Patent application number | Description | Published |
20080278990 | RESISTIVE-SWITCHING NONVOLATILE MEMORY ELEMENTS - Nonvolatile memory elements are provided that have resistive switching metal oxides. The nonvolatile memory elements may be formed in one or more layers on an integrated circuit. Each memory element may have a first conductive layer, a metal oxide layer, and a second conductive layer. Electrical devices such as diodes may be coupled in series with the memory elements. The first conductive layer may be formed from a metal nitride. The metal oxide layer may contain the same metal as the first conductive layer. The metal oxide may form an ohmic contact or a Schottky contact with the first conductive layer. The second conductive layer may form an ohmic contact or a Schottky contact with the metal oxide layer. The first conductive layer, the metal oxide layer, and the second conductive layer may include sublayers. The second conductive layer may include an adhesion or barrier layer and a workfunction control layer. | 11-13-2008 |
20090026434 | NONVOLATILE MEMORY ELEMENTS - Nonvolatile memory elements that are based on resistive switching memory element layers are provided. A nonvolatile memory element may have a resistive switching metal oxide layer. The resistive switching metal oxide layer may have one or more layers of oxide. A resistive switching metal oxide may be doped with a dopant that increases its melting temperature and enhances its thermal stability. Layers may be formed to enhance the thermal stability of the nonvolatile memory element. An electrode for a nonvolatile memory element may contain a conductive layer and a buffer layer. | 01-29-2009 |
20110081748 | METHODS FOR FORMING RESISTIVE-SWITCHING METAL OXIDES FOR NONVOLATILE MEMORY ELEMENTS - Nonvolatile memory elements are provided that have resistive switching metal oxides. The nonvolatile memory elements may be formed from resistive-switching metal oxide layers. Metal oxide layers may be formed using sputter deposition at relatively low sputtering powers, relatively low duty cycles, and relatively high sputtering gas pressures. Dopants may be incorporated into a base oxide layer at an atomic concentration that is less than the solubility limit of the dopant in the base oxide. At least one oxidation state of the metal in the base oxide is preferably different than at least one oxidation sate of the dopant. The ionic radius of the dopant and the ionic radius of the metal may be selected to be close to each other. Annealing and oxidation operations may be performed on the resistive switching metal oxides. Bistable metal oxides with relatively large resistivities and large high-state-to-low state resistivity ratios may be produced. | 04-07-2011 |
20120122291 | Nonvolatile Memory Elements - Nonvolatile memory elements that are based on resistive switching memory element layers are provided. A nonvolatile memory element may have a resistive switching metal oxide layer. The resistive switching metal oxide layer may have one or more layers of oxide. A resistive switching metal oxide may be doped with a dopant that increases its melting temperature and enhances its thermal stability. Layers may be formed to enhance the thermal stability of the nonvolatile memory element. An electrode for a nonvolatile memory element may contain a conductive layer and a buffer layer. | 05-17-2012 |
20120142143 | Methods for Forming Resistive Switching Memory Elements by Heating Deposited Layers - Resistive switching nonvolatile memory elements are provided. A metal-containing layer and an oxide layer for a memory element can be heated using rapid thermal annealing techniques. During heating, the oxide layer may decompose and react with the metal-containing layer. Oxygen from the decomposing oxide layer may form a metal oxide with metal from the metal-containing layer. The resulting metal oxide may exhibit resistive switching for the resistive switching memory elements. | 06-07-2012 |
20120149164 | METHODS FOR FORMING RESISTIVE-SWITCHING METAL OXIDES FOR NONVOLATILE MEMORY ELEMENTS - Nonvolatile memory elements are provided that have resistive switching metal oxides. The nonvolatile memory elements may be formed from resistive-switching metal oxide layers. Metal oxide layers may be formed using sputter deposition at relatively low sputtering powers, relatively low duty cycles, and relatively high sputtering gas pressures. Dopants may be incorporated into a base oxide layer at an atomic concentration that is less than the solubility limit of the dopant in the base oxide. At least one oxidation state of the metal in the base oxide is preferably different than at least one oxidation sate of the dopant. The ionic radius of the dopant and the ionic radius of the metal may be selected to be close to each other. Annealing and oxidation operations may be performed on the resistive switching metal oxides. Bistable metal oxides with relatively large resistivities and large high-state-to-low state resistivity ratios may be produced. | 06-14-2012 |
