is provided in a chamber, wherein the chamber is a single-wafer LPCVD chamber. A silicon source gas, an oxidation source gas and a nitridation source gas are then introduced into the chamber, wherein a volumetric flow rate ratio of the oxidation source gas to a total amount of the oxidation source gas and the nitridation source gas is varied within a range of 0.0245 to 0.375. Afterwards, the dielectric layer with a dielectric constant within a range of 4.8 to 7.6 is formed on the substrate.

Abstract: A method of fabricating a semiconductor device including forming a charge storage layer, and forming a first tunnel insulating layer covering the charge storage layer, the forming of the first tunnel insulating layer including heat treating the charge storage layer.

Abstract: Disclosed are embodiments of a semiconductor structure and method of forming the structure with selectively adjusted reflectance and absorption characteristics in order to selectively control temperature changes during a rapid thermal anneal and, thereby, to selectively control variations in device performance and/or to selectively optimize the anneal temperature of such devices. Selectively controlling the temperature changes in different devices during a rapid thermal anneal is accomplished by selectively varying the isolation material thickness in different sections of a shallow trench isolation structures. Alternatively, it is accomplished by selectively varying the pattern of fill structures in different sections of a semiconductor wafer so that predetermined amounts of shallow trench isolation regions in the different sections are exposed.

Abstract: There is provided a nonvolatile memory device having a tunnel dielectric layer formed over a substrate, the charge capturing layer formed over the tunnel dielectric layer and including a combination of at least one charge storage layer and at least one charge trap layer, a charge blocking layer formed over the charge capturing layer, and a gate electrode formed over the charge blocking layer.

Abstract: In a memory device and a method of forming the same, in one embodiment, the memory device comprises a first word line structure on a substrate, the first word line structure extending in a first direction. A bit line is provided over the first word line structure and spaced apart from the first word line by a first gap, the bit line extending in a second direction transverse to the first direction. A second word line structure is provided over the bit line and spaced apart from the bit line by a second gap, the second word line structure extending in the first direction.

Abstract: A method of forming a flash memory device includes forming a plurality of memory gates over a semiconductor substrate, forming an oxide film over the uppermost surface and sidewalls of the memory gates and then forming a plurality of selective gates on sidewalls of each of the memory gates.

Abstract: A semiconductor device includes a semiconductor region, a tunnel insulating film formed on the semiconductor region, a charge-storage insulating film formed on the tunnel insulating film, a block insulating film formed on the charge-storage insulating film, and a control gate electrode formed on the block insulating film, wherein the tunnel insulating film comprises a first region which is formed on a surface of the semiconductor region and contains silicon and oxygen, a second region which contains silicon and nitrogen, a third region which is formed on a back surface of the charge-storage insulating film and contains silicon and oxygen, and an insulating region which is formed at least between the first region and the second region or between the second region and the third region, and contains silicon and nitrogen and oxygen and the second region is formed between the first region and the third region.

Abstract: A semiconductor device according to the present invention comprises a semiconductor substrate, a gate insulating film which is composed of a material whose main component is a tetravalent metal oxide, a mixture of a tetravalent metal oxide and SiO2, or a mixture of a tetravalent metal oxide and SiON and which containing B when it is in an nMOS structure on the semiconductor substrate or containing at least one of P and As when it is in a pMOS structure on the semiconductor substrate, and a gate electrode made of a metal having a work function of 4 eV to 5.5 eV.

Abstract: A method for fabricating, a vertical channel type nonvolatile memory device includes: alternately forming a plurality of sacrificial layers and a plurality of interlayer dielectric layers over a semiconductor substrate; etching the sacrificial layers and the interlayer dielectric layers to form a plurality of first openings for channel each of which exposes the substrate; filling the first openings to form a plurality of channels protruding from the semiconductor substrate; etching the sacrificial layers and the interlayer dielectric layers to form second openings for removal of the sacrificial layers between the channels; exposing sidewalls of the channels by removing the sacrificial layers exposed by the second openings; and forming a tunnel insulation layer, a charge trap layer, a charge blocking layer, and a conductive layer for gate electrode on the exposed sidewalls of the channels.

