Patent application number | Description | Published |
20080315430 | NANOWIRE VIAS - A method of fabricating an integrated circuit including arranging a nanowire with a first end portion thereof at a first contact surface of a first electrical contact and with a second end portion sticking up from the first contact surface, and embedding at least part of the nanowire in dielectric material. | 12-25-2008 |
20090199043 | ERROR CORRECTION IN AN INTEGRATED CIRCUIT WITH AN ARRAY OF MEMORY CELLS - An integrated circuit includes an array of memory cells, and an error correction code circuit configured to correct errors in data read from the array based at least in part on a map that identifies locations of erratic memory cells in the array. | 08-06-2009 |
20090212438 | INTEGRATED CIRCUIT DEVICE COMPRISING CONDUCTIVE VIAS AND METHOD OF MAKING THE SAME - A semiconductor substrate for an integrated circuit device comprises at least one insulating substrate region being formed of a cohesive insulating material. The insulating substrate region includes at least two conductive vias extending at least between a first surface and a second surface of the insulating substrate region. | 08-27-2009 |
20090256258 | SEMICONDUCTOR CHIP WITH INTEGRATED VIA - An integrated circuit with a substrate with a lower and an upper surface is described. A via extends between the upper and the lower surface of the substrate. The via contains a conductive filling material that comprises carbon. | 10-15-2009 |
20090268513 | MEMORY DEVICE WITH DIFFERENT TYPES OF PHASE CHANGE MEMORY - A memory includes a first memory device including an array of phase changing memory cells. The first memory device is of a first memory type. The integrated circuit includes a second memory device including an array of phase changing memory cells. The second memory device is of a second memory type that is different than the first memory type. The first and second memory devices are packaged together into a single memory device. | 10-29-2009 |
20090321706 | Resistive Memory Devices with Improved Resistive Changing Elements - An integrated circuit includes a memory cell with a resistance changing memory element. The resistance changing memory element includes a first electrode, a second electrode, and a resistivity changing material disposed between the first and second electrodes, where the resistivity changing material is configured to change resistive states in response to application of a voltage or current to the first and second electrodes. In addition, at least one of the first electrode and the second electrode comprises an insulator material including a self-assembled electrically conductive element formed within the insulator material. The self-assembled electrically conductive element formed within the insulator material remains stable throughout the operation of switching the resistivity changing material to different resistive states. | 12-31-2009 |
20100084741 | Integrated Circuit - According to an embodiment, an integrated circuit including a plurality of resistance changing memory cells is disclosed. Each memory cell includes a first electrode, a second electrode and resistance changing memory element arranged between the first electrode and the second electrode. A front surface area of an end section of the first electrode that faces the resistance changing memory element is smaller than a front surface area of an end section of the second electrode that faces the resistance changing memory element. | 04-08-2010 |
20120243337 | P-/METAL FLOATING GATE NON-VOLATILE STORAGE ELEMENT - Non-volatile storage elements having a P−/metal floating gate are disclosed herein. The floating gate may have a P− region near the tunnel oxide, and may have a metal region near the control gate. A P− region near the tunnel oxide helps provide good data retention. A metal region near the control gate helps to achieve a good coupling ratio between the control gate and floating gate. Therefore, programming of non-volatile storage elements is efficient. Also, erasing the non-volatile storage elements may be efficient. In some embodiments, having a P− region near the tunnel oxide (as opposed to a strongly doped p-type semiconductor) may improve erase efficiency relative to P+. | 09-27-2012 |
Patent application number | Description | Published |
20080296557 | Semiconductor Power Switch and Method for Producing a Semiconductor Power Switch - A semiconductor power switch and method is disclosed. In one embodiment the semiconductor power switch has a source contact, a drain contact, a semiconductor structure which is provided between the source contact and the drain contact, and a gate which can be used to control a current flow through the semiconductor structure between the source contact and the drain contact. The semiconductor structure has a plurality of nanowires which are connected in parallel and are arranged in such a manner that each nanowire forms an electrical connection between the source contact and the drain contact. | 12-04-2008 |
