Patent application number | Description | Published |
20100291764 | Methods Of Removing Noble Metal-Containing Nanoparticles, Methods Of Forming NAND String Gates, And Methods Of Forming Integrated Circuitry - Some embodiments include methods of removing noble metal-containing particles from over a substrate. The substrate is exposed to a composition that reduces adhesion between the noble metal-containing particles and the substrate, and simultaneously the substrate is spun to sweep at least some of the noble metal-containing particles off from the substrate. Some embodiments include methods in which tunnel dielectric material is formed across a semiconductor wafer. Metallic nanoparticles are formed across the tunnel dielectric material. A stack of two or more different materials is formed over the metallic nanoparticles. A portion of the stack is covered with a protective mask while another portion of the stack is left unprotected. The unprotected portion of the stack is removed to expose some of the metallic nanoparticles. The semiconductor wafer to is subjected to etchant suitable to undercut at least some of the exposed metallic nanoparticles, and simultaneously the semiconductor wafer is spun. | 11-18-2010 |
20110147827 | Flash memory with partially removed blocking dielectric in the wordline direction - The present disclosure relates generally to the fabrication of non-volatile memory. In at least one embodiment, the present disclosure relates to forming a layered blocking dielectric which has a portion thereof removed in the wordline direction. | 06-23-2011 |
20110244674 | Method Of Forming A Plurality Of Spaced Features - A method of forming a plurality of spaced features includes forming sacrificial hardmask material over underlying material. The sacrificial hardmask material has at least two layers of different composition. Portions of the sacrificial hardmask material are removed to form a mask over the underlying material. Individual features of the mask have at least two layers of different composition, with one of the layers of each of the individual features having a tensile intrinsic stress of at least 400.0 MPa. The individual features have a total tensile intrinsic stress greater than 0.0 MPa. The mask is used while etching into the underlying material to form a plurality of spaced features comprising the underlying material. Other implementations are disclosed. | 10-06-2011 |
20120225562 | Methods Of Removing Noble Metal-Containing Nanoparticles - Some embodiments include methods of removing noble metal-containing particles from over a substrate. The substrate is exposed to a composition that reduces adhesion between the noble metal-containing particles and the substrate, and simultaneously the substrate is spun to sweep at least some of the noble metal-containing particles off from the substrate. Some embodiments include methods in which tunnel dielectric material is formed across a semiconductor wafer. Metallic nanoparticles are formed across the tunnel dielectric material. A stack of two or more different materials is formed over the metallic nanoparticles. A portion of the stack is covered with a protective mask while another portion of the stack is left unprotected. The unprotected portion of the stack is removed to expose some of the metallic nanoparticles. The semiconductor wafer to is subjected to etchant suitable to undercut at least some of the exposed metallic nanoparticles, and simultaneously the semiconductor wafer is spun. | 09-06-2012 |
20130309858 | Method of Forming a Plurality of Spaced Features - A method of forming a plurality of spaced features includes forming sacrificial hardmask material over underlying material. The sacrificial hardmask material has at least two layers of different composition. Portions of the sacrificial hardmask material are removed to form a mask over the underlying material. Individual features of the mask have at least two layers of different composition, with one of the layers of each of the individual features having a tensile intrinsic stress of at least 400.0 MPa. The individual features have a total tensile intrinsic stress greater than 0.0 MPa. The mask is used while etching into the underlying material to form a plurality of spaced features comprising the underlying material. Other implementations are disclosed. | 11-21-2013 |
20140162418 | Methods of Forming Vertically-Stacked Structures, and Methods of Forming Vertically-Stacked Memory Cells - Some embodiments include methods of forming vertically-stacked structures, such as vertically-stacked memory cells. A first hardmask is formed over a stack of alternating electrically conductive levels and electrically insulative levels. A first opening is formed through the first hardmask and the stack. Cavities are formed to extend into the electrically conductive levels. A fill material is formed within the first opening and within the cavities. A second hardmask is formed over the first hardmask and over the fill material. A second opening is formed through the second hardmask. The second opening is narrower than the first opening. The second opening is extended into the fill material to form an upwardly-opening container from the fill material. Sidewalls of the upwardly-opening container are removed, while leaving the fill material within the cavities as a plurality of vertically-stacked structures. | 06-12-2014 |