Abstract: Disclosed are a semiconductor device and a manufacturing method thereof. The semiconductor device includes a first insulating layer pattern on a semiconductor substrate, a second insulating layer including fluorine on the first insulating layer pattern, a third insulating layer pattern on the second insulating layer pattern, and a polysilicon pattern on the third insulating layer pattern. The fluorine is included in the second insulating layer that may be a nitride layer that stores data in a flash memory device, so that data retention and reliability are improved without exerting an influence upon capacitor characteristics.

Abstract: A gate structure for a semiconductor device is provided. The gate structure includes a conductive structure. The conductive structure insulatively disposed over a substrate includes a middle portion and two spacer portions. The middle portion has a first surface and two second surfaces. The first surface is between the two second surfaces. The two spacer portions are respectively connected to the two second surfaces of the middle portion. A width of each of the two spacer portions gradually increases from top to bottom.

Abstract: On a silicon substrate is formed a stacked body by alternately stacking a plurality of silicon oxide films and silicon films, a trench is formed in the stacked body, an alumina film, a silicon nitride film and a silicon oxide film are formed in this order on an inner surface of the trench, and a channel silicon crystalline film is formed on the silicon oxide film. Next, a silicon oxide layer is formed at an interface between the silicon oxide film and the channel silicon crystalline film by performing thermal treatment in an oxygen gas atmosphere.

Abstract: A method of manufacturing a semiconductor device includes forming silicon pillar 11 on substrate 10, forming a protective film which covers an upper end portion and a lower end portion of a side surface of silicon pillar 11, forming a constricted portion by anisotropic etching in a portion of the side surface of silicon pillar 11 which is not covered with the protective film after forming the protective film, removing the protective film after forming the constricted portion, forming gate oxide film 12 which covers the side surface of silicon pillar 11 in which the constricted portion is formed, and forming gate electrode 13 which covers gate oxide film 12.

Abstract: Methods for fabricating dual bit memory devices are provided. In an exemplary embodiment of the invention, a method for fabricating a dual bit memory device comprises forming a charge trapping layer overlying a substrate and etching an isolation opening through the charge trapping layer. An oxide layer is formed overlying the charge trapping layer and within the isolation opening. A control gate is fabricated overlying the isolation opening and portions of the charge trapping layer adjacent to the isolation opening. The oxide layer and the charge trapping layer are etched using the control gate as an etch mask and impurity dopants are implanted into the substrate using the control gate as an implantation mask.

Abstract: A method of manufacturing a semiconductor device comprising a first insulating film formed on a semiconductor substrate, a charge storage layer formed on the first insulating film, a second insulating film formed on the charge storage layer, and a control electrode formed on the second insulating film, wherein forming the second insulating film comprises forming an insulating film containing silicon using source gas not containing chlorine, and forming an insulating film containing oxygen and a metal element on the insulating film containing silicon.

Abstract: A SONOS gate structure has an oxide structure on a substrate having gate pattern thereon. The oxide structure has a relatively thinner oxide portion on the substrate for keeping good program/erase efficiency, and a relatively thicker oxide portion on sidewalls of the gate pattern for inhibiting gate disturb. Trapping dielectric spacers are on formed the oxide structure laterally adjacent to said sidewalls of said gate pattern respectively.

Abstract: A charge holding insulating film in a memory cell is constituted by a laminated film composed of a bottom insulating film, a charge storage film, and a top insulating film on a semiconductor substrate. Further, by performing a plasma nitriding treatment to the bottom insulating film, a nitride region whose nitrogen concentration has a peak value and is 1 atom % or more is formed on the upper surface side in the bottom insulating film. The thickness of the nitride region is set to 0.5 nm or more and 1.5 nm or less, and the peak value of nitrogen concentration is set to 5 atom % or more and 40 atom % or less, and a position of the peak value of nitrogen concentration is set within 2 nm from the upper surface of the bottom insulating film, thereby suppressing an interaction between the bottom insulating film and the charge storage film.

Abstract: Techniques are provided for fabricating memory with metal nanodots as charge-storing elements. In an example approach, a coupling layer such as an amino functional silane group is provided on a gate oxide layer on a substrate. The substrate is dip coated in a colloidal solution having metal nanodots, causing the nanodots to attach to sites in the coupling layer. The coupling layer is then dissolved such as by rinsing or nitrogen blow drying, leaving the nanodots on the gate oxide layer. The nanodots react with the coupling layer and become negatively charged and arranged in a uniform monolayer, repelling a deposition of an additional monolayer of nanodots. In a configuration using a control gate over a high-k dielectric floating gate which includes the nanodots, the control gates may be separated by etching while the floating gate dielectric extends uninterrupted since the nanodots are electrically isolated from one another.

