Abstract: The present invention discloses capacitors having via connections and electrodes designed such that they provide a low inductance path, thus reducing needed capacitance, while enabling the use of embedded capacitors for power delivery and other uses. One embodiment of the present invention discloses a capacitor comprising the following: a top capacitor electrode and a bottom capacitor electrode, wherein the top electrode is smaller than the bottom electrode, comprising, on all sides of the capacitor; in an array, a multiplicity of vias located on all sides of the top and bottom capacitor electrodes, wherein the top electrode and the vias connecting to the top electrode act as an inner conductor, and the bottom electrode and the vias connecting to the bottom electrode act as an outer conductor.

Abstract: Thin-film phase-change memories having small phase-change switching volume formed by overlapping thing films. Exemplary embodiments include a phase-change memory element, including a first phase change layer having a resistance, a second phase change layer having a resistance, an insulating layer disposed between the first and second phase change layers; and a third phase change layer having a resistance, and coupled to each of the first and second phase change layers, bridging the insulating layer and electrically coupling the first and second phase change layers, wherein the resistance of the third phase change layer is greater than both the resistance of the first phase change layer and the second phase change layer.

Abstract: A capacitor includes a pair of electrodes and a ferroelectric film sandwiched between the electrodes. The electrodes are provided perpendicular to the direction of the polarization axis of the ferroelectric film.

Abstract: A fabricated layered capacitor having three layers is provided. The first bottom layer comprises a first bottom plate portion, the second middle layer comprises a first top plate portion, and the third top layer comprises a second bottom plate portion of the layered capacitor. A set of vias connects the first and second bottom plate portions. The top plate portion may extend past the bottom plate portions. The layered capacitor may have a different number of layers (e.g., five layers). The layers may comprise metal layers produced using semiconductor fabrication methods. Also provided is a capacitor array having two or more layered capacitors where connectors connect all top plate portions of the capacitors. The capacitor array may be used in a capacitive DAC, the capacitors being connected according to the architecture of the DAC. The capacitive DAC may be used in a SAR ADC.

Abstract: Bottom electrodes of memory cell capacitors are recessed to prevent electrical shorts between neighboring memory cells. A partially fabricated memory cell capacitor has a bottom electrode comprising titanium nitride (TiN) and hemispherical grained (HSG) silicon. The container housing the capacitor is filled with photoresist and then planarized. The TiN layer is then selectively recessed with a peroxide mixture and subsequently the HSG silicon layer is recessed using tetramethyl ammoniumhydroxide. Thus, the bottom electrode is recessed below the level of particles which may overlie the memory cell capacitors and cause shorts by contacting the bottom electrode.

Abstract: An array of memory cells with non-volatile memory transistors having a compact arrangement of diagonally symmetric floating gates. The floating gates have portions extending in both X and Y directions, allowing them to be charged through a common tunnel oxide stripe that runs under a portion of each, for example a portion running in the X-direction while the two Y-direction portions serve to establish a channel. Shared source/drain regions are established between and in proximity to the Y-direction portions to define two non-volatile memory transistors in each memory cell. Memory cells are replicated in the word line direction and then mirrored with respect to the word line to form the next row or column. This geometry is contactless because the word line and source/drain regions are all linear throughout the array so that electrical contact can be established outside of the array of cells. Each transistor can be addressed and thus programmed and erased or pairs of transistors in a line can be erased, i.e.

Abstract: The present invention provides a manufacturing method of an image TFT array, which includes providing a substrate including a thin film transistor region, a storage capacitor region, a pad region, and a common electrode region, forming a photoresist layer on the substrate, and performing a photolithographic and etching process by utilizing a half-tone mask to pattern the photoresist layer to define a position of a through hole on the storage capacitor region and form the photoresist layer of a first thickness on the thin film transistor region and the photoresist layer of a second thickness on the region between the thin film transistor region and the storage capacitor region, wherein the first thickness is greater than the second thickness.

Abstract: A signal processing device is provided which is capable of suppressing a voltage change of a power supply when output signals from a plurality of signal sources are read, and capable of outputting a stable signal at a high sensitivity, and an image pickup apparatus using such a signal processing device is also provided. The signal processing device has: a plurality of terminals connectable to a plurality of signal sources; and a read circuit for converting signals input from the terminals into serial signals and outputting the serial signals, wherein: the read circuit comprises a holding capacitor connected to each of the terminals, a transfer switch for transferring a signal held in the holding capacitor to a common signal line, and a shift register for driving the transfer switch; and a semiconductor layer under the common signal line has a conductivity type opposite to a first conductivity type of a semiconductor substrate.