20090108248 | INTEGRATED CIRCUIT INCLUDING DOPED SEMICONDUCTOR LINE HAVING CONDUCTIVE CLADDING - An integrated circuit includes an array of memory cells and a doped semiconductor line formed in a semiconductor substrate. The doped semiconductor line is coupled to a row of memory cells. The integrated circuit includes conductive cladding contacting the doped semiconductor line. | 04-30-2009 |
20110227020 | BOTTOM ELECTRODES FOR USE WITH METAL OXIDE RESISTIVITY SWITCHING LAYERS - In a first aspect, a metal-insulator-metal (MIM) stack is provided that includes (1) a first conductive layer comprising a silicon-germanium (SiGe) alloy; (2) a resistivity-switching layer comprising a metal oxide layer formed above the first conductive layer; and (3) a second conductive layer formed above the resistivity-switching layer. A memory cell may be formed from the MIM stack. Numerous other aspects are provided. | 09-22-2011 |
20110227028 | BOTTOM ELECTRODES FOR USE WITH METAL OXIDE RESISTIVITY SWITCHING LAYERS - In a first aspect, an MIM stack is provided that includes (1) a first conductive layer comprising a first metal-silicide layer and a second metal-silicide layer; (2) a resistivity-switching layer comprising a metal oxide layer formed above the first conductive layer; and (3) a second conductive layer formed above the resistivity-switching layer. A memory cell may be formed from the MIM stack. Numerous other aspects are provided. | 09-22-2011 |
20110310653 | Memory Cell With Resistance-Switching Layers - A memory device in a 3-D read and write memory includes memory cells. Each memory cell includes a resistance-switching memory element (RSME) in series with a steering element. The RSME has first and second resistance-switching layers on either side of a conductive intermediate layer, and first and second electrodes at either end of the RSME. The first and second resistance-switching layers can both have a bipolar or unipolar switching characteristic. In a set or reset operation of the memory cell, an electric field is applied across the first and second electrodes. An ionic current flows in the resistance-switching layers, contributing to a switching mechanism. An electron flow, which does not contribute to the switching mechanism, is reduced due to scattering by the conductive intermediate layer, to avoid damage to the steering element. Particular materials and combinations of materials for the different layers of the RSME are provided. | 12-22-2011 |
20110310654 | Memory Cell With Resistance-Switching Layers And Lateral Arrangement - A memory device in a 3-D read and write memory includes memory cells. Each memory cell includes a resistance-switching memory element (RSME). The RSME has first and second resistance-switching layers on either side of a conductive intermediate layer, and first and second electrodes at either end of the RSME. The layers can be provided in a lateral arrangement, such as an end-to-end, face-to-face, L-shaped or U-shaped arrangement. In a set or reset operation of the memory cell, an electric field is applied across the first and second electrodes. An ionic current flows in the resistance-switching layers, contributing to a switching mechanism. An electron flow, which does not contribute to the switching mechanism, is reduced due to scattering by the conductive intermediate layer, to avoid damage to the steering element. | 12-22-2011 |
20110310655 | Composition Of Memory Cell With Resistance-Switching Layers - A memory device in a 3-D read and write memory includes memory cells. Each memory cell includes a resistance-switching memory element (RSME) in series with a steering element. The RSME has first and second resistance-switching layers on either side of a conductive intermediate layer, and first and second electrodes at either end of the RSME. The first and second resistance-switching layers can both have a bipolar or unipolar switching characteristic. In a set or reset operation of the memory cell, an ionic current flows in the resistance-switching layers, contributing to a switching mechanism. An electron flow, which does not contribute to the switching mechanism, is reduced due to scattering by the conductive intermediate layer, to avoid damage to the steering element. Particular materials and combinations of materials for the different layers of the RSME are provided. | 12-22-2011 |
20110310656 | Memory Cell With Resistance-Switching Layers Including Breakdown Layer - A memory device in a 3-D read and write memory includes memory cells. Each memory cell includes a resistance-switching memory element (RSME) in series with a steering element. The RSME has a resistance-switching layer, a conductive intermediate layer, and first and second electrodes at either end of the RSME. A breakdown layer is electrically between, and in series with, the second electrode and the intermediate layer. The breakdown layer maintains a resistance of at least about 1-10 MΩ while in a conductive state. In a set or reset operation of the memory cell, an ionic current flows in the resistance-switching layers, contributing to a switching mechanism. An electron flow, which does not contribute to the switching mechanism, is reduced due to scattering by the conductive intermediate layer, to avoid damage to the steering element. Particular materials and combinations of materials for the different layers of the RSME are provided. | 12-22-2011 |