20120319070 | RESISTIVE-SWITCHING NONVOLATILE MEMORY ELEMENTS - Nonvolatile memory elements are provided comprising switching metal oxides. The nonvolatile memory elements may be formed in one or more layers on an integrated circuit. Each memory element may have a first conductive layer, a metal oxide layer, and a second conductive layer. Electrical devices may be coupled in series with the memory elements. The first conductive layer may be formed from a metal nitride. The metal oxide layer may contain the same metal as the first conductive layer. The metal oxide may form an ohmic contact or a Schottky contact with the first conductive layer. The second conductive layer may form an ohmic contact or a Schottky contact with the metal oxide layer. The first conductive layer, the metal oxide layer, and the second conductive layer may include sublayers. The second conductive layer may include an adhesion or barrier layer and a workfunction control layer. | 12-20-2012 |
20130059427 | Nonvolatile Memory Elements - Nonvolatile memory elements that are based on resistive switching memory element layers are provided. A nonvolatile memory element may have a resistive switching metal oxide layer. The resistive switching metal oxide layer may have one or more layers of oxide. A resistive switching metal oxide may be doped with a dopant that increases its melting temperature and enhances its thermal stability. Layers may be formed to enhance the thermal stability of the nonvolatile memory element. An electrode for a nonvolatile memory element may contain a conductive layer and a buffer layer. | 03-07-2013 |
20130109149 | Methods for Forming Resistive-Switching Metal Oxides for Nonvolatile Memory Elements | 05-02-2013 |
20130122671 | PROCESS TO REMOVE Ni AND Pt RESIDUES FOR NiPtSi APPLICATIONS - The invention discloses a method for cleaning residues from a semiconductor substrate during a nickel platinum silicidation process. Embodiments of the invention provide a multi-step cleaning process, comprising exposing the substrate to a nitric acid solution after a first anneal, followed by an aqua regia solution after a second anneal. The substrate can be optionally exposed to a hydrochloric acid solution afterward to completely remove any remaining platinum residues. | 05-16-2013 |
20130125923 | METHOD FOR CLEANING PLATINUM RESIDUES ON A SEMICONDUCTOR SUBSTRATE - A method for cleaning platinum residues from a surface of a substrate is provided. The method initiates with exposing the surface to a first solution containing a mixture of nitric acid and hydrochloric acid. Then, the surface is exposed to a second solution containing hydrochloric acid. | 05-23-2013 |
20130130414 | HIGH PRODUCTIVITY COMBINATORIAL WORKFLOW FOR PHOTORESIST STRIP APPLICATIONS - Electrical testing of metal oxide semiconductor (MOS) high-k capacitor structures is used to evaluate photoresist strip or cleaning chemicals using a combinatorial workflow. The electrical testing can be able to identify the damages on the high-k dielectrics, permitting a selection of photoresist strip chemicals to optimize the process conditions in the fabrication of semiconductor devices. The high productivity combinatorial technique can provide a compatibility evaluation of photoresist strip chemicals with high-k devices. | 05-23-2013 |
20130217200 | Resistive-Switching Nonvolatile Memory Elements - Nonvolatile memory elements are provided that have resistive switching metal oxides. The nonvolatile memory elements may be formed in one or more layers on an integrated circuit. Each memory element may have a first conductive layer, a metal oxide layer, and a second conductive layer. Electrical devices such as diodes may be coupled in series with the memory elements. The first conductive layer may be formed from a metal nitride. The metal oxide layer may contain the same metal as the first conductive layer. The metal oxide may form an ohmic contact or a Schottky contact with the first conductive layer. The second conductive layer may form an ohmic contact or Schottky contact with the metal oxide layer. The first conductive layer, the metal oxide layer, and the second conductive layer may include sublayers. The second conductive layer may include an adhesion or barrier layer and a workfunction control layer. | 08-22-2013 |