Abstract: Provided is a semiconductor device having, over the main surface of a semiconductor substrate, a main circuit region and a memory cell array of a flash memory. The memory cell array has a floating gate electrode for accumulating charges of data, while the main circuit region has a gate electrode of MIS•FET constituting the main circuit. In the main circuit region, an insulating film made of a silicon nitride film is formed to cover the gate electrode, whereby miniaturization of elements in the main circuit region is not impaired. The memory cell array has no such insulating film. This means that the upper surface of the floating gate electrode is not contiguous to the insulating film but is covered directly with an interlayer insulating film. According to such a constitution, leakage of electrons from the floating gate electrode of the memory cell array can be suppressed or prevented and the flash memory thus obtained has improved data retention characteristics.

Abstract: To provide a semiconductor device having a memory element, and which is manufactured by a simplified manufacturing process. A method of manufacturing a semiconductor device includes, forming a first insulating film to cover a first semiconductor film and a second semiconductor film; forming a first conductive film and a second conductive film over the first semiconductor film and the second semiconductor film, respectively, with the first insulating film interposed therebetween; forming a second insulating film to cover the first conductive film; forming a third conductive film selectively over the first conductive film which is formed over the first semiconductor film, with the second insulating film interposed therebetween, and doping the first semiconductor film with an impurity element with the third conductive film serving as a mask and doping the second semiconductor film with the impurity element through the second conductive film.

Abstract: Provided are semiconductor integrated circuit (IC) devices including gate patterns having a step difference therebetween and a connection line interposed between the gate patterns. The semiconductor IC device includes a semiconductor substrate including a peripheral active region, a cell active region, and a device isolation layer. Cell gate patterns are disposed on the cell active region and the device isolation layer. A peripheral gate pattern is disposed on the peripheral active region. A cell electrical node is disposed on the cell active region adjacent to the cell gate patterns. Peripheral electrical nodes are disposed on the peripheral active region adjacent to the peripheral gate pattern. Connection lines are disposed on the cell gate patterns disposed on the device isolation layer. The connection lines are connected between the cell gate patterns and the peripheral gate pattern.

Abstract: The semiconductor device comprises a semiconductor substrate 10 with a trench 16a and a trench 16b formed in; a device isolation film 32a buried in the trench 16a and including a liner film including a silicon nitride film 20 and an insulating film 28 of a silicon oxide-based insulating material; a device isolation film 32b buried in the bottom of the trench 16b; and a capacitor formed on a side wall of an upper part of the second trench 16b and including an impurity diffused region 40 as a first electrode, a capacitor dielectric film 43 of a silicon oxide-based insulating film and a second electrode 46.

Abstract: The invention relates to a DRAM memory device with a capacity associated with a field effect transistor, in which all or some of the molecules capable of storing the loads comprising a polyoxometallate are incorporated into the capacity, or a flash-type memory using at least one field effect transistor, in which the molecules capable of storing the loads comprising a polyoxometallate are incorporated into the floating grid of the transistor.

Abstract: In order to improve the soft error resistance of a memory cell of an SRAM without increasing its chip size in deep through-holes formed by perforating a silicon oxide film, there is a silicon nitride film and a silicon oxide film, a capacitor element having a TIN film serving as a lower electrode. This capacitor element is connected between a storage node and a supply voltage line, between a storage node and a reference voltage line, or between storage nodes of the memory cell of the SRAM.

Abstract: A NAND includes a device isolation pattern disposed in a region of a substrate defining a plurality of active regions. Memory transistors having memory gate patterns, constituting a cell string, cross the plurality of active regions. Select transistors are disposed over the memory transistors, and lower plugs are disposed on each side of the cell string to electrically connect the plurality of active regions on both sides of the cell string and the select transistors.

Abstract: A write and erase method of a semiconductor memory device includes a floating gate type transistor having a semiconductor substrate, a gate insulating film formed on the semiconductor substrate, a floating gate electrode formed on the gate insulating film, and a control gate electrode opposing the floating gate electrode with a hollow portion being sandwiched therebetween. A capacitance between the semiconductor substrate and the control gate electrode is controlled by one of an operation of forming, in the hollow portion, an electrical path which electrically connects the floating gate electrode and the control gate electrode, and an operation of eliminating the electrical path.

