Patent application number | Description | Published |
20110127485 | KEYHOLE-FREE SLOPED HEATER FOR PHASE CHANGE MEMORY - Subject matter disclosed herein relates to a method of manufacturing a semiconductor integrated circuit device, and more particularly to a method of fabricating a phase change memory device. | 06-02-2011 |
20130214238 | Method for Forming Metal Oxides and Silicides in a Memory Device - Embodiments of the invention generally relate to memory devices and methods for fabricating such memory devices. In one embodiment, a method for fabricating a resistive switching memory device includes depositing a metallic layer on a lower electrode disposed on a substrate and exposing the metallic layer to an activated oxygen source while heating the substrate to an oxidizing temperature within a range from about 300° C. to about 600° C. and forming a metal oxide layer from an upper portion of the metallic layer during an oxidation process. The lower electrode contains a silicon material and the metallic layer contains hafnium or zirconium. Subsequent to the oxidation process, the method further includes heating the substrate to an annealing temperature within a range from greater than 600° C. to about 850° C. while forming a metal silicide layer from a lower portion of the metallic layer during a silicidation process. | 08-22-2013 |
20130221315 | Memory Cell Having an Integrated Two-Terminal Current Limiting Resistor - A resistor structure incorporated into a resistive switching memory cell with improved performance and lifetime is provided. The resistor structure may be a two-terminal structure designed to reduce the maximum current flowing through a memory cell. A method is also provided for making such a memory cell. The method includes depositing a resistor structure and depositing a variable resistance layer of a resistive switching memory cell of the memory cell, where the resistor structure is disposed in series with the variable resistance layer to limit the switching current of the memory cell. The incorporation of the resistor structure is very useful in obtaining desirable levels of switching currents that meet the switching specification of various types of memory cells. The memory cells may be formed as part of a high-capacity nonvolatile memory integrated circuit, which can be used in various electronic devices. | 08-29-2013 |
20130286726 | KEYHOLE-FREE SLOPED HEATER FOR PHASE CHANGE MEMORY - Subject matter disclosed herein relates to a method of manufacturing a semiconductor integrated circuit device, and more particularly to a method of fabricating a phase change memory device. | 10-31-2013 |
20130334490 | Transition Metal Oxide Bilayers - Embodiments of the invention include nonvolatile memory elements and memory devices comprising the nonvolatile memory elements. Methods for forming the nonvolatile memory elements are also disclosed. The nonvolatile memory element comprises a first electrode layer, a second electrode layer, and a plurality of layers of an oxide disposed between the first and second electrode layers. One of the oxide layers has linear resistance and substoichiometric composition, and the other oxide layer has bistable resistance and near-stoichiometric composition. Preferably, the sum of the two oxide layer thicknesses is between about 20 Å and about 100 Å, and the oxide layer with bistable resistance has a thickness between about 25% and about 75% of the total thickness. In one embodiment, the oxide layers are formed using reactive sputtering in an atmosphere with controlled flows of argon and oxygen. | 12-19-2013 |
20130337606 | Nonvolatile Memory Device Using a Tunnel Nitride As A Current Limiter Element - Embodiments of the invention generally include a method of forming a nonvolatile memory device that contains a resistive switching memory element that has an improved device switching performance and lifetime, due to the addition of a current limiting component disposed therein. In one embodiment, the current limiting component comprises a resistive material that is configured to improve the switching performance and lifetime of the resistive switching memory element. The electrical properties of the current limiting layer are configured to lower the current flow through the variable resistance layer during the logic state programming steps (i.e., “set” and “reset” steps) by adding a fixed series resistance in the resistive switching memory element found in the nonvolatile memory device. In one embodiment, the current limiting component comprises a tunnel nitride that is a current limiting material that is disposed within a resistive switching memory element in a nonvolatile resistive switching memory device. | 12-19-2013 |
20140038380 | Multifunctional Electrode - A nonvolatile memory element is disclosed comprising a first electrode, a near-stoichiometric metal oxide memory layer having bistable resistance, and a second electrode in contact with the near-stoichiometric metal oxide memory layer. At least one electrode is a resistive electrode comprising a sub-stoichiometric transition metal nitride or oxynitride, and has a resistivity between 0.1 and 10 Ωcm. The resistive electrode provides the functionality of an embedded current-limiting resistor and also serves as a source and sink of oxygen vacancies for setting and resetting the resistance state of the metal oxide layer. Novel fabrication methods for the second electrode are also disclosed. | 02-06-2014 |