20130236632 | Graphene Combinatorial Processing - A method for optimizing graphene synthesis is provided. The method includes providing a substrate having a plurality of site isolated regions defined thereon and depositing a metal layer within each region of the plurality of site isolated regions. The metal layer is combinatorially deposited among the plurality of site isolated regions. The method includes synthesizing a graphene layer over each metal layer within each region of the plurality of site isolated regions and evaluating grain boundary profiles in the synthesized graphene layer over each metal layer within each region of the plurality of site isolated regions. | 09-12-2013 |
20130323863 | Method for Generating Graphene Structures - A method for depositing graphene is provided. The method includes depositing a layer of non-conducting amorphous carbon over a surface of a substrate and depositing a transition metal in a pattern over the amorphous carbon. The substrate is annealed at a temperature below 500° C., where the annealing converts the non-conducting amorphous carbon disposed under the transition metal to conducting amorphous carbon. A portion of the pattern of the transition metal is removed from the surface of the substrate to expose the conducting amorphous carbon. | 12-05-2013 |
20140030887 | Sputtering and Aligning Multiple Layers Having Different Boundaries - Provided are methods and systems for forming discreet multilayered structures. Each structure may be deposited by in situ deposition of multiple layers at one of multiple site isolation regions provided on the same substrate for use in combinatorial processing. Alignment of different layers within each structure is provided by using two or more differently sized openings in-between one or more sputtering targets and substrate. Specifically, deposition of a first layer is performed through the first opening that defines a first deposition area. A shutter having a second smaller opening is then positioned in-between the one or more targets and substrate. Sputtering of a second layer is then performed through this second opening that defines a second deposition area. This second deposition area may be located within the first deposition area based on sizing and alignment of the openings as well as alignment of the substrate. | 01-30-2014 |
20140042384 | Resistive-Switching Nonvolatile Memory Elements - Nonvolatile memory elements including resistive switching metal oxides may be formed in one or more layers on an integrated circuit. Each memory element may have a first conductive layer, a metal oxide layer, and a second conductive layer. Electrical devices such as diodes may be coupled in series with the memory elements. The first conductive layer may be formed from a metal nitride. The metal oxide layer may contain the same metal as the first conductive layer. The metal oxide may form an ohmic contact or a Schottky contact with the first conductive layer. The second conductive layer may form an ohmic contact or Schottky contact with the metal oxide layer. The first conductive layer, the metal oxide layer, and the second conductive layer may include sublayers. The second conductive layer may include an adhesion or barrier layer and a workfunction control layer. | 02-13-2014 |
20140051210 | Nonvolatile Memory Elements - Nonvolatile memory elements that are based on resistive switching memory element layers are provided. A nonvolatile memory element may have a resistive switching metal oxide layer. The resistive switching metal oxide layer may have one or more layers of oxide. A resistive switching metal oxide may be doped with a dopant that increases its melting temperature and enhances its thermal stability. Layers may be formed to enhance the thermal stability of the nonvolatile memory element. An electrode for a nonvolatile memory element may contain a conductive layer and a buffer layer. | 02-20-2014 |
20140110764 | Method to control amorphous oxide layer formation at interfaces of thin film stacks for memory and logic components - Methods and apparatuses for combinatorial processing are disclosed. Methods of the present disclosure providing a substrate, the substrate comprising a plurality of site-isolated regions. Methods include forming a first capping layer on the surface of a first site-isolated region of the substrate. The methods further include forming a second capping layer on the surface of a second site-isolated region of the substrate. In some embodiments, forming the first and second capping layers include exposing the first and second site-isolated regions to a plasma induced with H | 04-24-2014 |
20140179095 | Methods and Systems for Controlling Gate Dielectric Interfaces of MOSFETs - Embodiments provided herein describe methods and systems for forming gate dielectrics for field effect transistors. A substrate including a germanium channel and a germanium oxide layer on a surface of the germanium channel is provided. A metallic layer is deposited on the germanium oxide layer. The metallic layer may be nanocrystalline or amorphous. The deposition of the metallic layer causes the germanium oxide layer to be reduced such that a metal oxide layer is formed adjacent to the germanium channel. | 06-26-2014 |
