Abstract: A nonvolatile semiconductor memory includes a transistor, one or two resistance-change portions, and one or two charge accumulation portions. The transistor has a control electrode, first main electrode region, and second main electrode region. Each resistance-change portion is of a second conductivity type having impurity concentration lower than that of the first and second main electrode regions. The charge-accumulation portions are provided on the associated resistance-change portions. Each charge accumulation portion has an insulating layer, and is capable of accumulating charge.

Abstract: The method of manufacturing a semiconductor device comprises the steps of: forming a gate electrode on a semiconductor substrate through a gate insulated film; forming source/drain regions to be adjacent to the gate electrode forming an Al wiring through an interlayer insulating film covering the gate electrode; and implanting impurity ions into a surface of the semiconductor substrate using as a mask the Al wiring and a photoresist formed thereon, thereby writing information into each of elements constituting a mask ROM and changing an outputting manner at an output port.

Abstract: A method of code programming a mask read only memory (ROM) is disclosed. A method of the present invention includes forming a layer of developable anti-reflective coating over a plurality of code openings located on a substrate of a ROM device. The plurality of code openings are typically elements of a first code, or pre-code, pattern, and a portion of the developable anti-reflective coating layer is removed or processed to define a second code, or real-code, pattern of the device. The method may be practiced by applying and patterning a layer of photoresist material over the developable anti-reflective coating to form a second code pattern, and then removing portions of the developable anti-reflective coating that remain exposed beneath the patterned photoresist material.

Abstract: A semiconductor structure 300 comprises a plurality of first track conductors 303, a plurality of second track conductors 304, which are insulated with respect to the first track conductors 303 and form a grid together with these first track conductors 303, and a plurality of third track conductors 307 parallel above the first track conductors 303, which third track conductors 307 partly cover the second track conductors 304 and are insulated with respect thereto, in which semiconductor structure 300, between in each case two adjacent second track conductors 304, there is located an electrical contact 305 between each first track conductor 303 and the corresponding third track conductor 307 which lies above it.

Abstract: The present invention relates to a multi-level read only memory cell that can store two bits and the fabrication method thereof. The multi-level ROM cell has the storage capacity of two bits and the resultant NAND type ROM memory array can provide four logic states of two bits, thus increasing the data storage capacity.

Abstract: A data writing method for mask read only memory using different doses of ion implantations to perform the data writing of Mask Read Only Memory. A semiconductor substrate having a plurality of gate structures is provided. The different ion implantations are performed depending on the mask from the user, thereby generating the different voltage output values. The different voltage output values are set as (00), (01), (10), and (11) for the bit output. Therefore, the present invention reduces the area of memory required for a specific data record, and lowers the production cost.

Abstract: The invention includes methods of fabricating multiple sets of field effect transistors. In one implementation, an etch stop layer is formed over an insulative capping layer which is formed over a conductive gate layer formed over a substrate. The etch stop layer, the insulative capping layer, and the conductive gate layer are patterned and etched to form a first set of conductive gate constructions over the substrate. A dielectric material is formed and planarized over the first set of gate constructions. Thereafter, the insulative capping layer and the conductive gate layer are patterned and etched to form a second set of conductive gate constructions over the substrate. Other aspects and implementations are contemplated.

Abstract: A Mask ROM and a method for fabricating the same are described. The Mask ROM comprises a substrate, a plurality of gates on the substrate, a gate oxide layer between the gates and the substrate, a plurality of buried bit lines in the substrate between the gates, an insulator on the buried bit lines and between the gates, a plurality of word lines each disposed over a row of gates perpendicular to the buried bit lines, and a coding layer between the word lines and the gates.

Abstract: Memory cells are formed by preferably cylindrical recesses at the main surface of a semiconductor substrate, containing a memory layer sequence at sidewalls and a gate electrode and being provided with upper and lower source/drain regions connected in columns to first and second bit lines. Word lines are arranged above the first and second bit lines and connected to rows of gate electrodes. The vertical transistor structure facilitates a further shrinking of the cells and enables a required minimum effective channel length.