Abstract: Phase-changeable memory devices and method of fabricating phase-changeable memory devices are provided that include a phase-changeable material pattern of a phase-changeable material that may include nitrogen atoms and/or silicon atoms. First and second electrodes are electrically connected to the phase-changeable material pattern and provide an electrical signal thereto. The phase-changeable material pattern may have a polycrystalline structure.

Abstract: A method for manufacturing a semiconductor device includes forming a second storage node contact hole with a mask for storage node and securing an overlay margin between a storage node contact hole and a storage node with a hard mask layer that serves as a hard mask as well as an anti-reflection film to reduce contact resistance, prevent reduction of a line-width of a lower interlayer insulating film and eliminate processes for depositing the interlayer insulating film and a polysilicon layer and etching the polysilicon layer to reduce a production period and cost of products.

Abstract: A non-volatile semiconductor memory comprising at least one EPROM/EEPROM memory cell that includes a floating gate transistor and a coupling capacitor, said floating gate transistor comprising a field effect transistor and a polysilicon layer, the coupling capacitor comprising a first electrode and a second electrode as well as a dielectric interposed between said electrodes, the first electrode of the coupling capacitor being electrically coupled with the polysilicon layer of the floating gate transistor, and the control electrode of the floating gate transistor forming the second electrode of the coupling capacitor. The invention also relates to a display device and an arrangement for controlling a display device, which each comprise a non-volatile semiconductor memory.

Abstract: A non-volatile memory device includes a pair of source/drain regions disposed in a semiconductor substrate, having a channel region between them. A charge storage oxide layer is disposed on the channel region and overlaps part of each of the pair of source/drain regions. A gate electrode is disposed on the charge storage oxide layer. At least one halo implantation region is formed in the semiconductor substrate adjacent to one of the pair of source/drain regions, and overlapping the charge storage oxide layer. A program operation is performed by trapping electrons in the charge storage oxide layer located near the source/drain region where the halo ion implantation region is formed, and an erase operation is performed by injecting holes into the charge storage oxide layer located near the source/drain region where the halo ion implantation region is formed.

Abstract: A self-aligned buried contact (BC) pair includes a substrate having diffusion regions; an oxide layer exposing a pair of diffusion regions formed on the substrate; bit lines formed between adjacent diffusion regions and on the oxide layer, each of the bit lines having bit line sidewall spacers formed on sidewalls thereof; a first interlayer dielectric (ILD) layer formed over the bit lines and the oxide layer; a pair of BC pads formed between adjacent bit lines and within the first ILD layer, each BC pad being aligned with one of the pair of exposed diffusion regions in the substrate; and a pair of capacitors, each of the pair of BC pads having one of the pair of capacitors formed thereon, wherein a pair of the bit line sidewall spacers is adjacent to each of the BC pads and the pair of bit line sidewall spacers has an asymmetrical shape.

Abstract: A single-poly electrically erasable/programmable CMOS logic memory cell for mobile applications includes a CMOS inverter that share a single polysilicon floating gate, and an enhanced control capacitor including a control gate capacitor and an optional isolated P-well (IPW) capacitor formed below the control gate capacitor. The control gate capacitor includes a polysilicon control gate that is interdigitated with the floating gate and serves as a capacitor plate to induce Fowler-Nordheim (F-N) injection or Band-to-Band Tunneling (BBT) to both program and erase the floating gate. The IPW capacitor is provided in the otherwise unused space below the control gate capacitor by a IPW that is separated from the control/floating gates by a dielectric layer and is electrically connected to the control gate. Both F-N injection and BBT program/erase are performed at 5V or less.

Abstract: An integrated circuit structure includes a digit line and an electrode adapted to be part of a storage cell capacitor and includes a barrier layer interposed between a conductive plug and an oxidation resistant layer. An insulative layer protects sidewalls of the barrier layer during deposition and anneal of a dielectric layer. The method includes forming the conductive plug recessed in an insulative layer. The barrier layer is formed in the recess and the top layer. An oxidation resistant conductive layer and a further oxide layer are formed in the recess. The conductive layer is planarized to expose the oxide or oxide/nitride layer. The oxide layers are then etched to expose the top surface and vertical portions of the conductive layer. A dielectric layer is formed to overlie the storage node electrode. A cell plate electrode is fabricated to overlie the dielectric layer.