20130126821 | BOTTOM ELECTRODES FOR USE WITH METAL OXIDE RESISTIVITY SWITCHING LAYERS - In a first aspect, a metal-insulator-metal (“MIM”) stack is provided that includes a first conductive layer, a resistivity-switching layer having a metal oxide layer formed above the first conductive layer, a material layer between the first conductive layer and the resistivity-switching layer, and a second conductive layer above the resistivity-switching layer. The first conductive layer includes a multi-layer metal-silicide stack, and the material layer has a Gibbs free energy of formation per O between about −3 and −6 eV. A memory cell may be formed from the MIM stack. Numerous other aspects are provided. | 05-23-2013 |
Patent application number | Description | Published |
20110140064 | CARBON/TUNNELING-BARRIER/CARBON DIODE - A carbon/tunneling-barrier/carbon diode and method for forming the same are disclosed. The carbon/tunneling-barrier/carbon may be used as a steering element in a memory array. Each memory cell in the memory array may include a reversible resistivity-switching element and a carbon/tunneling-barrier/carbon diode as the steering element. The tunneling-barrier may include a semiconductor or an insulator. Thus, the diode may be a carbon/semiconductor/carbon diode. The semiconductor in the diode may be intrinsic or doped. The semiconductor may be depleted when the diode is under equilibrium conditions. For example, the semiconductor may be lightly doped such that the depletion region extends from one end of the semiconductor region to the other end. The diode may be a carbon/insulator/carbon diode. | 06-16-2011 |
20110204316 | Structure And Fabrication Method For Resistance-Change Memory Cell In 3-D Memory - A memory device in a 3-D read and write memory includes a resistance-changing layer, and a local contact resistance in series with, and local to, the resistance-changing layer. The local contact resistance is established by a junction between a semiconductor layer and a metal layer. Further, the local contact resistance has a specified level of resistance according to a doping concentration of the semiconductor and a barrier height of the junction. A method for fabricating such a memory device is also presented. | 08-25-2011 |
20110204474 | MEMORY CELL WITH SILICON-CONTAINING CARBON SWITCHING LAYER AND METHODS FOR FORMING THE SAME - In a first aspect, a method of forming a memory cell is provided that includes (1) forming a metal-insulator-metal (MIM) stack, the MIM stack including (a) a first conductive carbon layer; (b) a low-hydrogen, silicon-containing carbon layer above the first conductive carbon layer; and (c) a second conductive carbon layer above the low-hydrogen, silicon-containing carbon layer; and (2) forming a steering element coupled to the MIM stack. Numerous other aspects are provided. | 08-25-2011 |
20110227024 | RESISTANCE-SWITCHING MEMORY CELL WITH HEAVILY DOPED METAL OXIDE LAYER - A non-volatile resistance-switching memory element includes a resistance-switching element formed from a metal oxide layer having a dopant which is provided at a relatively high concentration such as 10% or greater. Further, the dopant is a cation having a relatively large ionic radius such as 70 picometers or greater, such as Magnesium, Chromium, Calcium, Scandium or Yttrium. A cubic fluorite phase lattice may be formed in the metal oxide even at room temperature so that switching power may be reduced. The memory element may be pillar-shaped, extending between first and second electrodes and being in series with a steering element such as a diode. The metal oxide layer may be deposited at the same time as the dopant. Or, using atomic layer deposition, an oxide of a first metal can be deposited, followed by an oxide of a second metal, followed by annealing to cause intermixing, in repeated cycles. | 09-22-2011 |
20110227026 | NON-VOLATILE STORAGE WITH METAL OXIDE SWITCHING ELEMENT AND METHODS FOR FABRICATING THE SAME - Non-volatile storage elements having a reversible resistivity-switching element and techniques for fabricating the same are disclosed herein. The reversible resistivity-switching element may be formed by depositing an oxygen diffusion resistant material (e.g., heavily doped Si, W, WN) over the top electrode. A trap passivation material (e.g., fluorine, nitrogen, hydrogen, deuterium) may be incorporated into one or more of the bottom electrode, a metal oxide region, or the top electrode of the reversible resistivity-switching element. One embodiment includes a reversible resistivity-switching element having a bi-layer capping layer between the metal oxide and the top electrode. Fabricating the device may include depositing (un-reacted) titanium and depositing titanium oxide in situ without air brake. One embodiment includes incorporating titanium into the metal oxide of the reversible resistivity-switching element. The titanium might be implanted into the metal oxide while depositing the metal oxide, or after deposition of the metal oxide. Sub-plantation may be used to create a titanium region between two metal oxide regions. | 09-22-2011 |