Abstract: A memory system having a plurality of T-RAM cells arranged in an array is presented where each T-RAM cell has dual vertical devices and is fabricated over a SiC substrate. Each T-RAM cell has a vertical thyristor and a vertical transfer gate. The top surface of each thyristor is coplanar with the top surface of each transfer gate within the T-RAM array to provide a planar cell structure for the T-RAM array. A method is also presented for fabricating the T-RAM array having the vertical thyristors, the vertical transfer gates and the planar cell structure over the SiC substrate.

Abstract: A mask read only memory (ROM) and a method of fabricating the same is provided. This mask ROM and related method is capable of reducing the pitch of buried impurity diffusion regions. In the mask ROM fabrication process, a gate insulation layer is formed over a semiconductor substrate, and parallel conductive layer patterns are formed on the gate insulation layer. These conductive layer patterns are separated from each other by a first predetermined interval and extend in the same direction. Ion implantation is then carried out using the conductive layer patterns as a mask to form buried impurity diffusion regions near the semiconductor substrate between the conductive layer patterns. A conductive layer for use in forming word lines is then formed over the entire surface of the resultant structure, and both the conductive layer and the conductive layer patterns are etched so as to form word lines and pad conductive layers.

Abstract: A method for providing bitline contacts in a memory cell array includes a plurality of bitlines disposed in a first direction, the bitlines being covered by an isolating layer, a plurality of wordlines disposed in a second direction perpendicular to the first direction above the bitlines, and memory cells disposed at the points at which the bitlines and wordlines cross each other. According to a first aspect of the present invention, the isolating layer is removed from the bitlines at the portions that are not covered by the wordlines, whereas the areas between the bitlines remain unaffected. Alternatively, the isolating layer is removed from the whole cell array. Then, an electrical conductive material is provided on the exposed portions of the bitlines. The method is used to provide bitline contacts in a nitride read only memory (NROM™) chip.

Abstract: A fabrication method for a read only memory provides a substrate having a memory cell region and a periphery circuit region. A memory cell region has a memory cell array and the periphery circuit region has transistors. A precise layer having a plurality of first openings is formed in the memory cell region. The first openings are above the channel region of each memory cell in the memory cell array and the critical dimension of the first openings is identical. A mask layer having second openings and third openings is formed on the substrate. The second openings locate over a pre-coding memory cell region, and the third openings locate over the transistor gates. An ion implantation is performed to code the memory cell in the pre-coding memory cell region and to adjust the threshold voltage of the transistor, using the precise layer and the mask layer as a mask.

Abstract: Static pass transistor logic having transistors with multiple vertical gates are described. Multiple vertical gates are edge defined with only a single transistor being required for multiple logic inputs. Thus a minimal surface area is required for each logic input. The static pass transistor includes a transistor which has a horizontal depletion mode channel region between a single source and drain region. A number of vertical gates are located above different portions of the depletion mode channel region. A vertical gate is located above a first portion of the depletion mode channel region and is separated therefrom by a first insulator material. A vertical gate is located above a second portion of the channel region and is separated therefrom by a second insulator material. There is no source nor drain region associated with each input and the gates have sub-lithographic horizontal dimensions by virtue of being edge defined vertical gates.

Abstract: The present invention discloses a mask ROM which has excellent compatibility with a logic process and improves integration of a memory cell, and a fabrication method thereof. The mask ROM includes: a substrate where a memory cell array region and a segment select region are defined; first and second trenches respectively formed at the outer portion of the memory cell array region and at the outer portion of a buried layer formation region of the segment select region; an element isolating film and an isolating pattern respectively filling up the first and second trenches; a plurality of buried layers aligned on the substrate in a first direction by a predetermined interval, and surrounded by the isolating pattern; and a plurality of gates aligned in a second direction to cross the buried layers in an orthogonal direction.