Abstract: A nonvolatile memory cell that can be mounted in a CMOS manufacturing process, and is capable of implementing high level of programming, reading and erasing ability. The memory cell is configured by a MOS transistor comprising two N-type first impurity diffusion layers formed separately on a P-type semiconductor substrate, and a first gate electrode formed above a first cannel region sandwiched by both diffusion layers through a first gate insulation film, a first capacitor comprising P-type second impurity diffusion layers formed on a well, and a second gate electrode formed above the diffusion layer through a second gate insulation film, and a second capacitor comprising the well adjacent to the second impurity diffusion layer, and a third gate electrode formed above the well through a third gate insulation film, wherein a different voltage can be applied to each of the capacitors.

Abstract: A semiconductor device with a capacitor includes a lower electrode, a dielectric and an upper electrode on the dielectric layer. The dielectric layer including more than one polycrystalline tantalum oxide layer and more than one separation layer, wherein the polycrystalline tantalum oxide layers and the separation layers are alternately stacked, while one of the polycrystalline tantalum oxide layers is a lowermost layer among the stacked layers.

Abstract: A capacitor including a polysilicon layer doped with impurities to be conductive, a first dielectric layer formed on the polysilicon layer, a first conductive layer formed on the first dielectric layer, a second dielectric layer formed on the first conductive layer, and a second conductive layer formed on the first dielectric layer. The second conductive layer is coupled to the polysilicon layer.

Abstract: A semiconductor display device with an interlayer insulating film in which surface levelness is ensured with a limited film formation time, heat treatment for removing moisture does not take long, and moisture in the interlayer insulating film is prevented from escaping into a film or electrode adjacent to the interlayer insulating film. A TFT is formed and then a nitrogen-containing inorganic insulating film that transmits less moisture compared to organic resin film is formed so as to cover the TFT. Next, organic resin including photosensitive acrylic resin is applied and an opening is formed by partially exposing the organic resin film to light. The organic resin film where the opening is formed, is then covered with a nitrogen-containing inorganic insulating film which transmits less moisture than organic resin film does.

Abstract: Fabrication of recessed channel array transistors (RCAT) with a corner gate device includes forming pockets between a semiconductor fin that includes a gate groove and neighboring shallow trench isolations that extend along longs sides of the semiconductor fin. A protection liner covers the semiconductor fin and the trench isolations in a bottom portion of the gate groove and the pockets. An insulator collar is formed in the exposed upper sections of the gate groove and the pockets, wherein a lower edge of the insulator collar corresponds to a lower edge of source/drain regions formed within the semiconductor fin. The protection liner is removed. The bottom portion of the gate groove and the pockets are covered with a gate dielectric and a buried gate conductor layer. The protection liner avoids residuals of polycrystalline silicon between the active area in the semiconductor fin and the insulator collar.

Abstract: A semiconductor device in which a DRAM and a SRAM are mixedly mounted is provided. The DRAM and the SRAM have a stack-type structure in which a bitline is formed below a capacitive element. A cross couple connection of the SRAM is formed in a layer or below the layer in which a capacitive lower electrode of the DRAM is formed and in a layer or above the layer in which the bitline is formed. For example, the cross couple connection of the SRAM is formed in a same layer as a capacitive contact.

Abstract: A via etch to contact a capacitor with ferroelectric between electrodes together with dielectric on an insulating diffusion barrier includes two-step etch with F-based dielectric etch and Cl- and F-based barrier etch.

Abstract: Phase change memories may exhibit improved properties and lower cost in some cases by forming the phase change material layers in a planar configuration. A heater may be provided below the phase change material layers to appropriately heat the material to induce the phase changes. The heater may be coupled to an appropriate conductor.

Abstract: The present invention provides a device having a useful structure which is arranged on a substrate and has a useful structure side edge. In addition, an auxiliary structure is arranged on the substrate adjacent to the useful structure, the auxiliary structure having an auxiliary structure side edge, wherein the useful structure side edge is opposite to the auxiliary structure side edge separated by a distance, and wherein the auxiliary structure useful structure distance is dimensioned such that a form of the useful structure side edge or a form of the substrate next to the useful structure side edge differs from a form in a device where there is no auxiliary structure.

