Class / Patent application number | Description | Number of patent applications / Date published |
438261000 | Multiple interelectrode dielectrics or nonsilicon compound gate insulator | 57 |
20080227254 | ELECTRONIC DEVICE INCLUDING CHANNEL REGIONS LYING AT DIFFERENT ELEVATIONS AND PROCESSES OF FORMING THE SAME - An electronic device including a nonvolatile memory cell can include a substrate including a first portion and a second portion, wherein a first major surface within the first portion lies at an elevation lower than a second major surface within the second portion. The electronic device can also include a charge storage stack overlying the first portion, wherein the charge storage stack includes discontinuous storage elements. The electronic device can further include a control gate electrode overlying the first portion, and a select gate electrode overlying the second portion, wherein the select gate electrode includes a sidewall spacer. In a particular embodiment, a process can be used to form the charge storage stack and control gate electrode. A semiconductor layer can be formed after the charge storage stack and control gate electrode are formed to achieve the substrate with different major surfaces at different elevations. The select gate electrode can be formed over the semiconductor layer. | 09-18-2008 |
20080248622 | Methods Of Fabricating Non-Volatile Memory With Integrated Peripheral Circuitry And Pre-Isolation Memory Cell Formation - Non-volatile semiconductor memory devices with dual control gate memory cells and methods of forming the same using integrated peripheral circuitry formation are provided. Strips of charge storage material elongated in a row direction across the surface of a substrate with strips of tunnel dielectric material therebetween are formed. Forming the strips defines the dimension of the resulting charge storage structures in the column direction. The strips of charge storage material can include multiple layers of charge storage material to form composite charge storage structures in one embodiment. Strips of control gate material are formed between strips of charge storage material adjacent in the column direction. The strips of charge storage and control gate material are divided along their lengths in the row direction as part of forming isolation trenches and columns of active areas. After dividing the strips, the charge storage material at the peripheral circuitry region of the substrate is etched to define a gate dimension in the column direction for a peripheral transistor. Control gate interconnects can be formed to connect together rows of isolated control gates to extrinsically form word lines. | 10-09-2008 |
20080268596 | Methods Of Fabricating Non-Volatile Memory With Integrated Select And Peripheral Circuitry And Post-Isolation Memory Cell Formation - Non-volatile semiconductor memory devices with dual control gate memory cells and methods of forming the same using integrated select and peripheral circuitry formation are provided. Strips of charge storage material elongated in a column direction across the surface of a substrate with strips of tunnel dielectric material therebetween are formed. The strips of charge storage material can include multiple layers of charge storage material to form composite charge storage structures in one embodiment. After forming isolation trenches in the substrate between active areas below the strips of charge storage material, spacer-assisted patterning is used to form a pattern at the memory array region. Strips of photoresist are patterned over a portion of the pattern at the memory array. Photoresist is also applied at the peripheral circuitry region. At least a portion of the layer stack is etched using the photoresist as a mask before removing the photoresist and etching the strips of charge storage material to form the charge storage structures. | 10-30-2008 |
20080286925 | NONVOLATILE MEMORY WITH BACKPLATE - The present invention provides a non-volatile memory string having serially connected dual-gate devices, in which a first gate dielectric layer adjacent a first gate electrode layer in each dual-gate device is charge-storing and in which the second gate electrode adjacent a non-charge storing gate dielectric layer are connected in common. In one implementation, the second gate electrodes of the dual-gate devices in the memory string are provided by a continuous layer of doped polysilicon, tungsten, tantalum nitride, tungsten nitride or any combination of two or more of these conductors. | 11-20-2008 |
20080293199 | SINGLE-POLY NON-VOLATILE MEMORY DEVICE AND ITS OPERATION METHOD - A single-poly, P-channel non-volatile memory cell that is fully compatible with nano-scale semiconductor manufacturing process is provided. The single-poly, P-channel non-volatile memory cell includes an N well, a gate formed on the N well, a gate dielectric layer between the gate and the N well, an ONO layer on sidewalls of the gate, a P | 11-27-2008 |
20080305593 | MEMORY STRUCTURE AND METHOD OF MAKING THE SAME - A memory structure disclosed in the present invention features a control gate and floating gates being positioned in recessed trenches. A method of fabricating the memory structure includes the steps of first providing a substrate having a first recessed trench. Then, a first gate dielectric layer is formed on the first recessed trench. A first conductive layer is formed on the first gate dielectric layer. After that, the first conductive layer is etched to form a spacer which functions as a floating gate on a sidewall of the first recessed trench. A second recessed trench is formed in a bottom of the first recessed trench. An inter-gate dielectric layer is formed on a surface of the spacer, a sidewall and a bottom of the second recessed trench. A second conductive layer formed to fill up the first and the second recessed trench. | 12-11-2008 |