Abstract: According to embodiments of the invention, a first gate insulating pattern and a mask pattern are sequentially stacked on a semiconductor substrate. Subsequently an impurity region is formed in the semiconductor substrate. Next, the mask pattern is removed to expose the first gate insulating pattern and a second gate insulating layer is formed on the entire surface thereof. The mask pattern is preferably formed of an anti-reflecting pattern and a photoresist pattern that are sequentially stacked. The anti-reflecting pattern is preferably formed of a material layer without etching selectivity with respect to the photoresist pattern. For this, the anti-reflecting pattern is preferably formed of organic materials including hydrocarbonic compounds. In addition, removing a mask pattern is performed with an etch recipe having an etch selectivity with respect to the first gate insulating pattern.

Abstract: A method for manufacturing a mask ROM of flat cell structure.

Abstract: A process for forming a power MOSFET enables the connection a metal gate electrode to the conductive polysilicon gates in the active area without an additional mask step. In the process, a groove is formed in the field oxide during the active area mask step. Conductive polysilicon is then formed over the active area and into the groove. At least one window is formed over the groove along with the mask window for forming the channel and source implant windows, and the polysilicon is etched to the silicon surface in the active area, but a strip is left in the groove. This strip is contacted by gate metal during metal deposition. Thus, gate metal is connected to the polysilicon without an added mask step.

Abstract: A buried insulating film is formed in an LDD region between a source region and a drain region, and a non-doped silicon film is formed in the SOI layer above the buried insulating film. The SOI layer lying under the buried insulating film has a body concentration of 1018 cm?3.

Abstract: A method of code programming a mask read only memory (ROM) is disclosed. According to the method, a first photoresist layer is formed over word lines and a gate oxide layer of a substrate already having implanted bit lines. The first photoresist layer is patterned to develop pre-code openings over all of the memory cells, which correspond to intersecting word and bit lines. The first photoresist layer is then hardened using either a treatment implant or a treatment plasma. Subsequently, a second photoresist layer is formed over the first photoresist layer and patterned to develop real-code openings over memory cells which are actually to be coded with a logic “0” value. Each memory cell to be coded is then implanted with implants passing through the pre-code openings and the real code openings and into the memory cell.

Abstract: A multi-bit Read Only Memory (ROM) cell has a semiconductor substrate of a first conductivity type with a first concentration. A first and second regions of a second conductivity type spaced apart from one another are in the substrate. A channel is between the first and second regions. The channel has three portions, a first portion, a second portion and a third portion. A gate is spaced apart and is insulated from at least the second portion of the channel. The ROM cell has one of a plurality of N possible states, where N is greater than 2. The possible states of the ROM cell are determined by the existence or absence of extensions or halos that are formed in the first portion of the channel and adjacent to the first region and/or in the third portion of the channel adjacent to the second region. These extensions and halos are formed at the same time that extensions or halos are formed in MOS transistors in other parts of the integrated circuit device, thereby reducing cost.

Abstract: A method to form transistors having improved ESD performance in the manufacture of an integrated circuit device is achieved. The method includes providing a SOI substrate with a doped silicon layer and a buried oxide layer. The doped silicon layer has a first conductivity type and overlies the buried oxide layer. Ions are implanted into the SOI substrate to form higher concentration regions in the doped silicon layer. The higher concentration regions have the first conductivity type and are formed substantially below the top surface of the doped silicon layer. MOS gates are formed. These MOS gates include an electrode layer overlying the doped silicon layer with a gate oxide layer therebetween. Source and drain regions are formed in the doped silicon layer to complete the transistors in the manufacture of the integrated circuit device. The source and drain regions contact the higher concentration regions and have a second conductivity type.

Abstract: A method for programming a semiconductor element in a semiconductor structure such as an IC involves reducing the backside thickness of the substrate and directing an energy beam through the backside at an opaque component of the semiconductor element. A support structure mounted on the semiconductor structure provides support during and after the thinning operation. Alternatively, the substrate can be thinned only under the semiconductor element, leaving the rest of the substrate thick enough to maintain structural integrity. The energy beam heats the opaque component. The prior thinning operation minimizes heat dissipation away from the semiconductor element, so that dopant diffusion occurs, changing the electrical characteristics of the semiconductor element. By modifying selected elements in this manner, a semiconductor structure can be permanently programmed, even if it does not include non-volatile memory. Additionally, security is enhanced since the programming leaves no visible signs.