20140117303 | Resistive Random Access Memory Cells Having METAL ALLOY Current Limiting layers - Provided are semiconductor devices, such as resistive random access memory (ReRAM) cells, that include current limiting layers formed from alloys of transition metals. Some examples of such alloys include chromium containing alloys that may also include nickel, aluminum, and/or silicon. Other examples include tantalum and/or titanium containing alloys that may also include a combination of silicon and carbon or a combination of aluminum and nitrogen. These current limiting layers may have resistivities of at least about 1 Ohm-cm. This resistivity level is maintained even when the layers are subjected to strong electrical fields and/or high temperature processing. In some embodiments, the breakdown voltage of a current limiting layer is at least about 8V. The high resistivity of the layers allows scaling down the size of the semiconductor devices including these layers while maintaining their performance. | 05-01-2014 |
20140175354 | SEQUENTIAL ATOMIC LAYER DEPOSITION OF ELECTRODES AND RESISTIVE SWITCHING COMPONENTS - Provided are methods of forming nonvolatile memory elements using atomic layer deposition techniques, in which at least two different layers of a memory element are deposited sequentially and without breaking vacuum in a deposition chamber. This approach may be used to prevent oxidation of various materials used for electrodes without a need for separate oxygen barrier layers. A combination of signal lines and resistive switching layers may be used to cap the electrodes and to minimize their oxidation. As such, fewer layers are needed in a memory element. Furthermore, atomic layer deposition allows more precise control of electrode thicknesses. In some embodiments, a thickness of an electrode may be less than 50 Angstroms. Overall, atomic layer deposition of electrodes and resistive switching layers lead to smaller thicknesses of entire memory elements making them more suitable for low aspect ratio features of advanced nodes. | 06-26-2014 |
20140175355 | Carbon Doped Resistive Switching Layers - Provided are carbon doped resistive switching layers, resistive random access memory (ReRAM) cells including these layers, as well as methods of forming thereof. Carbon doping of metal containing materials creates defects in these materials that allow forming and breaking conductive paths as evidenced by resistive switching. Relative to many conventional dopants, carbon has a lower diffusivity in many suitable base materials. As such, these carbon doped materials exhibit structural stability and consistent resistive switching over many operating cycles. Resistive switching layers may include as much as 30 atomic percent of carbon, making the dopant control relatively simple and flexible. Furthermore, carbon doping has acceptor characteristics resulting in a high resistivity and low switching currents, which are very desirable for ReRAM applications. Carbon doped metal containing layer may be formed from metalorganic precursors at temperatures below saturation ranges of atomic layer deposition. | 06-26-2014 |
20140175356 | Resistive Random Access Memory Access Cells Having Thermally Isolating Structures - Provided are resistive random access memory (ReRAM) cells including resistive switching layers and thermally isolating structures for limiting heat dissipation from the switching layers during operation. Thermally isolating structures may be positioned within a stack or adjacent to the stack. For example, a stack may include one or two thermally isolating structures. A thermally isolating structure may directly interface with a switching layer or may be separated by, for example, an electrode. Thermally isolating structures may be formed from materials having a thermal conductivity of less than 1 W/m*K, such as porous silica and mesoporous titanium oxide. A thermally isolating structure positioned in series with a switching layer generally has a resistance less than the low resistance state of the switching layer. A thermally isolating structure positioned adjacent to a switching layer may have a resistance greater than the high resistance state of the switching layer. | 06-26-2014 |
20140175360 | Bilayered Oxide Structures for ReRAM Cells - Provided are resistive random access memory (ReRAM) cells having bi-layered metal oxide structures. The layers of a bi-layered structure may have different compositions and thicknesses. Specifically, one layer may be thinner than the other layer, sometimes as much as 5 to 20 times thinner. The thinner layer may be less than 30 Angstroms thick or even less than 10 Angstroms thick. The thinner layer is generally more oxygen rich than the thicker layer. Oxygen deficiency of the thinner layer may be less than 5 atomic percent or even less than 2 atomic percent. In some embodiments, a highest oxidation state metal oxide may be used to form a thinner layer. The thinner layer typically directly interfaces with one of the electrodes, such as an electrode made from doped polysilicon. Combining these specifically configured layers into the bi-layered structure allows improving forming and operating characteristics of ReRAM cells. | 06-26-2014 |