20090004795 | METHOD OF MANUFACTURING FLASH MEMORY DEVICE - A method of manufacturing a flash memory device that prevents generation of voids when forming an interlayer dielectric film. The method may include forming a gate on a semiconductor substrate, and then sequentially stacking a first dielectric film and a second dielectric film on the semiconductor substrate, and then forming a first spacer comprising a first dielectric film pattern and a second dielectric film pattern on sidewalls of the gate by performing a first etching process, and then forming source and drain areas in the semiconductor substrate, and then removing the second dielectric film, and then sequentially stacking a third dielectric film and a fourth dielectric film on the semiconductor substrate, and then forming a second spacer comprising the first dielectric pattern and a third dielectric pattern on the sidewalls of the gate by performing a second etching process, and then forming an interlayer dielectric film on the semiconductor substrate including the gate and the first spacer. | 01-01-2009 |
20090023259 | Method of Producing Non Volatile Memory Device - A method of forming a floating gate structure is disclosed, and includes modifying the etch chemistry of a plasma treated reactive ion etch process using an inert atom to physically damage a dielectric region. The damaged dielectric region is subsequently etched using a wet etch process. | 01-22-2009 |
20090029511 | NOR-type channel-program channel-erase contactless flash memory on SOI - A semiconductor device having an electrically erasable programmable read only memory (EEPROM) comprises a contactless array of EEPROM memory cells disposed in rows and columns and constructed over a silicon-on-insulator wafer. Each EEPROM memory cell comprises a drain region, a source region, a gate region, and a body region. The semiconductor device further comprises a plurality of gate lines each connecting the gate regions of a row of EEPROM memory cells, a plurality of body lines each connecting the body regions of a column of EEPROM memory cells, a plurality of source lines each connecting the source regions of a column of EEPROM memory cells, and a plurality of drain lines each connecting the drain regions of a column of EEPROM memory cells. The source lines and the drain lines are buried lines, and the source regions and the drain regions of a column of EEPROM memory cells are insulated from the source regions and the drain regions of the adjacent columns of EEPROM memory cells. | 01-29-2009 |
20090029512 | SEMICONDUCTOR MEMORY HAVING CHARGE TRAPPING MEMORY CELLS AND FABRICATION METHOD THEREOF - A semiconductor memory having charge trapping memory cells and fabrication method thereof. The direction of current flow of each channel region of the memory transistors runs transversely with respect to the relevant word line, the bit lines are arranged on the top side of the word lines and in a manner electrically insulated from the latter, and electrically conductive local interconnects of source-drain regions are present, which are arranged in sections in interspaces between the word lines and in a manner electrically insulated from the latter and connected to the bit lines, wherein gate electrodes are arranged in trenches at least partly formed in the memory substrate. | 01-29-2009 |
20090035903 | SEMICONDUCTOR DEVICES AND METHODS OF FABRICATING THE SAME - Disclosed is a semiconductor device and method of fabricating the same. The device is disposed on a substrate, including a fin constructed with first and second sidewalls, a first gate line formed in the pattern of spacer on the first sidewall of the fin, and a second gate line formed in the pattern of spacer on the second sidewall of the fin. First and second impurity regions are disposed in the fin. The first and second impurity regions are isolated from each other and define a channel region in the fin between the first and second gate lines. | 02-05-2009 |
20090035904 | METHODS OF FORMING NON-VOLATILE MEMORY HAVING TUNNEL INSULATOR OF INCREASING CONDUCTION BAND OFFSET - Methods of forming non-volatile memory cell structures are described that facilitate the use of band-gap engineered gate stacks with asymmetric tunnel barriers in reverse and normal mode floating node memory cells that allow for direct tunnel programming and erase, while maintaining high charge blocking barriers and deep carrier trapping sites for good charge retention. The low voltage direct tunneling program and erase capability reduces damage to the gate stack and the crystal lattice from high energy carriers, reducing write fatigue and enhancing device lifespan. The low voltage direct tunnel program and erase capability also enables size reduction through low voltage design and further device feature scaling. Such memory cells also allow multiple bit storage. These characteristics allow such memory cells to operate within the definition of a universal memory, capable of replacing both DRAM and ROM in a system. | 02-05-2009 |
20090047764 | NON-VOLATILE MEMORY AND MANUFACTURING METHOD THEREOF - A non-volatile memory having a gate structure and a source/drain region is provided. The gate structure is disposed on a substrate. The gate structure includes a pair of floating gates, tunneling dielectric layers, a control gate and an inter-gate dielectric layer. The floating gates are disposed on the substrate. Each tunneling dielectric layer is disposed between each floating gate and the substrate. The control gate is disposed on the substrate between the pair of the floating gates and covers a top surface and sidewalls of each floating gate. The inter-gate dielectric layer is disposed between the control gate and each of the floating gates, disposed between the control gate and each of the tunneling dielectric layers, and disposed between the control gate and the substrate. The source/drain region is disposed in the substrate at respective sides of the gate structure. | 02-19-2009 |