Abstract: A random access memory cell and fabrication method therefor are disclosed. The random access memory cell includes a first and a second pull-down transistor cross-coupled such that a control terminal of the first pull-down transistor is connected to a conduction terminal of the second pull-down transistors, and the control terminal of the second pull-down transistor is connected to the conduction terminal of the first pull-down transistor. A first pass gate transistor is coupled between the conduction terminal of the first transistor and a first bit line of a bit line pair, and a second pass gate transistor is coupled between the conduction terminal of the second transistor and a second bit line of the bit line pair.

Abstract: A method of fabricating ROM products through the use of embedded flash/EEPROM prototypes is disclosed. This is accomplished by first forming a Flash/EEPROM prototype, performing programming simulations on the prototype, developing a ROM code and mask, and then forming a ROM product in the same manufacturing line by skipping certain Flash/EEPROM steps and then implanting the ROM code into the final ROM product. The method improves turn-around-time in the manufacturing line, and reduces cost to the customer. A method of doing business is also disclosed directed to providing ROM products to a customer without much redesign time and effort on the part of the customer.

Abstract: Semiconductor processing methods of forming integrated circuitry are described. In one embodiment, memory circuitry and peripheral circuitry are formed over a substrate. The peripheral circuitry comprises first and second type MOS transistors. Second type halo implants are conducted into the first type MOS transistors in less than all of the peripheral MOS transistors of the first type. In another embodiment, a plurality of n-type transistor devices are formed over a substrate and comprise memory array circuitry and peripheral circuitry. At least some of the individual peripheral circuitry n-type transistor devices are partially masked, and a halo implant is conducted for unmasked portions of the partially masked peripheral circuitry n-type transistor devices. In yet another embodiment, at least a portion of only one of the source and drain regions is masked, and at least a portion of the other of the source and drains regions is exposed for at least some of the peripheral circuitry n-type transistor devices.

Abstract: A method for manufacturing a ROM device includes a semiconductor substrate having an array of field-effect transistors within a ROM region. A first dielectric layer covers the array and all transistors are initially in an “ON” state. A second dielectric layer covers at least one layer of metal interconnection formed over the first dielectric layer. The bit lines do not overlap the transistor-sources. A coding photoresist layer is formed on the second dielectric layer and is patterned to form a plurality of apertures defining exposure windows exposing underlying field-effect transistors to be coded permanently to an “OFF” state. A code etching back process is implemented using the photoresist layer as a mask to etch the first and second dielectric layers, the sources of the MOSFETs, and a portion of the substrate through the exposure windows to form a deep trench, disconnecting the coded MOSFETs from the source lines.

Abstract: An improved method for forming a flash memory is disclosed. A self-aligned source implanted pocket located underneath and around the source line junction is formed after the field oxide between adjacent word lines is removed, and before or after the self-aligned source doping is carried out, so that the configuration of the implanted boron follows the source junction profile.

Abstract: A semiconductor nonvolatile memory device improving reproducibility and reliability of insulation breakage of a silicon oxide film and capable of reducing the manufacturing cost and a method for production of the same, wherein each of the memory cells arranged in a matrix form has an insulating film breakage type fuse comprising an impurity region of a first conductivity type formed on a semiconductor substrate, a first insulating film formed on the semiconductor substrate while covering the impurity region, an opening formed in the first insulating film so as to reach the impurity region, and a first semiconductor layer of a first conductivity type, a second insulating film, and a second semiconductor layer of a second conductivity type successively stacked in the opening from the impurity region side, or has an insulating film breakage type fuse comprising an impurity region of a first conductivity type in the first semiconductor layer having an SOI structure, a first insulating film on the SOI layer, an op

Abstract: A method for differentiating integrated circuits implementing identical functions by storage of a binary code in a non-volatile storage element provided in each circuit, including providing, for each circuit of a same reticle, a selective implantation of dopants of its storage element which is different from the selective implantations of dopants of the storage elements of the other circuits.