Abstract: A method of fabricating a semiconductor device is disclosed. First, a substrate is provided. The substrate includes at least a transistor area having a gate structure thereon, a capacitor area having a first electrode thereon and a resistor area having a second electrode thereon. The capacitor area and the resistor area both have an isolation structure therein. Then, first spacers and source/drain regions on both sides of the gate are sequentially formed. After that, a dielectric layer and a first conductive material layer are sequentially formed on the substrate. Next, the first conductive material layer is patterned to form a third electrode in the capacitor area and a conductive layer in the resistor area. Then, second spacers are formed. Afterwards, the exposed dielectric layer is removed. Finally, a self-aligned silicide process is performed to form a metal salicide layer to cover the surface of the device.

Abstract: Some embodiments provide a semiconductor substrate having a cell array region and a peripheral circuit region. A plurality of word line patterns are placed in the cell array region, each of which include a word line and a word line capping layer pattern stacked thereon. At least one gate pattern including a gate electrode and a gate capping layer pattern is formed in the peripheral circuit region, the gate capping layer pattern and the word line capping layer pattern having different etching selectivity ratios. A pad interlayer insulating layer and a bit line interlayer insulating layer having approximately the same etching selectivity ratio as the gate capping layer pattern are sequentially formed over a surface of the semiconductor substrate having the gate spacers.

Abstract: The present invention discloses a low-noise single-gate non-volatile memory and an operation method thereof, wherein a transistor and a capacitor structure are embedded in a semiconductor substrate; the electrically-conductive gate of the transistor and the electrically-conductive gate of the capacitor structure are interconnected to form a single floating gate of a memory cell; an ion-doped buried layer is formed between the dielectric layer of the capacitor structure and the semiconductor substrate to reduce the external interference on the capacitor structure and control the initial threshold voltage; a reverse bias may be used to implement the reading, writing, and erasing operations of the single-floating-gate memory cell; in the operation of the low-noise single-gate non-volatile memory having an isolation well, positive and negative voltages may be applied to the drain, the gate, and the silicon substrate/the isolation well to create an inversion layer, and thereby, the absolute voltage, the area of th

Abstract: A semiconductor device includes a first hydrogen barrier film, a capacitor device formed on the first hydrogen barrier film, and a second hydrogen barrier film formed to cover the capacitor device. The first and second hydrogen barrier films each contain at least one common type of atoms for allowing the first and second hydrogen barrier films to adhere to each other.

Abstract: A non-volatile memory cell and a method of manufacturing the same are provided. The non-volatile memory cell includes a semiconductor substrate, a floating gate over the semiconductor substrate, a first, a second, and a third capacitor each having a first plate and sharing a common floating gate as a second plate. The non-volatile memory cell further includes a transistor connected in series with the first capacitor. The gate electrode of the transistor is connected to a wordline of a memory array, and a source/drain region is connected to a bitline.

Abstract: Provided are a nonvolatile semiconductor memory device and a method of manufacturing the same. The nonvolatile semiconductor memory device may include a tunnel insulating layer formed on a semiconductor substrate, a charge trap layer including a dielectric layer doped with a transition metal formed on the tunnel insulating layer, a blocking insulating layer formed on the charge trap layer, and a gate electrode formed on the blocking insulating layer. The dielectric layer may be a high-k dielectric layer, for example, a HfO2 layer. Thus, the data retention characteristics of the nonvolatile semiconductor memory device may be improved because a deeper charge trap may be formed by doping the high-k dielectric layer with a transition metal.

Abstract: In a complete CMOS SRAM having a memory cell composed of six MISFETs formed over a substrate, a capacitor element having a stack structure is formed of a lower electrode covering the memory cell, an upper electrode, and a capacitor insulating film (dielectric film) interposed between the lower electrode and the upper electrode. One electrode (the lower electrode) of the capacitor element is connected to one storage node of a flip-flop circuit, and the other electrode (the upper electrode) is connected to the other storage node. As a result, the storage node capacitance of the memory cell of the SRAM is increased to improve the soft error resistance.

Abstract: A nonvolatile memory and a fabrication method thereof. The nonvolatile memory includes a substrate, a bottom electrode deposited on the substrate, a resistor layer deposited on the bottom electrode, and a top electrode on the resistor layer. The bottom electrode includes LaNiO3 and the resistor layer includes doped SrZrO3.

Abstract: A phase change memory device includes a lower electrode and a porous dielectric layer having fine pores on the lower electrode. A phase change layer is provided in the fine pores of the porous dielectric layer. An upper electrode is provided on the phase change layer. Related manufacturing methods are also described.