20090053866 | NONVOLATILE SEMICONDUCTOR MEMORY DEVICE, METHOD FOR DRIVING THE SAME, AND METHOD FOR FABRICATING THE SAME - A p-type source region | 02-26-2009 |
20090098699 | METHOD FOR MANUFACTURING SEMICONDUCTOR DEVICE - A method for manufacturing a semiconductor device. In one example embodiment of the present invention, a method for manufacturing a semiconductor device includes various steps. First, a gate pattern is formed on a substrate. Next, a first oxide layer is formed on the gate pattern. Then, a second oxide layer, a first silicon nitride layer, and a second silicon nitride layer are sequentially formed over the substrate and the first oxide layer. Next, a first etching process is performed to remove horizontal portions of the first and second silicon nitride layers. Then, source/drain regions are formed in the substrate. Next, the vertical portions first and second silicon nitride layers are removed. Then, a third silicon nitride layer is formed over the second oxide layer. Finally, a second etching process is performed to remove horizontal portions of the third silicon nitride layer and the second oxide layer. | 04-16-2009 |
20090111228 | SELF ALIGNED RING ELECTRODES - The present invention in one embodiment provides a method of manufacturing an electrode that includes providing at least one metal stud positioned in a via extending into a first dielectric layer, wherein an electrically conductive liner is positioned between at least a sidewall of the via and the at least one metal stud; recessing an upper surface of the at least one metal stud below an upper surface of the first dielectric layer to provide at least one recessed metal stud; and forming a second dielectric atop the at least one recessed metal stud, wherein an upper surface of the electrically conductive liner is exposed. | 04-30-2009 |
20090111229 | METHOD OF FORMING A SPLIT GATE NON-VOLATILE MEMORY CELL - A method forms a split gate memory cell by providing a semiconductor substrate and forming an overlying select gate. The select gate has a predetermined height and is electrically insulated from the semiconductor substrate. A charge storing layer is subsequently formed overlying and adjacent to the select gate. A control gate is subsequently formed adjacent to and separated from the select gate by the charge storing layer. The charge storing layer is also positioned between the control gate and the semiconductor substrate. The control gate initially has a height greater than the predetermined height of the select gate. The control gate is recessed to a control gate height that is less than the predetermined height of the select gate. A source and a drain are formed in the semiconductor substrate. | 04-30-2009 |
20090155967 | METHOD OF FORMING MEMORY WITH FLOATING GATES INCLUDING SELF-ALIGNED METAL NANODOTS USING A COUPLING LAYER - 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. | 06-18-2009 |
20090155968 | METHOD OF FORMING A DIELECTRIC LAYER PATTERN AND METHOD OF MANUFACTURING A NON-VOLATILE MEMORY DEVICE USING THE SAME - In a method of forming a dielectric layer pattern, lower patterns are formed on a substrate. A first dielectric layer is formed on sidewalls and upper surfaces of the lower patterns and a surface of the substrate. A mask pattern is formed on the first dielectric layer to partially expose the first dielectric layer. The exposed first dielectric layer on upper surfaces and upper sidewalls of the lower patterns is partially removed and the removed first dielectric layer is deposited on surfaces of the first dielectric layer between the lower patterns, to form a second dielectric layer having a thickness greater than that of the first dielectric layer. The second dielectric layer on the sidewalls of the lower patterns and the substrate is etched to form a dielectric layer pattern. Accordingly, damage to the underlying layer may be reduced, and an unnecessary dielectric layer may be completely removed. | 06-18-2009 |
20090170263 | METHOD OF MANUFACTURING FLASH MEMORY DEVICE - Disclosed is a method of manufacturing a flash memory device. With this method, the surface area of a floating gate is increased by using a buffer film or a dummy pattern, without increasing the size of the flash memory device. Therefore, a coupling ratio is increased, and as a result, programming and erasure speed can be improved. | 07-02-2009 |
20090186459 | MANUFACTURING METHOD OF NON-VOLATILE MEMORY - A method of manufacturing a non-volatile memory is provided. A substrate is provided and then a number of stacked gate structures are formed on the substrate. Each of the stacked gate structures includes a tunneling dielectric layer, a floating gate, a first inter-gate dielectric layer, a control gate and a cap layer. A source region is formed in the substrate, and a second inter-gate dielectric layer is formed over the substrate. A number of polysilicon select gates are formed on one side of the stacked gate structures. The select gates connect the stacked gate structures together to form a memory cell column. A spacer is formed on each sidewall of the memory cell column. A drain region is formed in the substrate on one side of the memory cell column. A silicidation process is carried out to convert the polysilicon constituting the select gate into a silicide material. | 07-23-2009 |