20140175361 | Resistive Switching Layers Including Hf-Al-O - Provided are resistive random access memory (ReRAM) cells having switching layers that include hafnium, aluminum, oxygen, and nitrogen. The composition of such layers is designed to achieve desirable performance characteristics, such as low current leakage as well as low and consistent switching currents. In some embodiments, the concentration of nitrogen in a switching layer is between about 1 and 20 atomic percent or, more specifically, between about 2 and 5 atomic percent. Addition of nitrogen helps to control concentration and distribution of defects in the switching layer. Also, nitrogen as well as a combination of two metals helps with maintaining this layer in an amorphous state. Excessive amounts of nitrogen reduce defects in the layer such that switching characteristics may be completely lost. The switching layer may be deposited using various techniques, such as sputtering or atomic layer deposition (ALD). | 06-26-2014 |
20140175362 | Limited Maximum Fields of Electrode-Switching Layer Interfaces in Re-RAM Cells - Provided are ReRAM cells, each having at least one interface between an electrode and a resistive switching layers with a maximum field value of less than 0.25. The electrode materials forming such interfaces include tantalum nitrides doped with lanthanum, aluminum, erbium yttrium, or terbium (e.g., Ta | 06-26-2014 |
20140175363 | Forming Nonvolatile Memory Elements By Diffusing Oxygen Into Electrodes - Provided are methods of forming nonvolatile memory elements including resistance switching layers. A method involves diffusing oxygen from a precursor layer to one or more reactive electrodes by annealing. At least one electrode in a memory element is reactive, while another may be inert. The precursor layer is converted into a resistance switching layer as a result of this diffusion. The precursor layer may initially include a stoichiometric oxide that generally does not exhibit resistance switching characteristics until oxygen vacancies are created. Metals forming such oxides may be more electronegative than metals forming a reactive electrode. The reactive electrode may have substantially no oxygen at least prior to annealing. Annealing may be performed at 250-400° C. in the presence of hydrogen. These methods simplify process control and may be used to form nonvolatile memory elements including resistance switching layers less than 20 Angstroms thick. | 06-26-2014 |
20140175364 | RADIATION ENHANCED RESISTIVE SWITCHING LAYERS - Provided are radiation enhanced resistive switching layers, resistive random access memory (ReRAM) cells including these layers, as well as methods of forming these layers and cells. Radiation creates defects in resistive switching materials that allow forming and breaking conductive paths in these materials thereby improving their resistive switching characteristics. For example, ionizing radiation may break chemical bonds in various materials used for such a layer, while non-ionizing radiation may form electronic traps. Radiation power, dozing, and other processing characteristics can be controlled to generate a distribution of defects within the resistive switching layer. For example, an uneven distribution of defects through the thickness of a layer may help with lowering switching voltages and/or currents. Radiation may be performed before or after thermal annealing, which may be used to control distribution of radiation created defects and other types of defects in resistive switching layers. | 06-26-2014 |
20140175367 | Materials for Thin Resisive Switching Layers of Re-RAM Cells - Provided are resistive random access memory (ReRAM) cells that include thin resistive switching layers. In some embodiments, the resistive switching layers have a thickness of less than about 50 Angstroms and even less than about 30 Angstroms. The resistive switching characteristics of such thin layers are maintained by controlling their compositions and using particular fabrication techniques. Specifically, low oxygen vacancy metal oxides, such as tantalum oxide, may be used. The concentration of oxygen vacancies may be less than 5 atomic percent. In some embodiments, the resistive switching layers also include nitrogen and. For example, compositions of some specific resistive switching layers may be represented by Ta | 06-26-2014 |
20140177315 | Multi-Level Memory Array Having Resistive Elements For Multi-Bit Data Storage - A resistor array for multi-bit data storage without the need to increase the size of a memory chip or scale down the feature size of a memory cell contained within the memory chip is provided. The resistor array incorporates a number of discrete resistive elements to be selectively connected, in different series combinations, to at least one memory cell or memory device. In one configuration, by connecting each memory cell or device with at least one resistor array, a resistive switching layer found in the resistive switching memory element of the connected memory device is capable of being at multiple resistance states for storing multiple bits of digital information. During device programming operations, when a desired series combination of the resistive elements within the resistor array is selected, the resistive switching layer in the connected memory device can be in a desired resistance state. | 06-26-2014 |
20140192585 | Resistive Random Access Memory Cell Having Three or More Resistive States - Provided are resistive random access memory (ReRAM) cells, each having three or more resistive states and being capable of storing multiple bits of data, as well as methods of fabricating and operating such ReRAM cells. Such ReRAM cells or, more specifically, their resistive switching layer have wide range of resistive states and are capable of being very conductive (e.g., about 1 kOhm) in one state and very resistive (e.g., about 1 MOhm) in another state. In some embodiments, a resistance ratio between resistive states may be between 10 and 1,000 even up to 10,000. The resistive switching layers also allow establishing stable and distinct intermediate resistive states that may be assigned different data values. These layers may be configured to switching between their resistive states using fewer programming pulses than conventional systems by using specific materials, switching pluses, and resistive state threshold. | 07-10-2014 |
