Patent application number | Description | Published |
20080237053 | STRUCTURE COMPRISING A BARRIER LAYER OF A TUNGSTEN ALLOY COMPRISING COBALT AND/OR NICKEL - An interconnection structure comprising a substrate having a dielectric layer with a via opening therein; wherein the opening has an underlayer of cobalt and/or nickel therein, barrier layer of an alloy of cobalt and/or nickel; and tungsten is provided. | 10-02-2008 |
20090014878 | STRUCTURE AND METHOD OF FORMING ELECTRODEPOSITED CONTACTS - A contact metallurgy structure comprising a patterned dielectric layer having cavities on a substrate; a silicide or germanide layer such as of cobalt and/or nickel located at the bottom of cavities; a contact layer comprising Ti or Ti/TiN located on top of the dielectric layer and inside the cavities and making contact to the silicide or germanide layer on the bottom; a diffusion barrier layer located on top of the contact layer and inside the cavities; optionally a seed layer for plating located on top of the barrier layer; a metal fill layer in vias is provided along with a method of fabrication. The metal fill layer is electrodeposited with at least one member selected from the group consisting of copper, rhodium, ruthenium, iridium, molybdenum, gold, silver, nickel, cobalt, silver, gold, cadmium and zinc and alloys thereof. When the metal fill layer is rhodium, ruthenium, or iridium, an effective diffusion barrier layer is not required between the fill metal and the dielectric. When the barrier layer is platable, such as ruthenium, rhodium, platinum, or iridium, the seed layer is not required. | 01-15-2009 |
20110084393 | METHOD OF FORMING ELECTRODEPOSITED CONTACTS - A contact metallurgy structure comprising a patterned dielectric layer having vias on a substrate; a silicide layer of cobalt and/or nickel located at the bottom of vias; a contact layer comprising Ti located in vias on top of the silicide layer; a diffusion layer located in vias and on top of the contact layer; a metal fill layer in vias is provided along with a method of fabrication. The metal fill layer comprises at least one member selected from the group consisting of copper, ruthenium, rhodium platinum, palladium, iridium, rhenium, tungsten, gold, silver and osmium and alloys thereof. When the metal fill layer comprises rhodium, the diffusion layer is not required. Optionally a seed layer for the metal fill layer can be employed. | 04-14-2011 |
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 |
20110281402 | FORMATION OF A MASKING LAYER ON A DIELECTRIC REGION TO FACILITATE FORMATION OF A CAPPING LAYER ON ELECTRICALLY CONDUCTIVE REGIONS SEPARATED BY THE DIELECTRIC REGION - A masking layer is formed on a dielectric region of an electronic device so that, during subsequent formation of a capping layer on electrically conductive regions of the electronic device that are separated by the dielectric region, the masking layer inhibits formation of capping layer material on or in the dielectric region. The capping layer can be formed selectively on the electrically conductive regions or non-selectively; in either case (particularly in the latter), capping layer material formed over the dielectric region can subsequently be removed, thus ensuring that capping layer material is formed only on the electrically conductive regions. Silane-based materials, such as silane-based SAMs, can be used to form the masking layer. The capping layer can be formed of an electrically conductive material (e.g., a cobalt alloy, a nickel alloy, tungsten, tantalum, tantalum nitride), a semiconductor material, or an electrically insulative material, and can be formed using any appropriate process, including conventional deposition processes such as electroless deposition, chemical vapor deposition, physical vapor deposition or atomic layer deposition. | 11-17-2011 |
20120001320 | SUBSTRATE PROCESSING INCLUDING A MASKING LAYER - Methods for substrate processing are described. The methods include forming a material layer on a substrate. The methods include selecting constituents of a molecular masking layer (MML) to remove an effect of variations in the material layer as a result of substrate processing. The methods include normalizing the surface characteristics of the material layer by selectively depositing the MML on the material layer. | 01-05-2012 |
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 |
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 |
20120258595 | Formation of a Masking Layer on a Dielectric Region to Facilitate Formation of a Capping Layer on Electrically Conductive Regions Separated by the Dielectric Region - A masking layer is formed on a dielectric region of an electronic device so that, during subsequent formation of a capping layer on electrically conductive regions the masking layer inhibits formation of capping layer material on the dielectric region. The capping layer can be formed selectively on the electrically conductive regions or non-selectively; in either case, capping layer material formed over the dielectric region can subsequently be removed, thus ensuring that capping layer material is formed only on the electrically conductive regions. Silane-based materials, such as silane-based SAMs, can be used to form the masking layer. The capping layer can be formed of an electrically conductive, a semiconductor material, or an electrically insulative material, and can be formed using any appropriate process, including conventional deposition processes such as electroless deposition, chemical vapor deposition, physical vapor deposition or atomic layer deposition. | 10-11-2012 |