Abstract: Mask ROM cell and method of fabricating the same, is disclosed, including a semiconductor substrate of a first conductivity type, a plurality of impurity diffusion regions of a second conductivity type, formed in the semiconductor substrate in one direction, having a predetermined distance therebetween, an insulating layer formed on a portion of the semiconductor substrate, corresponding to each impurity diffusion region, a gate insulating layer formed on the semiconductor substrate, and a plurality of conductive lines formed on the gate insulating layer and insulating layer in a predetermined interval, being perpendicular to the impurity diffusion regions.

Abstract: A method for manufacturing a ROM device includes a semiconductor substrate having an array of field-effect transistors within a ROM region. A first dielectric layer covers the array of field-effect transistors. All of the field-effect transistors are initially in an “ON” state having a threshold voltage at a first value. At least one layer of metal interconnection is formed over the first dielectric layer within the ROM region and Is covered by a second dielectric layer. A coding photoresist layer is formed on the second dielectric layer and patterned to form a plurality of apertures defining exposure windows. Using the patterning coding photoresist layer as a dielectric etching and implantation hard mask, the underlying field-effect transistors to be coded permanently to a logic “OFF” state through the apertures, thereby raising the threshold voltage of the field-effect transistors to a second value.

Abstract: A method of manufacturing a CMOS TFT including forming first and second semiconductor layers on an insulating substrate using a first mask, respectively, the substrate having first and second regions, the first semiconductor layer formed on the first region, the second semiconductor layer formed on the second region; forming sequentially a first insulating layer, a first metal layer and a second insulating layer over the whole surface of the substrate; etching a portion of the first metal layer and a portion of the second insulating layer over the first region of the substrate using a second mask to form a first gate electrode and a first capping layer; forming first spacers on both side wall portion of the first gate electrode and the first capping layer; ion-implanting a first conductive-type high-density impurity into the first semiconductor layer using the first spacers and the first gate electrode as a mask to form first high-density source and drain regions; etching a portion of the first metal layer an

Abstract: The present invention includes a technique for making a dual voltage integrated circuit device. A gate dielectric layer is formed on a semiconductor substrate and a gate material layer is formed on the dielectric layer. A first region of the gate material layer is doped to a first nonzero level and a second region of the gate material level is doped to a second nonzero level greater than the first level. A first field effect transistor is defined that has a first gate formed from the first region. Also, a second field effect transistor is defined that has a second gate formed from the second region. The first transistor is operable at a gate threshold voltage greater than the second transistor in accordance with a difference between the first level and the second level.

Abstract: A fabrication method for a read only memory provides a substrate having a memory cell region and a periphery circuit region. A memory cell region has a memory cell array and the periphery circuit region has transistors. A precise layer having a plurality of first openings is formed in the memory cell region. The first openings are above the channel region of each memory cell in the memory cell array and the critical dimension of the first openings is identical. A mask layer having second openings and third openings is formed on the substrate. The second openings locate over a pre-coding memory cell region, and the third openings locate over the transistor gates. An ion implantation is performed to code the memory cell in the pre-coding memory cell region and to adjust the threshold voltage of the transistor, using the precise layer and the mask layer as a mask.

Abstract: The present invention generally relates to a method for fabricating a post-process one-time programmable (OTP) read only memory cell (ROM cell). The OTP ROM cell has two oxide layers positioned on a semiconductor substrate and a plurality of semiconductor-implanted regions are implanted in the semiconductor substrate. Oxide layers are respectively to those semiconductor-implanted regions of the semiconductor substrate and having a window-type isolating channel region for each. Finally, a polysilicon layer is positioned on the thicker oxide layer as a gate electrode region of the OTP ROM cell. Hence, the polysilicon layer can be applied a voltage to penetrate the thinker oxide layer of the window-type isolating channel region to form a P-N junction between the semiconductor-implanted regions and the polysilicon layer and then the ROM cell is programmed.

