Patent application number | Description | Published |
20100096687 | NON-VOLATILE MEMORY HAVING SILICON NITRIDE CHARGE TRAP LAYER - A flash memory device and methods of forming a flash memory device are provided. The flash memory device includes a doped silicon nitride layer having a dopant comprising carbon, boron or oxygen. The doped silicon nitride layer generates a higher number and higher concentration of nitrogen and silicon dangling bonds in the layer and provides an increase in charge holding capacity and charge retention time of the unit cell of a non-volatile memory device. | 04-22-2010 |
20100096688 | NON-VOLATILE MEMORY HAVING CHARGE TRAP LAYER WITH COMPOSITIONAL GRADIENT - A flash memory device and method of forming a flash memory device are provided. The flash memory device includes a silicon nitride layer having a compositional gradient in which the ratio of silicon to nitrogen varies through the thickness of the layer. The silicon nitride layer having a compositional gradient of silicon and nitrogen provides an increase in charge holding capacity and charge retention time of the unit cell of a non-volatile memory device. | 04-22-2010 |
20100099247 | FLASH MEMORY WITH TREATED CHARGE TRAP LAYER - A methods of forming a flash memory device are provided. The flash memory device comprises a silicon dioxide layer on a substrate and a silicon nitride layer that is formed on the silicon dioxide layer. The properties of the silicon nitride layer can be modified by any of: exposing the silicon nitride layer to ultraviolet radiation, exposing the silicon nitride layer to an electron beam, and by plasma treating the silicon nitride layer. A dielectric material is deposited on the silicon nitride layer and a conductive date is formed over the dielectric material. The flash memory device with modified silicon nitride layer provides an increase in charge holding capacity and charge retention time of the unit cell of a non-volatile memory device. | 04-22-2010 |
20120220116 | Dry Chemical Cleaning For Semiconductor Processing - A deposition process including a dry etch process, followed by a deposition process of a high-k dielectric is disclosed. The dry etch process involves placing a substrate to be cleaned into a processing chamber to remove surface oxides. A gas mixture is energized to form a plasma of reactive gas which reacts with an oxide on the substrate, forming a thin film. The substrate is heated to vaporize the thin film and expose a substrate surface. The substrate surface is substantially free of oxides. Deposition is then used to form a layer on the substrate surface. | 08-30-2012 |
20120270409 | Methods For Manufacturing High Dielectric Constant Films - Provided are methods for depositing a cerium doped hafnium containing high-k dielectric film on a substrate. The reagents of specific methods include hafnium tetrachloride, an organometallic complex of cerium and water. | 10-25-2012 |
20120322250 | N-Metal Film Deposition With Initiation Layer - Provided are methods of depositing N-Metals onto a substrate. Some methods comprise providing an initiation layer of TaM or TiM layer on a substrate, wherein M is selected from aluminum, carbon, noble metals, gallium, silicon, germanium and combinations thereof; and exposing the substrate having the TaM or TiM layer to a treatment process comprising soaking the surface of the substrate with a reducing agent to provided a treated initiation layer. | 12-20-2012 |
20120322262 | N-Metal Film Deposition With Initiation Layer - Provided are methods of depositing N-Metals onto a substrate. Methods include first depositing an initiation layer. The initiation layer may comprise or consist of cobalt, tantalum, nickel, titanium or TaAlC. These initiation layers can be used to deposit TaC | 12-20-2012 |
20130115383 | DEPOSITION OF METAL FILMS USING ALANE-BASED PRECURSORS - Provided are methods of depositing pure metal and aluminum alloy metal films. Certain methods comprises contacting a substrate surface with first and second precursors, the first precursor comprising an aluminum precursor selected from dimethylaluminum hydride, alane coordinated to an amine, and a compound having a structure represented by: | 05-09-2013 |
20130122697 | Doping aluminum in tantalum silicide - Provided are methods of providing aluminum-doped TaSi | 05-16-2013 |
20130200518 | Devices Including Metal-Silicon Contacts Using Indium Arsenide Films and Apparatus and Methods - Described are apparatus and methods for forming films comprise indium and arsenic. In particular, these films may be formed in a configuration of two or more chambers under “load lock” conditions. These films may include additional components as dopants, such as aluminum and/or gallium. Such films can be used in metal/silicon contacts having low contact resistances. Also disclosed are devices including the films comprising indium arsenide. | 08-08-2013 |
20130221445 | Atomic Layer Deposition Methods For Metal Gate Electrodes - Provided are devices and methods utilizing TiN and/or TaN films doped with Si, Al, Ga, Ge, In and/or Hf. Such films may be used as a high-k dielectric cap layer, PMOS work function layer, aluminum barrier layer, and/or fluorine barrier. These TiSiN, TaSiN, TiAlN, TaAlN, TiGaN, TaGaN, TiGeN, TaGeN, TiInN, TaInN, TiHfN or TaHfN films can be used where TiN and/or TaN films are traditionally used, or they may be used in conjunction with TiN and/or TaN. | 08-29-2013 |
20130288427 | Methods Of Fabricating Dielectric Films From Metal Amidinate Precursors - Described are methods for atomic layer deposition of films comprising mixed metal oxides using metal amidinate precursors. The mixed metal oxide films may comprise a lanthanide and a transition metal such as hafnium, zirconium or titanium. Such mixed metal oxide films may be used as dielectric layers in capacitors, transistors, dynamic random access memory cells, resistive random access memory cells, flash memory cells and display panels. | 10-31-2013 |
20130295759 | Methods For Manufacturing Metal Gates - Provided are methods for making metal gates suitable for FinFET structures. The methods described herein generally involve forming a high-k dielectric material on a semiconductor substrate; depositing a high-k dielectric cap layer over the high-k dielectric material; depositing a PMOS work function layer having a positive work function value; depositing an NMOS work function layer; depositing an NMOS work function cap layer over the NMOS work function layer; removing at least a portion of the PMOS work function layer or at least a portion of the NMOS work function layer; and depositing a fill layer. Depositing a high-k dielectric cap layer, depositing a PMOS work function layer or depositing a NMOS work function cap layer may comprise atomic layer deposition of TiN, TiSiN, or TiAlN. Either PMOS or NMOS may be deposited first. | 11-07-2013 |
20140017408 | Deposition Of N-Metal Films Comprising Aluminum Alloys - Provided are methods of depositing films comprising alloys of aluminum, which may be suitable as N-metal films. Certain methods comprise exposing a substrate surface to a metal halide precursor comprising a metal halide selected from TiCl | 01-16-2014 |
20140112824 | Deposition Of Films Comprising Aluminum Alloys With High Aluminum Content - Provided are films comprising aluminum, carbon and a metal, wherein the aluminum is present in an amount greater than about 16% by elemental content and less than about 50% carbon. Also provided are methods of depositing the same. | 04-24-2014 |
20140120723 | METHODS FOR DEPOSITING FLUORINE/CARBON-FREE CONFORMAL TUNGSTEN - Provided are atomic layer deposition methods to deposit a tungsten film or tungsten-containing film using a tungsten-containing reactive gas comprising one or more of tungsten pentachloride, a compound with the empirical formula WCl | 05-01-2014 |