20090191676 | FLASH MEMORY HAVING A HIGH-PERMITTIVITY TUNNEL DIELECTRIC - A high permittivity tunneling dielectric is used in a flash memory cell to provide greater tunneling current into the floating gate with smaller gate voltages. The flash memory cell has a substrate with source/drain regions. The high-k tunneling dielectric is formed above the substrate. The high-k tunneling dielectric can be deposited using evaporation techniques or atomic layer deposition techniques. The floating gate is formed on top of the high-k dielectric layer with an oxide gate insulator on top of that. A polysilicon control gate is formed on the top gate insulator. | 07-30-2009 |
20090286369 | Method of manufacturing a semiconductor device - In a method of manufacturing a semiconductor device, a tunnel insulation layer is formed on a substrate. A charge trapping layer is formed on the tunnel insulation layer. A protection layer pattern or a mold is formed on the charge trapping layer. Charge trapping layer patterns are formed on the tunnel insulation layer by etching the charge trapping layer using the protection layer pattern or the mold. The charge trapping layer patterns may be spaced apart from each other. Blocking layers are formed on the charge trapping layer patterns, respectively. A gate electrode is formed on the blocking layers and the tunnel insulation layer using the protection layer pattern or the mold. | 11-19-2009 |
20090325351 | NON-VOLATILE SEMICONDUCTOR MEMORY DEVICE AND METHOD FOR MANUFACTURING THE SAME - In a non-volatile semiconductor memory device having a MONOS structure, a memory cell section for storing information, and a periphery circuitry section for writing and reading the information with respect to the memory cell section are formed in the surface region of a silicon substrate. A plurality of memory cells is formed in the memory cell section, while a plurality of periphery circuitry transistors are formed also in the periphery circuitry section. Since the periphery circuitry transistor has a structure wherein no electric charge accumulation layer exists, it is possible to prevent from electric charge injection to the periphery circuitry transistor, whereby hot carrier characteristics of the periphery circuitry transistor are improved. | 12-31-2009 |
20100029052 | SELF-ALIGNED IN-LAID SPLIT GATE MEMORY AND METHOD OF MAKING - A method includes forming a silicon nitride layer and patterning it to form a first opening and a second opening separated by a first portion of silicon nitride. Gate material is deposited in the first and second openings to form first and second select gate structures in the first and second openings. Second and third portions of silicon nitride layer are removed adjacent to the first and second gate structures, respectively. A charge storage layer is formed over the semiconductor device after removing the second and third portions. First and second sidewall spacers of gate material are formed on the charge storage layer and adjacent to the first and second gate structures. The charge storage layer is etched using the first and second sidewall spacers as masks. The first portion is removed. A drain region is formed in the semiconductor layer between the first and second gate structures. | 02-04-2010 |
20100035395 | METHODS OF FORMING MEMORY CELLS ON PILLARS AND MEMORIES WITH MEMORY CELLS ON PILLARS - Methods of fabricating memory are disclosed. For example, a method includes fabricating rows of memory cells on pillars separated by isolation regions therebetween. Each pillar has a pair of memory cells, each on an opposite side thereof. The method also includes fabricating control gates substantially between the rows of memory cells, each control gate to control half the cells of each of its adjacent rows of memory cells, and fabricating word lines for the array, the word lines extending substantially parallel to the control gates for the cells. | 02-11-2010 |
20100041192 | Method For Preparing Multi-Level Flash Memory Structure - A method for preparing a multi-level flash memory structure comprises the steps of forming a protrusion in a semiconductor substrate, forming a plurality of storage structures at the sides of the protrusion, forming a dielectric layer overlying the storage structures and the protrusion of the semiconductor substrate, forming a gate structure on the dielectric layer, and forming a plurality of diffusion regions at the sides of the protrusion. Each of the storage structures includes a charge-trapping site and an insulation structure isolating the charge-trapping site from the semiconductor substrate. | 02-18-2010 |
20100047982 | Flash Memory Cell Arrays Having Dual Control Gates Per Memory Cell Charge Storage Element - A flash NAND type EEPROM system with individual ones of an array of charge storage elements, such as floating gates, being capacitively coupled with at least two control gate lines. The control gate lines are preferably positioned between floating gates to be coupled with sidewalls of floating gates. The memory cell coupling ratio is desirably increased, as a result. Both control gate lines on opposite sides of a selected row of floating gates are usually raised to the same voltage while the second control gate lines coupled to unselected rows of floating gates immediately adjacent and on opposite sides of the selected row are kept low. The control gate lines can also be capacitively coupled with the substrate in order to selectively raise its voltage in the region of selected floating gates. The length of the floating gates and the thicknesses of the control gate lines can be made less than the minimum resolution element of the process by forming an etch mask of spacers. | 02-25-2010 |