20110229990 | FORMING AND TRAINING PROCESSES FOR RESISTANCE-CHANGE MEMORY CELL - During the manufacture of a set of non-volatile resistance-switching memory elements, a forming process is performed in which a voltage is applied over forming period until a conductive filament is formed in a resistance-switching layer. A heat source at a temperature of 50° C. to 150° C. is applied to expedite the forming process while reducing the required magnitude of the applied voltage. Manufacturing time and reliability are improved. After the forming process, an expedited training process can be performed in which a fixed number of cycles of voltage pulses are applied without verifying the memory elements. Subsequently, the memory elements are verified by determining their read current in an evaluation. Another fixed number of cycles of voltage pulses is applied without verifying the memory elements, if the memory elements do not pass the evaluation. | 09-22-2011 |
20110254126 | MEMORY CELL WITH CARBON SWITCHING MATERIAL HAVING A REDUCED CROSS-SECTIONAL AREA AND METHODS FOR FORMING THE SAME - In a first aspect, a method of forming a metal-insulator-metal (“MIM”) stack is provided, the method including: (1) forming a dielectric material having an opening and a first conductive carbon layer within the opening; (2) forming a spacer in the opening; (3) forming a carbon-based switching material on a sidewall of the spacer; and (4) forming a second conductive carbon layer above the carbon-based switching material. A ratio of a cross sectional area of the opening in the dielectric material to a cross sectional area of the carbon-based switching material on the sidewall of the spacer is at least 5. Numerous other aspects are provided. | 10-20-2011 |
20120091418 | BIPOLAR STORAGE ELEMENTS FOR USE IN MEMORY CELLS AND METHODS OF FORMING THE SAME - In some embodiments, a memory cell is provided that includes (1) a bipolar storage element formed from a metal-insulator-metal (MIM) stack including (a) a first conductive layer; (b) a reversible resistivity switching (RRS) layer formed above the first conductive layer; (c) a metal/metal oxide layer stack formed above the first conductive layer; and (d) a second conductive layer formed above the RRS layer and the metal/metal oxide layer stack; and (2) a steering element coupled to the storage element. Numerous other aspects are provided. | 04-19-2012 |
20130221311 | TRAP PASSIVATION IN MEMORY CELL WITH METAL OXIDE SWITCHING ELEMENT - Non-volatile storage elements having a reversible resistivity-switching element and techniques for fabricating the same are disclosed herein. The reversible resistivity-switching element may be formed by depositing an oxygen diffusion resistant material (e.g., heavily doped Si, W, WN) over the top electrode. A trap passivation material (e.g., fluorine, nitrogen, hydrogen, deuterium) may be incorporated into one or more of the bottom electrode, a metal oxide region, or the top electrode of the reversible resistivity-switching element. One embodiment includes a reversible resistivity-switching element having a bi-layer capping layer between the metal oxide and the top electrode. Fabricating the device may include depositing (un-reacted) titanium and depositing titanium oxide in situ without air break. One embodiment includes incorporating titanium into the metal oxide of the reversible resistivity-switching element. The titanium might be implanted into the metal oxide while depositing the metal oxide, or after deposition of the metal oxide. | 08-29-2013 |
20130234099 | NON-VOLATILE STORAGE WITH METAL OXIDE SWITCHING ELEMENT AND METHODS FOR FABRICATING THE SAME - Non-volatile storage elements having a reversible resistivity-switching element and techniques for fabricating the same are disclosed herein. The reversible resistivity-switching element may be formed by depositing an oxygen diffusion resistant material (e.g., heavily doped Si, W, WN) over the top electrode. A trap passivation material (e.g., fluorine, nitrogen, hydrogen, deuterium) may be incorporated into one or more of the bottom electrode, a metal oxide region, or the top electrode of the reversible resistivity-switching element. One embodiment includes a reversible resistivity-switching element having a bi-layer capping layer between the metal oxide and the top electrode. Fabricating the device may include depositing (un-reacted) titanium and depositing titanium oxide in situ without air break. One embodiment includes incorporating titanium into the metal oxide of the reversible resistivity-switching element. The titanium might be implanted into the metal oxide while depositing the metal oxide, or after deposition of the metal oxide. | 09-12-2013 |