Abstract: A method of fabricating a semiconductor memory device, particularly a mask ROM. A sacrificial oxide layer is formed on a silicon substrate and then a photoresist layer is formed on the sacrificial oxide layer. The photoresist layer is patterned to form a plurality of openings where bit lines are to extend respectively. Taking the patterned photoresist layer as a mask, arsenic ions are implanted into the silicon substrate through the openings and then boron ions are implanted into the silicon substrate through the openings. The implantation depth of boron ions are deeper than arsenic ions. The photoresist layer and the sacrificial oxide layer are removed after implantation. A gate oxide and a field oxide are grown simultaneously on the non-implanted and the implanted regions of the semiconductor layers respectively and a gate conductive layer is deposited on the silicon substrate.

Abstract: Field effect transistor structures include a channel region formed in a recessed portion of a substrate. The recessed channel portion permits the use of relatively thicker source/drain regions thereby providing lower source/drain extension resistivity while maintaining the physical separation needed to overcome various short channel effects. The surface of the recessed channel portion may be of a rectangular, polygonal, or curvilinear shape. In a further aspect of the present invention, transistors are manufactured by a process in which a damascene layer is patterned, the channel region is recessed by etch that is self-aligned to the patterned damascene layer, and the gate electrode is formed by depositing a material over the channel region and patterned damascene layer, polishing off the excess gate electrode material and removing the damascene layer.

Abstract: A method of manufacturing mask ROM is provided. A buried bit line is formed in a substrate and then a gate and a word line are formed over the substrate. Thereafter, a pre-coding layer with a plurality of pre-coding openings therein is formed over the substrate in a relatively high precision process. The pre-coding openings correspond in position to a plurality of coding regions on the substrate underneath the gate. A filler material is deposited into the pre-coding openings to form a filler layer. A coding mask having a plurality of coding openings is formed over the substrate in a relatively low precision process. The filler material inside the pre-coding openings that correspond in position to the code openings in the coding mask is removed. The coding mask is removed. Finally, a coding ion implant is carried out using the pre-coding layer and the filler layer as mask and hence ions are implanted into the code region through the pre-coding openings.

Abstract: A mask ROM device is described. The mask ROM device includes a substrate, a gate, a double diffused source/drain region that comprises a first doped region and a second doped region, a channel region, a coding region, a dielectric layer and a word line. The gate is disposed on the substrate. The double diffused source/drain region is positioned beside the sides of the gate in the substrate, wherein the second doped region is located at the periphery of the first doped region in the substrate. The channel region is located between the double diffused source/drain region in the substrate. The coding region is disposed in the substrate at the intersection between the sides of the channel region and the double diffused source/drain region. The dielectric layer is disposed above the double diffused source/drain region, while the word line is disposed above the dielectric layer and the gate.

Abstract: A process uses two layers of polysilicon for fabricating high-density nonvolatile memory, such as mask ROM or SONOS memory, integrated with advanced peripheral logic on a single chip. The method includes covering a gate dielectric layer with a sacrificial layer of silicon nitride; using a masks for defining line structures in the layer of silicon nitride for the bit line implant processes; depositing a dielectric material among the line structures to fill gaps among the line structures; planarizing the deposited oxide and said layer of silicon nitride; removing the silicon nitride and applying a layer of polysilicon material; patterning wordlines in the array portion, and transistor gate structures in said non-array portion, and applying LDD, silicide and other logic circuit processes.

Abstract: A method for manufacturing a semiconductor memory device includes forming an isolation layer adjacent a diffusion region over a substrate that also has a stacked gate region. A gate oxide layer is formed over the gate region; a first conductive layer over the isolation and gate oxide layers and the diffusion region; a nitride layer over the first conductive layer, the nitride layer having an opening at the isolation layer; and an oxide region in the first conductive layer using the nitride layer as a mask. After removing the nitride layer and the silicon oxide region, an interelectrode dielectric layer is formed over the first conductive layer, and a second conductive layer is formed over the interelectrode dielectric layer. Then, the interelectrode dielectric layer and the first conductive layer over the diffusion portion are removed and a diffusion layer is formed in the substrate of the diffusion portion.