Abstract: A method of manufacturing a flash memory device according to an embodiment includes forming a second oxide layer pattern having a mask pattern buried therein on a first nitride layer pattern and a first oxide layer stack on a semiconductor substrate; forming first polysilicon patterns at sidewalls of the buried mask pattern; removing portions of the first oxide layer, the first nitride layer pattern, and the second oxide layer pattern to form a third oxide layer pattern, a second nitride layer pattern, and a fourth oxide layer pattern at lower portions of the first polysilicon patterns and the mask pattern; forming a fifth oxide layer pattern surrounding each of the first polysilicon patterns; forming second polysilicon patterns on sidewalls of the fifth oxide layer pattern; and removing the mask pattern and parts of the third oxide layer pattern and the second nitride layer pattern between the first polysilicon patterns.

Abstract: The invention is directed to a method for forming a memory array. The method comprises steps of providing a substrate having a charge trapping structure formed thereon. A patterned material layer is formed over the substrate and the patterned material layer having a plurality of trenches expose a portion of the charge trapping structure. Furthermore, a plurality of conductive spacers are formed on the sidewalls of the trenches of the patterned material layer respectively and a portion of the charge trapping structure at the bottom of the trenches is exposed by the conductive spacers. An insulating layer is formed over the substrate to fill up the trenches of the patterned material layer. Moreover, a planarization process is performed to remove a portion of the insulating layer until a top surface of the patterned material layer and a top surface of each of the conductive spacers are exposed.

Abstract: A flash memory device includes a semiconductor substrate having a trench formed therein, the trench including a device isolation film, an oxide film formed over the semiconductor substrate including the trench, a nitride film pattern inserted into the oxide film and formed at a sidewall of the trench, and a polysilicon pattern formed over the oxide film including the nitride film pattern.

Abstract: Methods of forming charge-trapping dielectric layer structures in semiconductor memory devices which comprise: (a) providing a semiconductor substrate; (b) forming an oxide layer on at least a portion of the substrate; (c) forming two or more source/drain regions in the substrate below the oxide layer; (d) re-oxidizing the oxide layer; (e) forming a charge-trapping dielectric layer on the oxide layer; and (f) forming an insulating layer on the charge-trapping dielectric layer; as well as methods which comprise: (a) providing a semiconductor substrate; (b) forming an oxide layer on at least a portion of the substrate in a dry atmosphere; (c) forming two or more source/drain regions in the substrate below the oxide layer; (d) forming a charge-trapping dielectric layer on the oxide layer; (e) forming an insulating layer on the charge-trapping dielectric layer; and (f) annealing the insulating layer in an atmosphere having a hydrogen content of less than about 0.01% are described.

Abstract: A non-volatile storage element 100 has a silicon substrate 102, a first memory region 106a composed of a first lower silicon oxide film 108a, a first silicon nitride film 110a, and a first upper layer silicon oxide film 112a provided in this order, a second memory region 106b composed of a second lower layer silicon oxide film 108b, a second silicon nitride film 110b, and a second upper layer silicon oxide film 112b provided in this order, and a first control gate 114 and a second control gate 116 arranged on the first memory region 106a and the second control gate 116, respectively, on the silicon substrate 102. The silicon nitride film 110 is provided so as to be horizontal in a direction within a substrate plane.

Abstract: A methods of forming a flash memory device are provided. The flash memory device comprises a silicon dioxide layer on a substrate and a silicon nitride layer that is formed on the silicon dioxide layer. The properties of the silicon nitride layer can be modified by any of: exposing the silicon nitride layer to ultraviolet radiation, exposing the silicon nitride layer to an electron beam, and by plasma treating the silicon nitride layer. A dielectric material is deposited on the silicon nitride layer and a conductive date is formed over the dielectric material. The flash memory device with modified silicon nitride layer provides an increase in charge holding capacity and charge retention time of the unit cell of a non-volatile memory device.

