Patent application number | Description | Published |
20100096686 | ELECTRONIC DEVICE INCLUDING TRENCHES AND DISCONTINUOUS STORAGE ELEMENTS - An electronic device can include a substrate including a first trench having a first bottom and a first wall. The electrode device can also include a first gate electrode within the first trench and adjacent to the first wall and overlying the first bottom of the first trench, and a second gate electrode within the first trench and adjacent to the first gate electrode and overlying the first bottom of the first trench. The electronic device can further include discontinuous storage elements including a first set of discontinuous storage elements, wherein the first set of the discontinuous storage elements lies between (i) the first gate electrode or the second gate electrode and (ii) the first bottom of the first trench. Processes of forming and using the electronic device are also described. | 04-22-2010 |
20100155824 | NANOCRYSTAL MEMORY WITH DIFFERENTIAL ENERGY BANDS AND METHOD OF FORMATION - A method of making a semiconductor device using a semiconductor substrate includes forming a first insulating layer having a first band energy over the semiconductor substrate. A first semiconductor layer having a second band energy is formed on the first insulating layer. The first semiconductor layer is annealed to form a plurality of first charge retainer globules from the first semiconductor layer. A first protective film is formed over each charge retainer globule of the plurality of first charge retainer globules. A second semiconductor layer is formed having a third band energy over the plurality of first charge retainer globules. The second semiconductor layer is annealed to form a plurality of storage globules from the second semiconductor layer over the plurality of first charge retainer globules. A magnitude of the second band energy is between a magnitude of the first band energy and a magnitude of the third band energy. | 06-24-2010 |
20110073936 | NANOCRYSTAL MEMORY WITH DIFFERENTIAL ENERGY BANDS AND METHOD OF FORMATION - A method of making a semiconductor device using a semiconductor substrate includes forming a first insulating layer having a first band energy over the semiconductor substrate. A first semiconductor layer having a second band energy is formed on the first insulating layer. The first semiconductor layer is annealed to form a plurality of first charge retainer globules from the first semiconductor layer. A first protective film is formed over each charge retainer globule of the plurality of first charge retainer globules. A second semiconductor layer is formed having a third band energy over the plurality of first charge retainer globules. The second semiconductor layer is annealed to form a plurality of storage globules from the second semiconductor layer over the plurality of first charge retainer globules. A magnitude of the second band energy is between a magnitude of the first band energy and a magnitude of the third band energy. | 03-31-2011 |
20110256705 | METHOD FOR FORMING A SPLIT GATE DEVICE - A method for forming a semiconductor device includes forming a dielectric layer over a substrate. The method further includes forming a select gate layer over the dielectric layer. The method further includes etching the select gate layer at a first etch rate to form a first portion of a sidewall of a select gate, wherein the step of etching the select gate layer at the first etch rate includes using an oxidizing agent to oxidize at least a top portion of the substrate underlying the dielectric layer to form an oxide layer. The method further includes etching the select gate layer at a second etch rate lower than the first etch rate to form a second portion of the sidewall of the select gate, wherein the step of etching the select gate layer at the second etch rate includes removing only a top portion of the dielectric layer. | 10-20-2011 |
20120261635 | RESISTIVE RANDOM ACCESS MEMORY (RAM) CELL AND METHOD FOR FORMING - A resistive random access memory cell over a substrate includes a memory stack structure and a sidewall spacer. The memory stack structure is over the substrate and includes a first electrode layer, a second electrode layer, and a metal oxide layer between the first electrode layer and the second electrode layer. The metal oxide layer has a sidewall. The sidewall spacer is adjacent to the sidewall and has a composition including silicon, carbon, and nitrogen. | 10-18-2012 |
20120261636 | RESISTIVE RANDOM ACCESS MEMORY (RAM) CELL AND METHOD FOR FORMING - A resistive random access memory cell uses a substrate and includes a gate stack over the substrate. The gate stack includes a first copper layer over the substrate, a copper oxide layer over the first copper layer, and a second copper layer over the copper oxide layer. | 10-18-2012 |
20130264533 | RERAM DEVICE STRUCTURE - A resistive random access memory (ReRAM) includes a first metal layer having a first metal and a metal-oxide layer on the first metal layer. The metal-oxide layer inlcudes the first metal. The ReRAM further includes a second metal layer over the metal-oxide layer and a first continuous conductive barrier layer in physical contact with sidewalls of the first metal layer and of the metal-oxide layer. | 10-10-2013 |
20130320284 | FIELD FOCUSING FEATURES IN A RERAM CELL - A resistive random access memory (ReRAM) cell, comprising a first conductive electrode and a dielectric storage material layer over the first conductive electrode. The dielectric storage material layer is conducive to the formation of conductive filaments during the application of a filament forming voltage to the cell. The cell includes a second conductive electrode over the dielectric storage material layer and an interface region comprising a plurality of interspersed field focusing features that are not photo-lithographically defined. The interface region is located between the first conductive electrode and the dielectric storage material layer or between the dielectric storage material layer and the second conductive electrode. | 12-05-2013 |