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 |
20130330902 | ENHANCED NON-NOBLE ELECTRODE LAYERS FOR DRAM CAPACITOR CELL - A metal oxide first electrode material for a MIM DRAM capacitor is formed wherein the first and/or second electrode materials or structures contain layers having one or more dopants up to a total doping concentration that will not prevent the electrode materials from crystallizing during a subsequent anneal step. Advantageously, the electrode doped with one or more of the dopants has a work function greater than about 5.0 eV. Advantageously, the electrode doped with one or more of the dopants has a resistivity less than about 1000 μΩ cm. Advantageously, the electrode materials are conductive molybdenum oxide. | 12-12-2013 |
20140080282 | Leakage reduction in DRAM MIM capacitors - A method for forming a DRAM MIM capacitor stack having low leakage current involves the use of a first electrode that serves as a template for promoting the high-k phase of a subsequently deposited dielectric layer. The high-k dielectric layer includes a doped material that can be crystallized after a subsequent annealing treatment. An amorphous blocking is formed on the dielectric layer. The thickness of the blocking layer is chosen such that the blocking layer remains amorphous after a subsequent annealing treatment. A second electrode layer compatible with the blocking layer is formed on the blocking layer. | 03-20-2014 |
20140080284 | High Temperature ALD Process of Metal Oxide for DRAM Applications - A first electrode layer for a Metal-Insulator-Metal (MIM) DRAM capacitor is formed wherein the first electrode layer contains a conductive metal oxide formed using a high temperature, low pressure ALD process. The high temperature ALD process results in a layer with enhanced crystallinity, higher density, reduced shrinkage, and lower carbon contamination. The high temperature ALD process can be used for either or both the bottom electrode and the top electrode layers. | 03-20-2014 |
Patent application number | Description | Published |
20080246150 | FORMATION OF A MASKING LAYER ON A DIELECTRIC REGION TO FACILITATE FORMATION OF A CAPPING LAYER ON ELECTRICALLY CONDUCTIVE REGIONS SEPARATED BY THE DIELECTRIC REGION - Devices are presented including: a substrate including a dielectric region and a conductive region; a molecular self-assembled layer selectively formed on the dielectric region; and a capping layer formed on the conductive region, where the capping layer is an electrically conductive material such as: an alloy of cobalt and boron material, an alloy of cobalt, tungsten, and phosphorous material, an alloy of nickel, molybdenum, and phosphorous. In some embodiments, devices are presented where the molecular self-assembled layer includes one or more of a polyelectrolyte, a dendrimer, a hyper-branched polymer, a polymer brush, a block co-polymer, and a silane-based material where the silane-based material includes one or more hydrolysable substituents of a general formula R | 10-09-2008 |
20110021015 | Formation of a Masking Layer on a Dielectric Region to Facilitate Formation of a Capping Layer on Electrically Conductive Regions Separated by the Dielectric Regions - A masking layer is formed on a dielectric region of an electronic device so that, during subsequent formation of a capping layer on electrically conductive regions of the electronic device that are separated by the dielectric region, the masking layer inhibits formation of capping layer material on or in the dielectric region. The capping layer can be formed selectively on the electrically conductive regions or non-selectively; in either case (particularly in the latter), capping layer material formed over the dielectric region can subsequently be removed, thus ensuring that capping layer material is formed only on the electrically conductive regions. Silane-based materials, such as silane-based SAMs, can be used to form the masking layer. The capping layer can be formed of an electrically conductive material (e.g., a cobalt alloy, a nickel alloy, tungsten, tantalum, tantalum nitride), a semiconductor material, or an electrically insulative material, and can be formed using any appropriate process, including conventional deposition processes such as electroless deposition, chemical vapor deposition, physical vapor deposition or atomic layer deposition. | 01-27-2011 |
20120225553 | FORMATION OF A MASKING LAYER ON A DIELECTRIC REGION TO FACILITATE FORMATION OF A CAPPING LAYER ON ELECTRICALLY CONDUCTIVE REGIONS SEPARATED BY THE DIELECTRIC REGION - A masking layer is formed on a dielectric region of an electronic device so that, during subsequent formation of a capping layer on electrically conductive regions of the electronic device that are separated by the dielectric region, the masking layer inhibits formation of capping layer material on or in the dielectric region. The capping layer can be formed selectively on the electrically conductive regions or non-selectively; in either case, capping layer material formed over the dielectric region can subsequently be removed, thus ensuring that capping layer material is formed only on the electrically conductive regions. Silane-based materials, can be used to form the masking layer. The capping layer can be formed of an conductive material, a semiconductor material, or an insulative material, and can be formed using any appropriate process, including conventional deposition processes such as electroless deposition, chemical vapor deposition, physical vapor deposition or atomic layer deposition. | 09-06-2012 |