20100093142 | METHOD OF FABRICATING DEVICE - A method of fabricating a device is described. A substrate having at least two isolation structures is provided. A first oxide layer and a first conductive layer are sequentially formed on the substrate between the isolation structures. A first nitridation process is performed to form a first nitride layer on the surface of the first conductive layer and a first oxynitride layer on the surface of the isolation structures. A second oxide layer is formed on the first nitride layer and first oxynitride layer. A densification process is performed to oxidize the first oxynitride layer on the surface of the isolation structures. A second nitride layer and a third oxide layer are sequentially formed on the second oxide layer. A second nitridation process is performed to form a third nitride layer on the surface of the third oxide layer. A second conductive layer is formed on the third nitride layer. | 04-15-2010 |
20100093143 | METHOD OF MANUFACTURING SEMICONDUCTOR DEVICE - A semiconductor device including a semiconductor substrate; a plurality of memory cell transistors aligned in a predetermined direction on the semiconductor substrate, each memory cell transistor provided with a first gate electrode including a floating gate electrode comprising a polycrystalline silicon layer of a first thickness, a control gate electrode provided above the floating gate electrode, and an inter-gate insulating film between the floating and the control gate electrode; a pair of select gate transistors on the semiconductor substrate with a pair of second gate electrodes neighboring in alignment with the first gate electrode, each second gate electrode including a lower-layer gate electrode comprising the polycrystalline silicon layer of the first thickness, an upper-layer gate electrode provided above the lower-layer gate electrode; a polyplug of the first thickness situated between the second gate electrodes of the pair of select gate transistors; and a metal plug provided on the polyplug. | 04-15-2010 |
20100105178 | Method of manufacturing a flash memeory device - Provided may be a method of fabricating a flash memory device having metal nano particles. The method of manufacturing a flash memory device may include forming a metal oxide thin layer on a semiconductor substrate, forming a floating gate of an amorphous metal silicon oxide thin layer by performing a thermal treatment process on the semiconductor substrate where the metal oxide thin layer is formed, and forming metal nano particles in the floating gate by projecting an electron beam on the floating gate, the metal nano particles being surrounded by a silicon oxide layer. | 04-29-2010 |
20100105179 | METHOD FOR MANUFACTURING FLASH MEMORY DEVICE - A method for manufacturing a flash memory device is capable of controlling a phenomenon in which a length of the channel between a source and a drain is decreased due to undercut. The method includes forming a gate electrode comprising a floating gate, an ONO film and a control gate using a hard mask pattern over a semiconductor substrate, forming a spacer over the sidewall of the gate electrode, forming an low temperature oxide (LTO) film over the entire surface of the semiconductor substrate including the gate electrode and the spacer, etching the LTO film such that a top portion of the source/drain region and a top portion of the gate electrode are exposed, and removing the LTO film present over the sidewall of the gate electrode by wet-etching. | 04-29-2010 |
20100112768 | METHOD OF MANUFACTURING NON-VOLATILE SEMICONDUCTOR DEVICES - A non-volatile semiconductor device includes a memory cell in a first area of a substrate, a low voltage transistor in a second area of the substrate, and a high voltage transistor in a third area of the substrate. The memory cell includes a tunnel insulation layer formed on the substrate, a charge trapping layer pattern formed on the tunnel insulation layer in the first area of the substrate, a blocking layer pattern formed on the charge trapping layer pattern and a control gate formed on the blocking layer pattern. The control gate has a width substantially smaller than a width of the blocking layer pattern and the width of the control gate is substantially smaller than a width of the charge trapping layer pattern. In addition, an offset is formed between the control gate and the blocking layer pattern such that a spacer is not formed on a sidewall of the control gate. | 05-06-2010 |
20100112769 | VERTICAL-TYPE NON-VOLATILE MEMORY DEVICES AND METHODS OF MANUFACTURING THE SAME - In a semiconductor device, and a method of manufacturing thereof, the device includes a substrate of single-crystal semiconductor material extending in a horizontal direction and a plurality of interlayer dielectric layers on the substrate. A plurality of gate patterns are provided, each gate pattern being between a neighboring lower interlayer dielectric layer and a neighboring upper interlayer dielectric layer. A vertical channel of single-crystal semiconductor material extends in a vertical direction through the plurality of interlayer dielectric layers and the plurality to of gate patterns, a gate insulating layer being between each gate pattern and the vertical channel that insulates the gate pattern from the vertical channel. | 05-06-2010 |
20100167480 | Method for Manufacturing Flash Memory Device - The present invention relates to a method for fabricating a flash memory device capable of reducing charge loss. The method includes forming a gate pattern on a semiconductor substrate, forming a sidewall spacer layer on the gate pattern using SiO | 07-01-2010 |
