Patent application number | Description | Published |
20080246101 | METHOD OF POLY-SILICON GRAIN STRUCTURE FORMATION - A method for forming a poly-crystalline silicon film on a substrate by positioning a substrate within a processing chamber, heating the processing chamber to a first temperature between about 640° C. and about 720° C., stabilizing a deposition pressure between about 200 Torr and about 350 Torr, introducing a silicon precursor into the processing chamber to deposit a silicon film comprising an amorphous or hemisphere grain film, and heating the processing chamber to a second temperature between about 700° C. and about 750 C.° to anneal the amorphous or hemisphere grain film into a poly-crystalline nano-crystalline grain film. | 10-09-2008 |
20090020802 | INTEGRATED SCHEME FOR FORMING INTER-POLY DIELECTRICS FOR NON-VOLATILE MEMORY DEVICES - Electronic devices and methods for forming electronic devices that allow for a reduction in device dimensions while also maintaining or reducing leakage current for non-volatile memory devices are provided. In one embodiment, a method of fabricating a non-volatile memory device is provided. The method comprises depositing a floating gate polysilicon layer on a substrate, forming a silicon oxide layer on the floating gate polysilicon layer, depositing a first silicon oxynitride layer on the silicon oxide layer, depositing a high-k dielectric material layer on the first silicon oxynitride layer, depositing a second silicon oxynitride on the high-k dielectric material, and forming a control gate polysilicon layer on the second silicon oxynitride layer. In one embodiment, the high-k dielectric material layer comprises hafnium silicon oxynitride. | 01-22-2009 |
20090042353 | INTEGRATED CIRCUIT FABRICATION PROCESS FOR A HIGH MELTING TEMPERATURE SILICIDE WITH MINIMAL POST-LASER ANNEALING DOPANT DEACTIVATION - Post-laser annealing dopant deactivation is minimized by performing certain silicide formation process steps prior to laser annealing. A base metal layer of nickel is deposited on the source-drain regions and the gate electrode, followed by deposition of an overlying layer of a metal having a higher melting temperature than nickel. Thereafter, a rapid thermal process is performed to heat the substrate sufficiently to form metal silicide contacts at the top surfaces of the source-drain regions and of the gate electrode. The method further includes removing the remainder of the metal-containing layer and then depositing an optical absorber layer over the substrate prior to laser annealing. | 02-12-2009 |
20090042354 | INTEGRATED CIRCUIT FABRICATION PROCESS USING A COMPRESSION CAP LAYER IN FORMING A SILICIDE WITH MINIMAL POST-LASER ANNEALING DOPANT DEACTIVATION - Post-laser annealing dopant deactivation is minimized by performing certain silicide formation process steps prior to laser annealing. A base metal layer is deposited on the source-drain regions and the gate electrode, followed by deposition of an overlying compression cap layer, to prevent metal agglomeration at the silicon melting temperature. Thereafter, a rapid thermal process is performed to heat the substrate sufficiently to form metal silicide contacts at the top surfaces of the source-drain regions and of the gate electrode. The method further includes removing the remainder of the metal-containing layer and then depositing an optical absorber layer over the substrate prior to laser annealing near the silicon melting temperature. | 02-12-2009 |
20090042376 | INTEGRATED CIRCUIT FABRICATION PROCESS WITH MINIMAL POST-LASER ANNEALING DOPANT DEACTIVATION - Post-laser annealing dopant deactivation is minimized by performing certain low temperature process steps prior to laser annealing. | 02-12-2009 |
20090065816 | MODULATING THE STRESS OF POLY-CRYSTALINE SILICON FILMS AND SURROUNDING LAYERS THROUGH THE USE OF DOPANTS AND MULTI-LAYER SILICON FILMS WITH CONTROLLED CRYSTAL STRUCTURE - In certain embodiments a method of forming a multi-layer silicon film is provided. A substrate is placed in a process chamber. An amorphous silicon film is formed on the substrate by flowing into the process chamber a first process gas comprising a silicon source gas. A polysilicon film is formed on the amorphous silicon film by flowing into the deposition chamber a first process gas mix comprising a silicon source gas and a first dilution gas mix comprising H | 03-12-2009 |