20130320285 | FIELD FOCUSING FEATURES IN A RERAM CELL - A resistive random access memory (ReRAM) cell comprising a first conductive electrode and a dielectric storage material layer over the first conductive electrode. The dielectric storage material layer is conducive to the formation of conductive filaments during the application of a filament forming voltage to the cell. The cell includes a second conductive electrode over the dielectric storage material layer and a layer of conductive nanoclusters ( | 12-05-2013 |
20140003155 | SPLIT GATE PROGRAMMING | 01-02-2014 |
20140036568 | RERAM DEVICE STRUCTURE - A resistive random access memory (ReRAM) device can comprise a first metal layer and a first metal-oxide layer on the first metal layer. The first metal-oxide layer comprises the first metal. A second metal layer can comprise a second metal over and in physical contact with the first metal-oxide layer. A first continuous non-conductive barrier layer can be in physical contact with sidewalls of the first metal layer and sidewalls of the first metal-oxide layer. A second metal-oxide layer can be on the second metal layer. The second metal-oxide layer can comprise the second metal layer. A third metal layer can be over and in physical contact with the second metal-oxide layer. The first and second metal-oxide layers, are further characterized as independent storage mediums. | 02-06-2014 |
20140091380 | Split Gate Flash Cell - In one aspect, a disclosed method of fabricating a split gate memory device includes forming a gate dielectric layer overlying an channel region of a semiconductor substrate and forming an electrically conductive select gate overlying the gate dielectric layer. The method further includes forming a counter doping region in an upper region of the substrate. A proximal boundary of the counter doping region is laterally displaced from a proximal sidewall of the select gate. The method further includes forming a charge storage layer comprising a vertical portion adjacent to the proximal sidewall of the select gate and a lateral portion overlying the counter doping region and forming an electrically conductive control gate adjacent to the vertical portion of the charge storage layer and overlying the horizontal portion of the charge storage layer. | 04-03-2014 |
20140209995 | Non-Volatile Memory Cells Having Carbon Impurities and Related Manufacturing Methods - Non-volatile memory (NVM) cells having carbon impurities are disclosed along with related manufacturing methods. The carbon impurities can be introduced using a variety of techniques, including through epitaxial growth of silicon-carbon (SiC) layers and/or carbon implants. Further, the carbon impurities can be introduced into one or more structures within NVM cells, including source regions, drain regions, gate regions, and/or charge storage layers. For discrete charge storage layers that utilize nanocrystal structures, carbon impurities can be introduced into the nanocrystal charge storage layers. The disclosed embodiments are useful for a variety of NVM cell types including split-gate NVM cells, floating gate NVM cells, discrete charge storage NVM cells, and/or other desired NVM cells. Advantageously, the carbon impurities introduce tensile stress into the cell structures, and this tensile stress helps maintain NVM system performance and data retention even as device geometries are reduced. | 07-31-2014 |
20140239372 | SPLIT GATE NON-VOLATILE MEMORY (NVM) CELL AND METHOD THEREFOR - A split gate memory structure includes a pillar of active region having a first source/drain region disposed at a first end of the pillar, a second source/drain region disposed at a second end of the pillar, opposite the first end, and a channel region between the first and second source/drain regions. The pillar has a major surface extending between first and the second ends which exposes the first source/drain region, the channel region, and the second source/drain region. A select gate is adjacent the first source/drain region and a first portion of the channel region, wherein the select gate encircles the major surface the pillar. A charge storage layer is adjacent the second source/drain region and a second portion of the channel region, wherein the charge storage layer encircles the major surface the pillar. A control gate is adjacent the charge storage layer, wherein the control gate encircles the pillar. | 08-28-2014 |
20140295639 | FIELD FOCUSING FEATURES IN A RERAM CELL - A resistive random access memory (ReRAM) cell comprising a first conductive electrode and a dielectric storage material layer over the first conductive electrode. The dielectric storage material layer is conducive to the formation of conductive filaments during the application of a filament forming voltage to the cell. The cell includes a second conductive electrode over the dielectric storage material layer and a layer of conductive nanoclusters ( | 10-02-2014 |
20140319593 | SCALABLE SPLIT GATE MEMORY CELL ARRAY - A split gate memory array includes a first row having memory cells; a second row having memory cells, wherein the second row is adjacent to the first row; and a plurality of segments. Each segment includes a first plurality of memory cells of the first row, a second plurality of memory cells of the second row, a first control gate portion which forms a control gate of each memory cell of the first plurality of memory cells, and a second control gate portion which forms a control gate of each memory cell of the second plurality of memory cells. The first control gate portion and the second control gate portion converge to a single control gate portion between neighboring segments of the plurality of segments. | 10-30-2014 |