20140256111 | Nonvolatile Memory Elements - Nonvolatile memory elements that are based on resistive switching memory element layers are provided. A nonvolatile memory element may have a resistive switching metal oxide layer. The resistive switching metal oxide layer may have one or more layers of oxide. A resistive switching metal oxide may be doped with a dopant that increases its melting temperature and enhances its thermal stability. Layers may be formed to enhance the thermal stability of the nonvolatile memory element. An electrode for a nonvolatile memory element may contain a conductive layer and a buffer layer. | 09-11-2014 |
20140264281 | Channel-Last Methods for Making FETS - Semiconductor devices and methods of making thereof are disclosed. A field effect transistor (FET) is provided comprising a substrate, a first layer disposed above the substrate, the first layer being operable as a gate electrode, a second layer disposed above the first layer, the second layer comprising a dielectric material, a third layer disposed above the second layer, the third layer comprising a semiconductor, and a fourth layer comprising one or more conductive materials and operable as source and drain electrodes disposed above the third layer. In some embodiments, the dielectric material comprises a high-κ dielectric. In some embodiments, the source and drain electrodes comprise one or more metals. The source and drain electrodes are each in ohmic contact with an area of the top surface of the third layer, and substantially all of the current through the transistor flows through the ohmic contacts. | 09-18-2014 |
20140273309 | Controlling Radical Lifetimes in a Remote Plasma Chamber - Remote-plasma treatments of surfaces, for example in semiconductor manufacture, can be improved by preferentially exposing the surface to only a selected subset of the plasma species generated by the plasma source. The probability that a selected species reaches the surface, or that an unselected species is quenched or otherwise converted or diverted before reaching the surface, can be manipulated by introducing additional gases with selected properties either at the plasma source or in the process chamber, varying chamber pressure or flow rate to increase or decrease collisions, or changing the dimensions or geometry of the injection ports, conduits and other passages traversed by the species. Some example processes treat surfaces preferentially with relatively low-energy radicals, vary the concentration of radicals at the surface in real time, or clean and passivate in the same unit process. | 09-18-2014 |
20140273525 | Atomic Layer Deposition of Reduced-Leakage Post-Transition Metal Oxide Films - Metal-oxide films (e.g., aluminum oxide) with low leakage current suitable for high-k gate dielectrics are deposited by atomic layer deposition (ALD). The purge time after the metal-deposition phase is 5-15 seconds, and the purge time after the oxidation phase is prolonged beyond 60 seconds. Prolonging the post-oxidation purge produced an order-of-magnitude reduction of leakage current in 30 Å-thick Al | 09-18-2014 |
20150034896 | Resistive-Switching Nonvolatile Memory Elements - Nonvolatile memory elements including resistive switching metal oxides may be formed in one or more layers on an integrated circuit. Each memory element may have a first conductive layer, a metal oxide layer, and a second conductive layer. Electrical devices such as diodes may be coupled in series with the memory elements. The first conductive layer may be formed from a metal nitride. The metal oxide layer may contain the same metal as the first conductive layer. The metal oxide may form an ohmic contact or a Schottky contact with the first conductive layer. The second conductive layer may form an ohmic contact or Schottky contact with the metal oxide layer. The first conductive layer, the metal oxide layer, and the second conductive layer may include sublayers. The second conductive layer may include an adhesion or barrier layer and a workfunction control layer. | 02-05-2015 |
20150056748 | Methods for Forming Resistive Switching Memory Elements by Heating Deposited Layers - Resistive switching nonvolatile memory elements are provided. A metal-containing layer and an oxide layer for a memory element can be heated using rapid thermal annealing techniques. During heating, the oxide layer may decompose and react with the metal-containing layer. Oxygen from the decomposing oxide layer may form a metal oxide with metal from the metal-containing layer. The resulting metal oxide may exhibit resistive switching for the resistive switching memory elements. | 02-26-2015 |