Patent application number | Description | Published |
20130087883 | Integrated Circuit Devices And Methods Of Forming Memory Array And Peripheral Circuitry Isolation - A method of forming memory array and peripheral circuitry isolation includes chemical vapor depositing a silicon dioxide-comprising liner over sidewalls of memory array circuitry isolation trenches and peripheral circuitry isolation trenches formed in semiconductor material. Dielectric material is flowed over the silicon dioxide-comprising liner to fill remaining volume of the array isolation trenches and to form a dielectric liner over the silicon dioxide-comprising liner in at least some of the peripheral isolation trenches. The dielectric material is furnace annealed at a temperature no greater than about 500° C. The annealed dielectric material is rapid thermal processed to a temperature no less than about 800° C. A silicon dioxide-comprising material is chemical vapor deposited over the rapid thermal processed dielectric material to fill remaining volume of said at least some peripheral isolation trenches. Other aspects are disclosed, including integrated circuitry resulting from the disclosed methods and integrated circuitry independent of method of manufacture. | 04-11-2013 |
20130168756 | SOURCE/DRAIN ZONES WITH A DELECTRIC PLUG OVER AN ISOLATION REGION BETWEEN ACTIVE REGIONS AND METHODS - Devices, memory arrays, and methods are disclosed. In an embodiment, one such device has a source/drain zone that has first and second active regions, and an isolation region and a dielectric plug between the first and second active regions. The dielectric plug may extend below upper surfaces of the first and second active regions and may be formed of a dielectric material having a lower removal rate than a dielectric material of the isolation region for a particular isotropic removal chemistry. | 07-04-2013 |
20130249050 | INTEGRATED CIRCUIT DEVICES AND METHODS OF FORMING MEMORY ARRAY AND PERIPHERAL CIRCUITRY ISOLATION - A method of forming memory array and peripheral circuitry isolation includes chemical vapor depositing a silicon dioxide-comprising liner over sidewalls of memory array circuitry isolation trenches and peripheral circuitry isolation trenches formed in semiconductor material. Dielectric material is flowed over the silicon dioxide-comprising liner to fill remaining volume of the array isolation trenches and to form a dielectric liner over the silicon dioxide-comprising liner in at least some of the peripheral isolation trenches. The dielectric material is furnace annealed at a temperature no greater than about 500° C. The annealed dielectric material is rapid thermal processed to a temperature no less than about 800° C. A silicon dioxide-comprising material is chemical vapor deposited over the rapid thermal processed dielectric material to fill remaining volume of said at least some peripheral isolation trenches. Other aspects are disclosed, including integrated circuitry resulting from the disclosed methods and integrated circuitry independent of method of manufacture. | 09-26-2013 |
20140003148 | THREE DIMENSIONAL NAND FLASH WITH SELF-ALIGNED SELECT GATE | 01-02-2014 |
20140252363 | THREE DIMENSIONAL MEMORY STRUCTURE - A method to fabricate a three dimensional memory structure includes forming an array stack, creating a layer of sacrificial material above the array stack, etching a hole through the layer of sacrificial material and the array stack, creating a pillar of semiconductor material in the hole to form at least two vertically stacked flash memory cells that use the pillar as a common body, removing at least some of the layer of sacrificial material around the pillar to expose a portion of the pillar, and forming a field effect transistor (FET) using the portion of the pillar as the body of the FET. | 09-11-2014 |
20150064871 | Forming Source/Drain Zones with a Delectric Plug Over an Isolation Region Between Active Regions - An embodiment includes forming an isolation region between first and second active regions in a semiconductor, forming an opening between the first and second active regions by removing a portion of the isolation region, and forming a dielectric plug within the opening so that the dielectric plug is between the first and second active regions and so that a portion of the dielectric plug extends below upper surfaces of the first and second active regions. The dielectric plug may be formed of a dielectric material having a lower removal rate than a dielectric material of the isolation region for a particular isotropic removal chemistry. | 03-05-2015 |
20150123189 | METHODS AND APPARATUSES HAVING MEMORY CELLS INCLUDING A MONOLITHIC SEMICONDUCTOR CHANNEL - Methods for forming a string of memory cells, apparatuses having a string of memory cells, and systems are disclosed. One such method for forming a string of memory cells forms a source material over a substrate. A capping material may be formed over the source material. A select gate material may be formed over the capping material. A plurality of charge storage structures may be formed over the select gate material in a plurality of alternating levels of control gate and insulator materials. A first opening may be formed through the plurality of alternating levels of control gate and insulator materials, the select gate material, and the capping material. A channel material may be formed along the sidewall of the first opening. The channel material has a thickness that is less than a width of the first opening, such that a second opening is formed by the semiconductor channel material. | 05-07-2015 |
20150333085 | THREE DIMENSIONAL MEMORY STRUCTURE - A method to fabricate a three dimensional memory structure includes forming an array stack, creating a layer of sacrificial material above the array stack, etching a hole through the layer of sacrificial material and the array stack, creating a pillar of semiconductor material in the hole to form at least two vertically stacked flash memory cells that use the pillar as a common body, removing at least some of the layer of sacrificial material around the pillar to expose a portion of the pillar, and forming a field effect transistor (FET) using the portion of the pillar as the body of the FET. | 11-19-2015 |