20090152617 | HETERO-STRUCTURE VARIABLE SILICON RICHNESS NITRIDE FOR MLC FLASH MEMORY DEVICE - Charge storage stacks containing hetero-structure variable silicon richness nitride for memory cells and methods for making the charge storage stacks are provided. The charge storage stack can contain a first insulating layer on a semiconductor substrate; n charge storage layers comprising silicon-rich silicon nitride on the first insulating layer, wherein numbers of the charge storage layers increase from the bottom to the top and a k-value of an n-1th charge storage layer is higher than a k-value of an nth charge storage layer; n-1 dielectric layers comprising substantially stoichiometric silicon nitride between each of the n charge storage layers; and a second insulating layer on the nth charge storage layers. | 06-18-2009 |
20090242957 | ATOMIC LAYER DEPOSITION PROCESSES FOR NON-VOLATILE MEMORY DEVICES - Embodiments of the invention provide memory devices and methods for forming memory devices. In one embodiment, a memory device is provided which includes a floating gate polysilicon layer disposed over source/drain regions of a substrate, a silicon oxynitride layer disposed over the floating gate polysilicon layer, a first aluminum oxide layer disposed over the silicon oxynitride layer, a hafnium silicon oxynitride layer disposed over the first aluminum oxide layer, a second aluminum oxide layer disposed over the hafnium silicon oxynitride layer, and a control gate polysilicon layer disposed over the second aluminum oxide layer. In another embodiment, a memory device is provided which includes a control gate polysilicon layer disposed over an inter-poly dielectric stack disposed over a silicon oxide layer disposed over the floating gate polysilicon layer. The inter-poly dielectric stack contains two silicon oxynitride layers separated by a silicon nitride layer. | 10-01-2009 |
20090246972 | METHODS FOR MANUFACTURING HIGH DIELECTRIC CONSTANT FILM - Processes for making a high K (dielectric constant) film using an ultra-high purity hafnium containing organometallic compound are disclosed. Also described are devices incorporating high K films made with high purity hafnium containing organometallic compounds. | 10-01-2009 |
20090261406 | USE OF SILICON-RICH NITRIDE IN A FLASH MEMORY DEVICE - A flash memory cell includes a charge storage element that includes at least a first layer and a second layer. One of the layers includes silicon-rich silicon nitride and the other layer includes silicon nitride. More specifically, the ratio of silicon-to-nitrogen in the first layer is greater than the ratio of silicon-to-nitrogen in the second layer. | 10-22-2009 |
20090269916 | METHODS FOR FABRICATING MEMORY CELLS HAVING FIN STRUCTURES WITH SEMICIRCULAR TOP SURFACES AND ROUNDED TOP CORNERS AND EDGES - Methods for fabricating a FIN structure with a semicircular top surface and rounded top surface corners and edges are disclosed. As a part of a disclosed method, a FIN structure is formed in a semiconductor substrate. The FIN structure includes a top surface having corners and edges. The FIN structure is annealed where the annealing causes the top surface to have a semicircular shape and the top surface corners and edges to be rounded. | 10-29-2009 |
20090269918 | METHODS FOR FABRICATING MEMORY CELLS HAVING FIN STRUCTURES WITH SMOOT SIDEWALLS AND ROUNDED TOP CORNERS AND EDGES - Methods for fabricating a semiconductor FIN structure with smooth sidewalls and rounded top corners and edges is disclosed. A method includes forming a plurality of semiconductor FIN structures. A sacrificial oxide layer is formed on the top surface and the sidewall surfaces of the plurality of semiconductor FIN structures for rounding the corners and edges between the top surfaces and the sidewall surfaces of the plurality of semiconductor FIN structures. The sacrificial oxide layer is removed with a high selectivity oxide etchant. The plurality of semiconductor FIN structures are annealed in a hydrogen environment. A tunnel oxide is formed over the plurality of semiconductor FIN structures. | 10-29-2009 |
20100065940 | 3-D INTEGRATED CIRCUIT SYSTEM AND METHOD - A semiconductor fabrication system and method are presented. A three dimensional multilayer integrated circuit fabrication method can include forming a first device layer and forming a second device layer on top of the first device layer with minimal detrimental heat transfer to the first layer by utilizing a controlled laser layer formation annealing process. A controlled laser crystallization process can be utilized and the controlled laser can include creating an amorphous layer; defining a crystallization area in the amorphous layer, where in the crystallization area is defined to promote single crystal growth (i.e. prevent multi-crystalline growth); and applying laser to the crystallization area, wherein the laser is applied in a manner that prevents undesired heat transfer to another layer. | 03-18-2010 |