Abstract: Methods of fabricating a semiconductor device are provided, the methods include forming a first dielectric layer, a data storage layer, and a second dielectric layer, which are sequentially stacked, on a semiconductor substrate. A mask having a first opening exposing a first region of the second dielectric layer is formed on the second dielectric layer. A gate electrode filling at least a portion of the first opening is formed. A second opening exposing a second region of the second dielectric layer is formed by etching the mask such that the second region is spaced apart from the first region. A second dielectric pattern and a data storage pattern are formed by sequentially etching the exposed second region of the second dielectric layer and the data storage layer. The second dielectric pattern is formed to have a greater width than a lower surface of the gate electrode.

Abstract: A multiple dual bit integrated circuit system is provided that includes forming first address lines in a semiconductor substrate and forming a charge-trapping layer over the semiconductor substrate. A semiconductor layer is formed over the charge-trapping layer and second address lines are formed in the semiconductor layer to form a plurality of dual bit locations.

Abstract: A semiconductor storage element includes: a source region and a drain region provided in a semiconductor substrate; a tunnel insulating film provided on the semiconductor substrate between the source region and the drain region; a charge storage film provided on the tunnel insulating film; a block insulating film provided on the charge storage film; a gate electrode provided on the block insulating film; and a region containing a gas molecule, the region provided in a neighborhood of an interface between the charge storage film and the block insulating film.

Abstract: A nonvolatile semiconductor memory device (and method of forming same) includes a word gate provided above a channel region of a semiconductor substrate via an insulating layer, a control gate provided at a side of the word gate, and a charge storage layer provided by an ONO film between the channel region and the control gate, and between the word gate and the control gate. The control gate includes a silicide layer including silicide containing nickel, and a non-silicide layer provided between the silicide layer and the charge storage layer.

Abstract: A method of fabricating a semiconductor device and a flash memory device are provided. The method of fabricating the semiconductor device includes: forming a nitride film on a semiconductor substrate; forming a sacrificial vertical structure on the nitride film; forming sacrificial spacers on lateral surfaces of the sacrificial vertical structure; performing an initial patterning of the nitride film using the sacrificial vertical structure and the sacrificial spacers as etch masks; removing the sacrificial spacers after the initial patterning of the nitride film and forming gate electrodes on the lateral surfaces of the sacrificial vertical structure; and removing the sacrificial vertical structure from between the gate electrodes and performing a secondary patterning of the nitride film using the gate electrodes as etch masks.

Abstract: A memory cell array includes a number of memory cells, each of the memory cells including a source and a drain region defined by corresponding bitlines within a semiconductor substrate. Each of the bitlines has a doped semiconductor region as well as a conductive region in direct electrical contact with the doped semiconductor region.

Abstract: In a nonvolatile semiconductor memory device, a stacked body is provided on a silicon substrate by alternately stacking pluralities of isolation dielectric films and electrode films, a through-hole is formed in the stacked body to extend in the stacking direction, a memory film is formed by stacking a block layer, a charge layer and a tunnel layer in this order at an inner face of the through-hole, and thereby a silicon pillar is buried in the through-hole. At this time, the electrode film is protruded further than the isolation dielectric film toward the silicon pillar at the inner face of the through-hole, and an end face of the isolation dielectric film has a curved shape displacing toward the silicon pillar side as the electrode film is approached.

Abstract: Semiconductor-based non-volatile memory that includes memory cells with composite charge storage elements is fabricated using an etch stop layer during formation of at least a portion of the storage element. One composite charge storage element suitable for memory applications includes a first charge storage region having a larger gate length or dimension in a column direction than a second charge storage region. While not required, the different regions can be formed of the same or similar materials, such as polysilicon. Etching a second charge storage layer selectively with respect to a first charge storage layer can be performed using an interleaving etch-stop layer. The first charge storage layer is protected from overetching or damage during etching of the second charge storage layer. Consistency in the dimensions of the individual memory cells can be increased.

Abstract: A method for fabricating a non-volatile memory is provided. The method includes a stacked structure and a consuming layer are formed in sequence over a substrate. A converting process is performed at a peripheral region of the consuming layer to form a first insulating layer. A conductive layer is formed over the stacked layer and the first insulating layer.