Abstract: The invention includes methods in which metal oxide dielectric materials are deposited over barrier layers. The barrier layers can comprise compositions of metal and one or more of carbon, boron and nitrogen, and the metal oxide of the dielectric material can comprise the same metal as the barrier layer. The dielectric material/barrier layer constructions can be incorporated into capacitors. The capacitors can be used in, for example, DRAM cells, which in turn can be used in electronic systems.

Abstract: A semiconductor device having resistors in a peripheral area and fabrication method thereof are provided. A mold layer is formed on a semiconductor substrate. The mold layer is patterned to form first molding holes and a second molding hole in the mold layer. A storage node layer is formed on the mold layer as well as in the first and second molding holes. The storage node layer is patterned to form storage nodes in the first molding holes and a portion of a resistor in the second hole.

Abstract: A configuration memory cell (“CRAM”) for a field programmable gate array (“FPGA”) integrated circuit (“IC”) device is given increased resistance to single event upset (“SEU”). A portion of the gate structure of the input node of the CRAM is increased in size relative to the nominal size of the remainder of the gate structure. Part of the enlarged gate structure is located capacitively adjacent to an N-well region of the IC, and another part is located capacitively adjacent to a P-well region of the IC. This arrangement gives the input node increased capacitance to resist SEU, regardless of the logical level of the input node. The invention is also applicable to any node of any type of memory cell for which increased resistance to SEU is desired.

Abstract: A semiconductor assembly providing even nucleation between silicon and oxide surfaces for growing uniformly thin silicon nitride layers used in semiconductor devices is disclosed. First, a nonconductive nitride-nucleation enhancing monolayer is formed over a semiconductor assembly having both nitridation receptive and resistive materials. For purposes of the present invention, a nitride-nucleation enhancing monolayer is a material that will readily accept the bonding of nitrogen atoms to the material itself. Next, a silicon nitride layer is formed over the nonconductive nitride-nucleation enhancing monolayer. The nonconductive nitride-nucleation enhancing monolayer provides even nucleation over both the nitridation receptive material and the nitridation resistive material for silicon nitride, thereby allowing for the growth of a uniformly thin nitride layer.

Abstract: A field effect transistor includes a trench gate extending into a semiconductor region. The trench gate has a front wall facing a drain region and a side wall perpendicular to the front wall. A channel region extends along the side wall of the trench gate, and a drift region extends at least between the drain region and the trench gate. The drift region includes a stack of alternating conductivity type silicon layers.

Abstract: A chip or wafer comprises a semiconductor substrate, first and second transistors on the semiconductor substrate, first and second metal layers over the semiconductor substrate, an insulating layer on the first and second metal layers, a third and fourth metal layers on the insulating layer, a passivation layer over the third and fourth metal layers, and a fifth metal layer over the passivation layer. A signal is suited to be transmitted from the first transistor to the second transistor sequentially through the first, third, fifth, fourth and second metal layers.

Abstract: A ferroelectric material includes a compound of formula (I): (Pb1?x?zBazAx)(ByZr1?y)O3, ??(I) wherein 0?x?0.1, 0?y?0.020, 0.15?z?0.35, with the proviso that y?0 when x=0, and that x?0, when y=0; and wherein A is a first element having a valence number greater than that of Pb, and B is a second element having a valence number greater than that of Zr. A ferroelectric memory device made from the ferroelectric material is also disclosed.

Abstract: Container structures for use in integrated circuits and methods of their manufacture. The container structures have a dielectric cap on the top of a conductive container to reduce the risk of container-to-container shorting by insulating against bridging of conductive debris across the tops of adjacent container structures. The container structures are adapted for use in memory cells and apparatus incorporating such memory cells, as well as other integrated circuits.

Abstract: A method of making embedded non-volatile memory devices includes forming a first mask layer overlying a polycrystalline silicon layer in a cell region and a peripheral region on a semiconductor substrate wherein the first mask layer has a plurality of openings in the cell region. Portions of the polycrystalline silicon layer exposed in the plurality of openings can be oxidized to form a plurality of poly-oxide regions, and the first mask layer can then be removed. The polycrystalline silicon layer not covered by the plurality of poly-oxide regions can be etched to form a plurality of floating gates, wherein etching the polycrystalline silicon layer is accompanied by a sputtering. A dielectric layer can then be formed, as well as a second mask layer in both the cell region and the peripheral region. The second mask layer in the cell region is partially etched back after a photoresist layer is formed over the second mask layer in the peripheral region.