20100102376 | Atomic Layer Deposition Processes for Non-Volatile Memory Devices - Embodiments of the invention provide memory devices and methods for forming such memory devices. In one embodiment, a method for fabricating a non-volatile memory device on a substrate is provided which includes depositing a first polysilicon layer on a substrate surface, depositing a silicon oxide layer on the first polysilicon layer, depositing a first silicon oxynitride layer on the silicon oxide layer, depositing a silicon nitride layer on the first silicon oxynitride layer, depositing a second silicon oxynitride layer on the silicon nitride layer, and depositing a second polysilicon layer on the second silicon oxynitride layer. In some examples, the first polysilicon layer is a floating gate and the second polysilicon layer is a control gate. | 04-29-2010 |
20110057248 | VARIED SILICON RICHNESS SILICON NITRIDE FORMATION - A method, in one embodiment, can include forming a tunnel oxide layer on a substrate. In addition, the method can include depositing via atomic layer deposition a first layer of silicon nitride over the tunnel oxide layer. Note that the first layer of silicon nitride includes a first silicon richness. The method can also include depositing via atomic layer deposition a second layer of silicon nitride over the first layer of silicon nitride. The second layer of silicon nitride includes a second silicon richness that is different than the first silicon richness. | 03-10-2011 |
20110272775 | 3D INTEGRATED CIRCUIT SYSTEM AND METHOD - A semiconductor fabrication system and method are presented. A three dimensional multilayer integrated circuit fabrication method can include forming a first device layer and forming a second device layer on top of the first device layer with minimal detrimental heat transfer to the first layer by utilizing a controlled laser layer formation annealing process. A controlled laser crystallization process can be utilized and the controlled laser can include creating an amorphous layer; defining a crystallization area in the amorphous layer, where in the crystallization area is defined to promote single crystal growth (i.e. prevent multi-crystalline growth); and applying laser to the crystallization area, wherein the laser is applied in a manner that prevents undesired heat transfer to another layer. | 11-10-2011 |
20130062587 | Resistive Switching Devices Having Alloyed Electrodes And Methods of Formation Thereof - In accordance with an embodiment of the present invention, a resistive switching device comprises a bottom electrode, a switching layer disposed over the bottom electrode, and a top electrode disposed over the switching layer. The top electrode comprises an alloy of a memory metal and an alloying element. The top electrode provides a source of the memory metal. The memory metal is configured to change a state of the switching layer. | 03-14-2013 |
20130285004 | SOLID ELECTROLYTE MEMORY ELEMENTS WITH ELECTRODE INTERFACE FOR IMPROVED PERFORMANCE - A memory element can include a first electrode; a second electrode; and a memory material programmable between different resistance states, the memory material disposed between the first electrode and the second electrode and comprising a solid electrolyte with at least one modifier element formed therein; wherein the first electrode is an anode electrode that includes an anode element that is ion conductible in the solid electrolyte, the anode element being different than the modifier element. | 10-31-2013 |
20140246641 | Resistive Switching Devices Having a Switching Layer And An Intermediate Electrode Layer and Methods of Formation Thereof - In one embodiment of the present invention, a resistive switching device includes a first electrode disposed over a substrate and coupled to a first potential node, a switching layer disposed over the first electrode, a conductive amorphous layer disposed over the switching layer, and a second electrode disposed on the conductive amorphous layer and coupled to a second potential node. | 09-04-2014 |
20140293676 | PROGRAMMABLE IMPEDANCE MEMORY ELEMENTS AND CORRESPONDING METHODS - A memory element programmable between different impedance states can include a first electrode; a switching layer formed in contact with the first electrode and including at least one metal oxide; and a buffer layer in contact with the switching layer. A buffer layer can include a first metal, tellurium, a third element, and a second metal distributed within the buffer layer. A second electrode can be in contact with the buffer layer. | 10-02-2014 |