20140203344 | 3D MEMORY - Three-dimensional memory cells and methods of making and using the memory cells are discussed generally herein. In one or more embodiments, a three-dimensional vertical memory can include a memory stack. Such a memory stack can include memory cells and a dielectric between adjacent memory cells, each memory cell including a control gate and a charge storage structure. The memory cell can further include a barrier material between the charge storage structure and the control gate, the charge storage structure and the barrier material having a substantially equal dimension. | 07-24-2014 |
20140264532 | FLOATING GATE MEMORY CELLS IN VERTICAL MEMORY - Floating gate memory cells in vertical memory. A control gate is formed between a first tier of dielectric material and a second tier of dielectric material. A floating gate is formed between the first tier of dielectric material and the second tier of dielectric material, wherein the floating gate includes a protrusion extending towards the control gate. A charge blocking structure is formed between the floating gate and the control gate, wherein at least a portion of the charge blocking structure wraps around the protrusion. | 09-18-2014 |
20140264533 | CELL PILLAR STRUCTURES AND INTEGRATED FLOWS - Various embodiments comprise apparatuses and methods, such as a memory stack having a continuous cell pillar. In various embodiments, the apparatus includes a source material, a buffer material, a select gate drain (SGD), and a memory stack arranged between the source material and the SGD. The memory stack comprises alternating levels of conductor materials and dielectric materials. A continuous channel-fill material forms a cell pillar that is continuous from the source material to at least a level corresponding to the SGD. | 09-18-2014 |
20140264542 | MEMORY INCLUDING BLOCKING DIELECTRIC IN ETCH STOP TIER - Vertical memories and methods of making the same are discussed generally herein. In one embodiment, a vertical memory can include a vertical pillar extending to a source, an etch stop tier over the source, and a stack of alternating dielectric tiers and conductive tiers over the etch stop tier. The etch stop tier can comprise a blocking dielectric adjacent to the pillar. In another embodiment, the etch stop tier can comprise a blocking dielectric adjacent to the pillar, and a plurality of dielectric films horizontally extending from the blocking dielectric into the etch stop tier. | 09-18-2014 |
20140273462 | Methods of Fabricating Integrated Structures, and Methods of Forming Vertically-Stacked Memory Cells - Some embodiments include methods of forming vertically-stacked memory cells. An opening is formed to extend partially through a stack of alternating electrically insulative levels and electrically conductive levels. A liner is formed along sidewalls of the opening, and then the stack is etched to extend the opening. The liner is at least partially consumed during the etch and forms passivation material. Three zones occur during the etch, with one of the zones being an upper zone of the opening protected by the liner, another of the zones being an intermediate zone of the opening protected by passivation material but not the liner, and another of the zones being a lower zone of the opening which is not protected by either passivation material or the liner. Cavities are formed to extend into the electrically conductive levels along sidewalls of the opening. Charge blocking dielectric and charge-storage structures are formed within the cavities. | 09-18-2014 |
20140339621 | METHODS FOR FORMING A STRING OF MEMORY CELLS AND APPARATUSES HAVING A VERTICAL STRING OF MEMORY CELLS INCLUDING METAL - Methods for forming a string of memory cells and apparatuses having a vertical string of memory cells are disclosed. One such string of memory cells can be formed at least partially in a stack of materials comprising a plurality of alternating levels of control gate material and insulator material. A memory cell of the string can include floating gate material adjacent to a level of control gate material of the levels of control gate material. The memory cell can also include tunnel dielectric material adjacent to the floating gate material. The level of control gate material and the tunnel dielectric material are adjacent opposing surfaces of the floating gate material. The memory cell can include metal along an interface between the tunnel dielectric material and the floating gate material. The memory cell can further include a semiconductor material adjacent to the tunnel dielectric material. | 11-20-2014 |
20150041879 | SEMICONDUCTOR STRUCTURES AND METHODS OF FABRICATION OF SAME - Semiconductor structures may include a stack of alternating dielectric materials and control gates, charge storage structures laterally adjacent to the control gates, a charge block material between each of the charge storage structures and the laterally adjacent control gates, and a pillar extending through the stack of alternating oxide materials and control gates. Each of the dielectric materials in the stack has at least two portions of different densities and/or different rates of removal. Also disclosed are methods of fabricating such semiconductor structures. | 02-12-2015 |