20100197095 | Methods Of Forming Memory Cells - Some embodiments include methods of forming memory cells. A semiconductor construction may be provided, with such construction including tunnel dielectric material over a semiconductor substrate. The construction may be placed within a chamber. While the construction is within the chamber, a plurality of charge-trapping centers may be dispersed over the tunnel dielectric material. The charge-trapping centers may be nanoclusters formed by sputter-depositing metallic nanoparticles into an aggregation chamber, and then aggregating groups of the nanoparticles into the nanoclusters. Also while the construction is within the chamber, electrically insulative material may be formed over and between the charge-trapping centers. Control gate material may then be formed over the electrically insulative material. | 08-05-2010 |
20100203694 | METHODS FOR FABRICATING DUAL BIT FLASH MEMORY DEVICES - 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. | 08-12-2010 |
20100240181 | Method for Forming Single-Level Electrically Erasable and Programmable Read Only Memory Operated in Environment with High/Low-Voltage - First of all, a semiconductor substrate is provided, and then a first/second wells with a first conductivity are formed therein so as to individually form a first part of the floating gate of single-level EEPROM and a low-voltage device thereon, wherein the first and the second wells are used to separate the high-voltage device, and the depth of the first well is the same as the second well. Furthermore, the high-voltage device and the second part of the floating gate of single-level EEPROM are individually formed on the semiconductor substrate between the first and the second wells, and the control gate of the floating gate of single-level EEPROM is formed in the third well located under the second part of the floating gate of single-level EEPROM, wherein the high-voltage device can be operated in the opposite electric field about 18V, such as −6V˜12V, −12V˜6V, −9V˜9V etc. | 09-23-2010 |
20100240182 | Spacer Patterns Using Assist Layer For High Density Semiconductor Devices - High density semiconductor devices and methods of fabricating the same are provided. Spacer fabrication techniques are utilized to form circuit elements having reduced feature sizes, which in some instances are smaller than the smallest lithographically resolvable element size of the process being used. Spacers are formed that serve as a mask for etching one or more layers beneath the spacers. An etch stop pad layer having a material composition substantially similar to the spacer material is provided between a dielectric layer and an insulating sacrificial layer such as silicon nitride. When etching the sacrificial layer, the matched pad layer provides an etch stop to avoid damaging and reducing the size of the dielectric layer. The matched material compositions further provide improved adhesion for the spacers, thereby improving the rigidity and integrity of the spacers. | 09-23-2010 |
20100248435 | METHOD OF SELECTIVE NITRIDATION - Methods of forming semiconductor devices are provided herein. In some embodiments, a method of forming a semiconductor device may include providing a substrate having an oxide surface and a silicon surface; forming a nitrogen-containing layer on exposed portions of both the oxide and silicon surfaces; and oxidizing the nitrogen-containing layer to selectively remove the nitrogen-containing layer from atop the oxide surface. In some embodiments, an oxide layer is formed atop a remaining portion of the nitrogen-containing layer formed on the silicon feature. In some embodiments, the oxide surface is an exposed surface of a shallow trench isolate region (STI) disposed adjacent to one or more floating gates of a semiconductor device. In some embodiments, the silicon surface is an exposed surface of a silicon or polysilicon floating gate of a semiconductor device. | 09-30-2010 |
20100304540 | SEMICONDUCTOR DEVICE AND METHOD OF FORMING THE SAME - There is provided a semiconductor device and a method of forming the same. The semiconductor device includes a memory device and a self-aligned selection device. A floating junction is formed between the self-aligned selection device and the memory device. | 12-02-2010 |
20100323483 | METHOD OF FABRICATING MEMORY - A method of fabricating a semiconductor device is provided. First, a stacked structure is formed on a substrate. The stacked structure includes, from the substrate, a dielectric layer and a conductive gate in order. An ion implant process is performed to form doped regions in the substrate on the opposite sides of the stacked structure. Thereafter, source-side spacer is formed on a sidewall of the stacked structure. A thermal process is performed to activate the doped regions, thereby forming a source in the substrate under the sidewall of the stacked structure having the source-side spacer and a drain in the substrate on another side of the stacked structure. | 12-23-2010 |
20110014759 | Method of Fabricating Non-volatile Memory Device - A method of fabricating a non-volatile memory device includes: forming a tunnel insulation layer pattern and a floating gate electrode layer pattern over a semiconductor substrate; forming an isolation trench by etching an exposed portion of the semiconductor substrate so that the isolation trench is aligned with the tunnel insulation layer pattern and the floating gate electrode layer pattern; forming an isolation layer by filling the isolation trench with a filling insulation layer; forming a hafnium-rich hafnium silicon oxide layer over the isolation layer and the floating gate electrode layer pattern; forming a hafnium-rich hafnium silicon oxynitride layer by carrying out a first nitridation on the hafnium-rich hafnium silicon oxide layer; forming a silicon-rich hafnium silicon oxide layer over the hafnium-rich hafnium silicon oxynitride layer; forming a silicon-rich hafnium silicon oxynitride layer by carrying out a second nitridation on the silicon-rich hafnium silicon oxide layer; and forming a control gate electrode layer over the silicon-rich hafnium silicon oxynitride layer. | 01-20-2011 |