20140217348 | Transition Metal Oxide Bilayers - Embodiments of the invention include nonvolatile memory elements and memory devices comprising the nonvolatile memory elements. Methods for forming the nonvolatile memory elements are also disclosed. The nonvolatile memory element comprises a first electrode layer, a second electrode layer, and a plurality of layers of an oxide disposed between the first and second electrode layers. One of the oxide layers has linear resistance and substoichiometric composition, and the other oxide layer has bistable resistance and near-stoichiometric composition. Preferably, the sum of the two oxide layer thicknesses is between about 20 Å and about 100 Å, and the oxide layer with bistable resistance has a thickness between about 25% and about 75% of the total thickness. In one embodiment, the oxide layers are formed using reactive sputtering in an atmosphere with controlled flows of argon and oxygen. | 08-07-2014 |
20140315369 | Resistive Random Access Memory Cells Having METAL ALLOY Current Limiting layers - Provided are semiconductor devices, such as resistive random access memory (ReRAM) cells, that include current limiting layers formed from alloys of transition metals. Some examples of such alloys include chromium containing alloys that may also include nickel, aluminum, and/or silicon. Other examples include tantalum and/or titanium containing alloys that may also include a combination of silicon and carbon or a combination of aluminum and nitrogen. These current limiting layers may have resistivities of at least about 1 Ohm-cm. This resistivity level is maintained even when the layers are subjected to strong electrical fields and/or high temperature processing. In some embodiments, the breakdown voltage of a current limiting layer is at least about 8V. The high resistivity of the layers allows scaling down the size of the semiconductor devices including these layers while maintaining their performance. | 10-23-2014 |
20140319443 | Sequential Atomic Layer Deposition of Electrodes and Resistive Switching Components - Provided are methods of forming nonvolatile memory elements using atomic layer deposition techniques, in which at least two different layers of a memory element are deposited sequentially and without breaking vacuum in a deposition chamber. This approach may be used to prevent oxidation of various materials used for electrodes without a need for separate oxygen barrier layers. A combination of signal lines and resistive switching layers may be used to cap the electrodes and to minimize their oxidation. As such, fewer layers are needed in a memory element. Furthermore, atomic layer deposition allows more precise control of electrode thicknesses. In some embodiments, a thickness of an electrode may be less than 50 Angstroms. Overall, atomic layer deposition of electrodes and resistive switching layers lead to smaller thicknesses of entire memory elements making them more suitable for low aspect ratio features of advanced nodes. | 10-30-2014 |
20140361235 | Nonvolatile Resistive Memory Element With A Metal Nitride Containing Switching Layer - A nonvolatile resistive memory element has a novel variable resistance layer that includes a metal nitride, a metal oxide-nitride, a two-metal oxide-nitride, or a multilayer stack thereof. One method of forming the novel variable resistance layer comprises an interlayer deposition procedure, in which metal oxide layers are interspersed with metal nitride layers and then converted into a substantially homogeneous layer by an anneal process. Another method of forming the novel variable resistance layer comprises an intralayer deposition procedure, in which various ALD processes are sequentially interleaved to form a metal oxide-nitride layer. Alternatively, a metal oxide is deposited, nitridized, and annealed to form the variable resistance layer or a metal nitride is deposited, oxidized, and annealed to form the variable resistance layer. | 12-11-2014 |
20140363920 | Atomic Layer Deposition of Metal Oxides for Memory Applications - Embodiments of the invention generally relate to nonvolatile memory devices and methods for manufacturing such memory devices. The methods for forming improved memory devices, such as a ReRAM cells, provide optimized, atomic layer deposition (ALD) processes for forming a metal oxide film stack which contains at least one hard metal oxide film (e.g., metal is completely oxidized or substantially oxidized) and at least one soft metal oxide film (e.g., metal is less oxidized than hard metal oxide). The soft metal oxide film is less electrically resistive than the hard metal oxide film since the soft metal oxide film is less oxidized or more metallic than the hard metal oxide film. In one example, the hard metal oxide film is formed by an ALD process utilizing ozone as the oxidizing agent while the soft metal oxide film is formed by another ALD process utilizing water vapor as the oxidizing agent. | 12-11-2014 |