Abstract: A non-volatile memory device including a plurality of memory cells, each memory cell formed as MOS transistor with a source region, a drain region and a gate having sides formed therewith; and one or more dielectric spacers disposed on the sides of the gate. At least one memory cell is defined in an ON state and at least one memory cell is defined in an OFF state. The memory cells in the ON state comprise drain regions and source regions of the lightly diffused drain (LDD) type, characterized in that the at least one drain region and the at least one source region of the memory cells in the OFF state are formed by one or more high dopant regions. The memory cells in the OFF state consists of layers of silicide on top of one or more active regions defined as the source region, the drain region, and the gate.

Abstract: A memory cell, which is isolated from other memory cells by STI trenches, each includes an ONO layer structure between a gate electrode and a channel region formed in a semiconductor body. The gate electrode is a component of a strip-shaped word line. Source and drain regions are disposed between gate electrodes of adjacent memory cells. Source regions are provided with polysilicon layers, in the form of a strip, as common source lines. Drain regions are connected as bit lines through polysilicon fillings to metallic interconnects applied to the top face of the semiconductor body.

Abstract: Methods for making integrated circuit devices, such as high density memory devices and memory devices exhibiting dual bits per cell, include forming multiple oxide fences on a semiconductor substrate between multiple polybars. The oxide fences create a hole pre-code pattern that facilitates ion implantation into trenches disposed between the polybars. The holes, or voids, formed by the oxide fences provide greater control of the critical dimension of ion implantation, for example, the critical dimension of the trench sidewalls. Semiconductor devices used in the manufacture of memory devices include the oxide fences during the manufacturing process.

Abstract: A method of fabricating a mask read only memory. Embedded bit line are formed in a substrate. A gate dielectric layer and a word line are formed on the substrate. The word line is perpendicular to the bit lines. The substrate under the word line and between each pair of the bit lines is referred as a memory unit. A first dielectric layer is formed to cover the substrate. A plurality of coding windows is formed in the first dielectric layer over the memory units. Ions are implanted into the memory cells exposed by the coding windows, and a second dielectric layer is formed to fill the coding windows.

Abstract: A method for fabricating a y-direction, self-alignment mask ROM device is described. The method includes forming a buried drain region in a substrate and forming a gate oxide layer on the substrate. Perpendicular to the direction of the buried drain region, a bar-shaped silicon nitride layer is formed on the gate oxide layer. A photoresist layer is then formed on the gate oxide layer and the bar-shaped silicon nitride layer. Performing a code implantation to form a plurality of coded memory cells using the photoresist layer as a mask. The photoresist layer is then removed. A polysilicon layer is further formed on the gate oxide layer and the bar-shaped silicon nitride layer. The polysilicon layer is back-etched until the bar-shaped silicon nitride layer is exposed. The silicon nitride layer is subsequently removed.

Abstract: A method for fabricating an UV-programmed P-type Mask ROM is described. The threshold voltages of all memory cells are raised at first to make each memory cell be in a first logic state, in which the channel is hard to switch on, in order to prevent a leakage current. After the bit lines and the word lines are formed, the Mask ROM is programmed by irradiating the substrate with UV light to inject electrons into the ONO layer under the openings to make the memory cells under the openings be in a second logic state.

Abstract: A passivation structure for a semiconductor device includes a high ultraviolet transmittance silicon nitride (UV-SiN) layer. This UV-SiN layer substantially conformally overlies a plurality of top metal lines, which are formed over a semiconductor substrate, such that topographical hollows are defined between adjacent top metal lines. A spin-on glass (SOG) material fills in the topographical hollows. A silicon oxynitride (SiON) layer having a thickness in a range from about 8,000 angstroms to about 10,000 angstroms overlies the UV-SiN layer and the SOG material. A method for forming the passivation structure also is described.

Abstract: A method of fabricating a memory device having a buried source/drain region is provided, in which a dielectric layer and a word-line is sequentially formed on the substrate, then a buried source/drain region is formed in the substrate. After that, a barrier layer is formed on the exposed surface of the word-line, then a metal layer is formed over the substrate. The metal layer is patterned to leave a portion covering the buried source/drain region beside the word-line and crossing over the word-line.