20110124166 | Memory device and method of manufacturing the same - In a memory device and a method of manufacturing the memory device, a source contact connected to a common source line may be formed on a drain region instead of a source region. A transistor having a negative threshold voltage may be formed between the source region and the drain region. A channel of the transistor may be formed. Because the source contact is formed on the drain region, the size of the source region may be reduced. An integration degree of the memory device may be improved. A control gate may linearly extend in a second direction because the source contact is not formed on the source region. | 05-26-2011 |
20110165745 | NONVOLATILE SEMICONDUCTOR MEMORY AND MANUFACTURING METHOD THEREOF - A nonvolatile semiconductor memory according to examples of the present invention comprises a memory cell and a peripheral transistor. The memory cell has a first intergate insulating film having a multilayer structure and provided on a floating gate electrode and an isolation insulating layer. The peripheral transistor has a second intergate insulating film having a multilayer structure and provided on a first gate electrode and a second isolation insulating layer. The first and second intergate insulating films have the same structure, and a lowermost insulating layer of the first intergate insulating film on the first isolation insulating layer is thinner than a lowermost insulating layer of the second intergate insulating film on the second isolation insulating layer. | 07-07-2011 |
20110244640 | METHOD OF MANUFACTURING FLASH MEMORY CELL - A method of manufacturing a flash memory cell includes providing a substrate having a first dielectric layer formed thereon, forming a control gate on the first dielectric layer, forming an oxide-nitride-oxide (ONO) spacer on sidewalls of the control gate, forming a second dielectric layer on the substrate at two sides of the ONO spacer, and forming a floating gate at outer sides of the ONO spacer on the second dielectric layer, respectively. | 10-06-2011 |
20110287597 | Nonvolatile semicondutor memory device and manufacturing method thereof - A nonvolatile semiconductor memory device that have a new structure are provided, in which memory cells are laminated in a three dimensional state so that the chip area may be reduced. The nonvolatile semiconductor memory device of the present invention is a nonvolatile semiconductor memory device that has a plurality of the memory strings, in which a plurality of electrically programmable memory cells is connected in series. The memory strings comprise a pillar shaped semiconductor; a first insulation film formed around the pillar shaped semiconductor; a charge storage layer formed around the first insulation film; the second insulation film formed around the charge storage layer; and first or nth electrodes formed around the second insulation film (n is natural number more than 1). The first or nth electrodes of the memory strings and the other first or nth electrodes of the memory strings are respectively the first or nth conductor layers that are spread in a two dimensional state. | 11-24-2011 |
20120003800 | Methods of Forming Nonvolatile Memory Devices Having Vertically Integrated Nonvolatile Memory Cell Sub-Strings Therein and Nonvolatile Memory Devices Formed Thereby - Methods of forming nonvolatile memory devices according to embodiments of the invention include techniques to form highly integrated vertical stacks of nonvolatile memory cells. These vertical stacks of memory cells can utilize dummy memory cells to compensate for process artifacts that would otherwise yield relatively poor functioning memory cell strings when relatively large numbers of memory cells are stacked vertically on a semiconductor substrate using a plurality of vertical sub-strings electrically connected in series. | 01-05-2012 |
20120156843 | DIELECTRIC LAYER FOR GALLIUM NITRIDE TRANSISTOR - A dielectric layer for a gallium nitride transistor is disclosed. In one example, the dielectric layer has a hydrogen content of less than or equal to 10% by atomic percentage. In one example, both a dielectric layer formed before a conductive electrode of the transistor and a dielectric layer formed after the conductive elective electrode have a hydrogen content of less than or equal to 10% by atomic percentage. In one example, the dielectric layer formed before the conductive electrode is formed by a LPCVD process and the dielectric layer formed after the conductive electrode is formed by a sputtering process. | 06-21-2012 |
20120220088 | ULTRAHIGH DENSITY VERTICAL NAND MEMORY DEVICE AND METHOD OF MAKING THEREOF - Monolithic, three dimensional NAND strings include a semiconductor channel, at least one end portion of the semiconductor channel extending substantially perpendicular to a major surface of a substrate, a plurality of control gate electrodes having a strip shape extending substantially parallel to the major surface of the substrate, the blocking dielectric comprising a plurality of blocking dielectric segments, a plurality of discrete charge storage segments, and a tunnel dielectric located between each one of the plurality of the discrete charge storage segments and the semiconductor channel. | 08-30-2012 |