20140374240 | MULTIFUNCTIONAL ELECTRODE - A nonvolatile memory element is disclosed comprising a first electrode, a near-stoichiometric metal oxide memory layer having bistable resistance, and a second electrode in contact with the near-stoichiometric metal oxide memory layer. At least one electrode is a resistive electrode comprising a sub-stoichiometric transition metal nitride or oxynitride, and has a resistivity between 0.1 and 10Ω cm. The resistive electrode provides the functionality of an embedded current-limiting resistor and also serves as a source and sink of oxygen vacancies for setting and resetting the resistance state of the metal oxide layer. Novel fabrication methods for the second electrode are also disclosed. | 12-25-2014 |
20150123071 | Method for Forming Metal Oxides and Silicides in a Memory Device - Embodiments of the invention generally relate to memory devices and methods for fabricating such memory devices. In one embodiment, a method for fabricating a resistive switching memory device includes depositing a metallic layer on a lower electrode disposed on a substrate and exposing the metallic layer to an activated oxygen source while heating the substrate to an oxidizing temperature within a range from about 300° C. to about 600° C. and forming a metal oxide layer from an upper portion of the metallic layer during an oxidation process. The lower electrode contains a silicon material and the metallic layer contains hafnium or zirconium. Subsequent to the oxidation process, the method further includes heating the substrate to an annealing temperature within a range from greater than 600° C. to about 850° C. while forming a metal silicide layer from a lower portion of the metallic layer during a silicidation process. | 05-07-2015 |
20150179935 | Atomic Layer Deposition of Metal Oxides for Memory Applications - Embodiments of the invention generally relate to nonvolatile memory devices and methods for manufacturing such memory devices. The methods for forming improved memory devices, such as a ReRAM cells, provide optimized, atomic layer deposition (ALD) processes for forming a metal oxide film stack which contains at least one hard metal oxide film (e.g., metal is completely oxidized or substantially oxidized) and at least one soft metal oxide film (e.g., metal is less oxidized than hard metal oxide). The soft metal oxide film is less electrically resistive than the hard metal oxide film since the soft metal oxide film is less oxidized or more metallic than the hard metal oxide film. In one example, the hard metal oxide film is formed by an ALD process utilizing ozone as the oxidizing agent while the soft metal oxide film is formed by another ALD process utilizing water vapor as the oxidizing agent. | 06-25-2015 |
20150200361 | Transition Metal Oxide Bilayers - Embodiments of the invention include nonvolatile memory elements and memory devices comprising the nonvolatile memory elements. Methods for forming the nonvolatile memory elements are also disclosed. The nonvolatile memory element comprises a first electrode layer, a second electrode layer, and a plurality of layers of an oxide disposed between the first and second electrode layers. One of the oxide layers has linear resistance and substoichiometric composition, and the other oxide layer has bistable resistance and near-stoichiometric composition. Preferably, the sum of the two oxide layer thicknesses is between about 20 Å and about 100 Å, and the oxide layer with bistable resistance has a thickness between about 25% and about 75% of the total thickness. In one embodiment, the oxide layers are formed using reactive sputtering in an atmosphere with controlled flows of argon and oxygen. | 07-16-2015 |
20150310910 | Multi-Level Memory Array Having Resistive Elements for Multi-Bit Data Storage - A resistor array for multi-bit data storage without the need to increase the size of a memory chip or scale down the feature size of a memory cell contained within the memory chip is provided. The resistor array incorporates a number of discrete resistive elements to be selectively connected, in different series combinations, to at least one memory cell or memory device. In one configuration, by connecting each memory cell or device with at least one resistor array, a resistive switching layer found in the resistive switching memory element of the connected memory device is capable of being at multiple resistance states for storing multiple bits of digital information. During device programming operations, when a desired series combination of the resistive elements within the resistor array is selected, the resistive switching layer in the connected memory device can be in a desired resistance state. | 10-29-2015 |
20150311257 | Resistive Random Access Memory Cells Having Shared Electrodes with Transistor Devices - Provided are resistive random access memory (ReRAM) cells having extended conductive layers operable as electrodes of other devices, and methods of fabricating such cells and other devices. A conductive layer of a ReRAM cell extends beyond the cell boundary defined by the variable resistance layer. The extended portion may be used a source or drain region of a FET that may control an electrical current through the cell or other devices. The extended conductive layer may be also operable as electrode of another resistive-switching cell or a different device. The extended conductive layer may be formed from doped silicon. The variable resistance layer of the ReRAM cell may be positioned on the same level as a gate dielectric layer of the FET. The variable resistance layer and the gate dielectric layer may have the same thickness and share common materials, though they may be differently doped. | 10-29-2015 |