Abstract: A semiconductor device which includes two trenches formed in a semiconductor substrate, a charge storage layer as an insulator formed on each side surface of the trenches, and separated on a bottom surface thereof, and a bit line formed below the bottom surface of the trenches in the semiconductor substrate. A channel region is formed in the semiconductor substrate from a side surface of one of the two trenches to that of the other trench via an upper surface of a protruding portion between those two trenches. A method for manufacturing the semiconductor device is also provided.

Abstract: A method for fabricating a nonvolatile charge trap memory device is described. The method includes first forming a tunnel dielectric layer on a substrate in a first process chamber of a single-wafer cluster tool. A charge-trapping layer is then formed on the tunnel dielectric layer in a second process chamber of the single-wafer cluster tool. A top dielectric layer is then formed on the charge-trapping layer in the second or in a third process chamber of the single-wafer cluster tool.

Abstract: A reconfigurable semiconductor device is disclosed. The semiconductor device includes a substrate, a first insulating material formed on the substrate, two channels having different polarities, a plurality of terminal electrodes formed on the insulating material and coupled in common with the channels at their opposite ends, a second insulating material formed on the terminal electrodes, and a control gate formed on the second insulating material. The channels have different polarity and a charge storage layer is formed inside the second insulating material. The control gate is applied with a forward bias or a reverse bias and then the bias is cut off. The voltage-current characteristics of the semiconductor device are changed according to an electrical charge created in the charge storage layer.

Abstract: A non-volatile memory device and a method of manufacturing the non-volatile memory device are provided. At least one first semiconductor layer and at least one second semiconductor layer are disposed. At least one control gate electrode is disposed between the at least one first semiconductor layer and the at least one second semiconductor layer. At least one first layer selection line is capacitively coupled to the at least one first semiconductor layer. At least one second layer selection line is capacitively coupled to the at least one second semiconductor layer.

Abstract: The non-volatile memory device may include a semiconductor substrate having a body and a pair of fins. A bridge insulating layer may non-electrically connect upper portions of the pair of fins to define a void between the pair of fins. Outer surfaces of the pair of fins are the surfaces of the pair of fins that do not face the void and inner surfaces of the pair of fins are the surfaces of the pair of fins that do face the void. The non-volatile memory device may further include at least one control gate electrode that may cover at least a portion of outer surfaces of the pair of fins, may extend over the bridge insulating layer, and may be isolated from the semiconductor substrate. At least one pair of gate insulating layers may be between the at least one control gate electrode and the pair of fins, and at least one pair of storage nodes may be between the at least one pair of gate insulating layers and the at least one control gate electrode.

Abstract: A semiconductor memory device includes a plurality of memory cell transistors each having a gate electrode section including a charge accumulation layer formed on a semiconductor substrate via a gate insulating film, a first insulating film formed using a material with a higher dielectric constant than the gate insulating film, a control gate, an impurity diffusion layer functioning as a source or a drain, and a plurality of barrier films formed on a side surface of the gate electrode section so as to cover a side surface of at least the first insulating film and formed between the first insulating film and the control gate. The device further includes a plurality of second insulating films formed on the semiconductor substrate and each formed between the gate electrode sections of adjacent ones of the plurality of memory cell transistors.

Abstract: A dielectric layer containing a hafnium tantalum oxide film and a method of fabricating such a dielectric layer produce a dielectric layer for use in a variety of electronic devices. Embodiments include structures for capacitors, transistors, memory devices, and electronic systems with dielectric layers containing a hafnium tantalum oxide film structured as one or more monolayers.

Abstract: To improve characteristics of a semiconductor device having a nonvolatile memory. There is provided a semiconductor device having a nonvolatile memory cell that performs memory operations by transferring a charge to/from a charge storage film, wherein the nonvolatile memory cell includes a p well formed in a principal plane of a silicon substrate, and a memory gate electrode formed over the principal plane across the charge storage film, and wherein a memory channel region located beneath the charge storage film of the principal plane of the silicon substrate contains fluorine.

Abstract: There is provided a charge trap type non-volatile memory device and a method for fabricating the same, the charge trap type non-volatile memory device including: a tunnel insulation layer formed over a substrate; a charge trap layer formed over the tunnel insulation layer, the charge trap layer including a charge trap polysilicon thin layer and a charge trap nitride-based layer; a charge barrier layer formed over the charge trap layer; a gate electrode formed over the charge barrier layer; and an oxide-based spacer formed over sidewalls of the charge trap layer and provided to isolate the charge trap layer.