20120225528 | FLOATING GATE FLASH CELL DEVICE AND METHOD FOR PARTIALLY ETCHING SILICON GATE TO FORM THE SAME - A method for forming a split gate flash cell memory device provides for establishing a floating gate region then using spacers or other hard mask materials that cover opposed edges of a gate electrode material in the gate region, to serve as hard masks during an etching operation that partially etches the gate electrode material which may be polysilicon. The gate electrode so produced serves as a floating gate electrode and includes a recessed central portion flanked by a pair of opposed upwardly extending fins which may terminate upwardly at an apex. A floating gate oxide is then formed by thermal oxidation and/or oxide deposition techniques. | 09-06-2012 |
20130045578 | DEVICES AND METHODS TO IMPROVE CARRIER MOBILITY - Electronic apparatus and methods of forming the electronic apparatus include a silicon oxynitride layer on a semiconductor device for use in a variety of electronic systems. The silicon oxynitride layer may be structured to control strain in a silicon channel of the semiconductor device to modify carrier mobility in the silicon channel, where the silicon channel is configured to conduct current under appropriate operating conditions of the semiconductor device. | 02-21-2013 |
20130078775 | METHOD OF FABRICATING MEMORY - A method of fabricating a memory is provided. A substrate including a memory region and a periphery region is provided. A plurality of first gates is formed in the memory region and a plurality of first openings is formed between the first gates. A nitride layer is formed on the substrate in the memory region, and the nitride layer covers the first gates and the first openings. An oxide layer is formed on the substrate in the periphery region. A nitridization process is performed to nitridize the oxide layer into a nitridized oxide layer. A conductive layer is formed on the substrate, and the conductive layer includes a cover layer disposed on the substrate in the memory region and a plurality of second gates disposed on the substrate in the periphery region. The cover layer covers the nitride layer and fills the first openings. | 03-28-2013 |
20130330893 | INTEGRATING FORMATION OF A REPLACEMENT GATE TRANSISTOR AND A NON-VOLATILE MEMORY CELL USING A HIGH-K DIELECTRIC - A first dielectric layer is formed in an NVM region and a logic region. A charge storage layer is formed over the first dielectric layer and is patterned to form a dummy gate in the logic region and a charge storage structure in the NVM region. A second dielectric layer is formed in the NVM and logic regions which surrounds the charge storage structure and dummy gate. The second dielectric layer is removed from the NVM region while protecting the second dielectric layer in the logic region. The dummy gate is removed, resulting in an opening. A third dielectric layer is formed over the charge storage structure and within the opening, and a gate layer is formed over the third dielectric layer and within the opening, wherein the gate layer forms a control gate layer in the NVM region and the gate layer within the opening forms a logic gate. | 12-12-2013 |
20140106526 | METHOD OF MANUFACTURING FLASH MEMORY CELL - A method of manufacturing a flash memory cell includes providing a substrate having a first dielectric layer formed thereon, forming a control gate on the first dielectric layer, forming an oxide-nitride-oxide (ONO) spacer on sidewalls of the control gate, forming a second dielectric layer on the substrate at two sides of the ONO spacer, and forming a floating gate at outer sides of the ONO spacer on the second dielectric layer, respectively. | 04-17-2014 |
20150011063 | METHODS OF FABRICATING SEMICONDUCTOR STRUCTURES - Semiconductor structures including an etch stop material between a substrate and a stack of alternating insulating materials and first conductive materials, wherein the etch stop material comprises an amorphous aluminum oxide on the substrate and a crystalline aluminum oxide on the amorphous aluminum oxide; a channel material extending through the stack; and a second conductive material between the channel material and at least one of the first conductive materials in the stack of alternating insulating materials and first conductive materials, wherein the second conductive material is not between the channel material and the etch stop material. Also disclosed are methods of fabricating such semiconductor structures. | 01-08-2015 |
20160043096 | METHOD FOR MANUFACTURING A FLOATING GATE MEMORY ELEMENT - The disclosed technology generally relates to fabricating semiconductor devices and more particularly to fabricating a floating-gate based memory device. In one aspect, a method of fabricating a memory device comprises forming a stack of horizontal layers comprising alternating sacrificial layers of a first type and sacrificial layers of a second type; forming a vertical opening through the horizontal stack of layers; forming a first vertical dielectric layer on a sidewall of the vertical opening; forming a vertical floating gate layer on the first vertical dielectric layer; forming a second vertical dielectric layer on the vertical floating gate layer; filling the vertical opening with a channel material; forming cavities of a first type by removing the sacrificial layers of the second type to expose the first vertical dielectric layer; removing portions of the first vertical dielectric layer and the vertical floating gate layer at locations adjacent to the cavities of the first type, such that portions of the second vertical dielectric layer are exposed; filling the cavities of the first type with an isolating material; forming cavities of a second type by removing the sacrificial layers of the first type, wherein the cavities of the second type exposes portions of the first vertical dielectric layer; forming a third dielectric layer in the cavities of the second type, wherein the third dielectric layer is formed on the first vertical dielectric layer; and forming a conductive material in the cavities of the second type. | 02-11-2016 |