20140321213 | BIASING SPLIT GATE MEMORY CELL DURING POWER-OFF MODE - A non-volatile memory (NVM) system has a normal mode, a standby mode and an off mode that uses less power than the standby mode. The NVM system includes an NVM array that includes NVM cells and NVM peripheral circuitry. Each NVM cell includes a control gate. A controller is coupled to the NVM array, applies a voltage to the control gates and power to the peripheral circuitry during the standby mode, and applies an off-mode voltage to the control gates and removes power from the NVM peripheral circuitry during the off mode. | 10-30-2014 |
20150035034 | SPLIT GATE NON-VOLATILE MEMORY CELL - A method of making a semiconductor structure uses a substrate having a background doping of a first type. A gate structure has a gate dielectric on the substrate and a select gate layer on the gate dielectric. Implanting is performed into a first portion of the substrate adjacent to a first end with dopants of a second type. The implanting is prior to any dopants being implanted into the background doping of the first portion which becomes a first doped region of the second type. An NVM gate structure has a select gate, a storage layer having a first portion over the first doped region, and a control gate over the storage layer. Implanting at a non-vertical angle with dopants of the first type forms a deep doped region under the select gate. Implanting with dopants of the second type forms a source/drain extension. | 02-05-2015 |
20150054044 | Method to Form a Polysilicon Nanocrystal Thin Film Storage Bitcell within a High K Metal Gate Platform Technology Using a Gate Last Process to Form Transistor Gates - A process integration is disclosed for fabricating non-volatile memory (NVM) cells ( | 02-26-2015 |
20150054049 | INTEGRATED SPLIT GATE NON-VOLATILE MEMORY CELL AND LOGIC STRUCTURE - A method of making a semiconductor structure includes forming a select gate and a charge storage layer in an NVM region. A spacer select gate is formed by depositing a conformal layer followed by an etch back. A patterned etch results in leaving a portion of the charge storage layer over the select gate. A dummy gate structure formed in a logic region has a dummy gate surrounded by an insulating layer. Performing chemical polishing results in the top surface of the charge storage layer being coplanar with top surface of the dummy gate structure. Replacing a portion of the dummy gate structure with a metal logic gate which includes a further chemical mechanical polishing results in the top surface of the charge storage layer being coplanar with the metal logic gate. | 02-26-2015 |
20150054050 | INTEGRATED SPLIT GATE NON-VOLATILE MEMORY CELL AND LOGIC DEVICE - A method of making a semiconductor structure includes forming a select gate and a charge storage layer in an NVM region. A control gate is formed by depositing a conformal layer followed by an etch back. A patterned etch results in leaving a portion of the charge storage layer over the select gate and under the control gate and to remove the charge storage layer from the logic region. A logic gate structure formed in a logic region has a metal work function surrounded by an insulating layer. | 02-26-2015 |
20150069490 | Methods For Forming Contact Landing Regions In Split-Gate Non-Volatile Memory (NVM) Cell Arrays - Methods and related structures are disclosed for forming contact landing regions in split-gate NVM (non-volatile memory) systems. A dummy select gate structure is formed while also forming select gates for split-gate NVM cells. A control gate layer is formed over the select gates and the dummy select gate structure, as well as an intervening charge storage layer. The control gate material will fill in gaps between the select gate material and the dummy select gate material. A non-patterned spacer etch is then used to etch the control gate layer to form a contact landing region associated with the dummy select gate structure while also forming spacer control gates for the split-gate NVM cells. The disclosed embodiments provide improved (e.g., more planar) contact landing regions without requiring additional processing steps and without increasing the pitch of the resulting NVM cell array. | 03-12-2015 |
20150069524 | Method of Forming Different Voltage Devices with High-K Metal Gate - A method and apparatus are described for integrating high voltage (HV) transistor devices and medium voltage or dual gate oxide (DGO) transistor devices with low voltage (LV) core transistor devices on a single substrate, where each high voltage transistor device ( | 03-12-2015 |
20150072489 | NON-VOLATILE MEMORY (NVM) CELL AND HIGH-K AND METAL GATE TRANSISTOR INTEGRATION - A method of making a semiconductor device includes depositing a layer of polysilicon in a non-volatile memory (NVM) region and a logic region of a substrate. The layer of polysilicon is patterned into a gate in the NVM region while the layer of polysilicon remains in the logic region. A memory cell is formed including the gate in the NVM region while the layer of polysilicon remains in the logic region. The layer of polysilicon in the logic region is removed and the substrate is implanted to form a well region in the logic region after the memory cell is formed. A layer of gate material is deposited in the logic region. The layer of gate material is patterned into a logic gate in the logic region. | 03-12-2015 |