Abstract: Methods of fabricating memory are disclosed. For example, a method includes fabricating rows of memory cells on pillars separated by isolation regions therebetween. Each pillar has a pair of memory cells, each on an opposite side thereof. The method also includes fabricating control gates substantially between the rows of memory cells, each control gate to control half the cells of each of its adjacent rows of memory cells, and fabricating word lines for the array, the word lines extending substantially parallel to the control gates for the cells.

Abstract: A relaxed metal pitch architecture may include a bit line and a first active area string and a second active area string. The bit line may be directly coupled to the first active area string and to the second active area string. The relaxed metal pitch architecture may be applied to a non-volatile memory structure.

Abstract: A relaxed metal pitch architecture may include a bit line and a first active area string and a second active area string. The bit line may be directly coupled to the first active area string and to the second active area string. The relaxed metal pitch architecture may be applied to a non-volatile memory structure.

Abstract: Methods of fabricating memory are disclosed. For example, a method includes fabricating rows of memory cells on pillars separated by isolation regions therebetween. Each pillar has a pair of memory cells, each on an opposite side thereof. The method also includes fabricating control gates substantially between the rows of memory cells, each control gate to control half the cells of each of its adjacent rows of memory cells, and fabricating word lines for the array, the word lines extending substantially parallel to the control gates for the cells.

Abstract: A floating gate memory cell includes isolation regions between adjacent cells, and a staggered pattern of columns of cells. Word lines are formed parallel to control gate structures.

Abstract: An anti-reflective coating (ARC) is formed over the various layers involved in a cell fabrication process. The ARC is selectively etched such that the edges of the etched areas of the ARC slope downward at an angle determined by the thickness of the ARC. The etching process could include CF4 chemistry. The inner edges of the sloped ARC areas reduce the original photo-defined space since the underlying layers are now defined by the sloped edges.

Abstract: A floating gate memory cell includes isolation regions between adjacent cells, and a staggered pattern of columns of cells. Word lines are formed parallel to control gate structures.

Abstract: A NAND memory array has a substrate, a source select gate formed on the substrate, and a drain select gate formed on the substrate. A string of floating-gate memory cells is formed on the substrate and is connected in series between the source select gate and the drain select gate. A drain contact has a head connected substantially perpendicularly to a stem. The head is aligned with the drain select gate and overlies a dielectric layer formed on the drain select gate. The stem overlies a polysilicon plug formed on the substrate. A bit line contact is in direct electrical contact with the head.

Abstract: Methods and apparatus are provided. A source slot and a drain contact region are formed at opposite ends of a NAND string disposed on a substrate of a NAND memory array using a single mask. The drain contact region is self-aligned to a drain select gate. The NAND string has a plurality of memory cells connected in series.

Abstract: A relaxed metal pitch architecture may include a bit line and a first active area string and a second active area string. The bit line may be directly coupled to the first active area string and to the second active area string. The relaxed metal pitch architecture may be applied to a non-volatile memory structure.

Abstract: A NAND memory device has a source line connected to two or more columns of serially-connected floating-gate transistors. The source line includes a first conductive layer formed on a substrate and coupled to source select gates associated with the two or more columns of serially-connected floating-gate transistors. The source line also includes a second conductive layer formed on the first conductive layer, where the second layer has a greater electrical conductivity than the first conductive layer.

Abstract: A NAND memory device has a source line connected to two or more columns of serially-connected floating-gate transistors. The source line includes a first conductive layer formed on a substrate and coupled to source select gates associated with the two or more columns of serially-connected floating-gate transistors. The source line also includes a second conductive layer formed on the first conductive layer, where the second layer has a greater electrical conductivity than the first conductive layer.

Abstract: An anti-reflective coating (ARC) is formed over the various layers involved in a cell fabrication process. The ARC is selectively etched such that the edges of the etched areas of the ARC slope downward at an angle determined by the thickness of the ARC. The etching process could include CF4 chemistry. The inner edges of the sloped ARC areas reduce the original photo-defined space since the underlying layers are now defined by the sloped edges.

Abstract: A source line is formed by forming a source slot in a bulk insulation layer overlying a substrate to expose a portion of a substrate within the source slot, where the exposed portion of the substrate includes source regions of select gates associated with two or more columns of serially-connected floating-gate transistors formed on the substrate. A layer of epitaxial silicon is grown on the exposed portion so as to partially fill the source slot. A conductive layer is formed on the bulk insulation layer and on the layer of epitaxial silicon so as to substantially fill an unfilled portion of the source slot. The conductive layer is removed from a surface of the bulk insulation layer.

Abstract: Methods and apparatus utilizing epitaxial silicon growth on a base structure of a floating gate of a floating-gate memory cell to increase the available coupling area of the floating gate while reducing the spacing between adjacent memory cells. The epitaxial silicon growth facilitates a reduction in spacing between adjacent cells beyond the capability of the patterning technology, e.g., photolithography.

Abstract: Methods and apparatus are provided. A NAND memory device has a source line connected to two or more columns of serially-connected floating-gate transistors. The source line includes a first conductive layer formed on a substrate and coupled to source select gates associated with the two or more columns of serially-connected floating-gate transistors. The source line also includes a second conductive layer formed on the first conductive layer, where the second layer has a greater electrical conductivity than the first conductive layer.

Abstract: A floating gate memory cell includes isolation regions between adjacent cells, and a staggered pattern of columns of cells. Word lines are formed parallel to control gate structures.

Abstract: A method of forming an array of FLASH field effect transistors and circuitry peripheral to such array includes forming a sacrificial oxide over an array area and a periphery area of a semiconductor substrate. After forming the sacrificial oxide, at least one conductivity modifying implant is conducted into semiconductive material of the substrate within the array without conducting the one conductivity modifying implant into semiconductive material of the substrate within the periphery. The sacrificial oxide is removed from the array while the sacrificial oxide is left over the periphery. After removing the sacrificial oxide from the array, at least some FLASH transistor gates are formed within the array and at least some non-FLASH transistor gates are formed within the periphery.

Abstract: Thermal oxidation of a peripheral area of a semiconductor substrate is globally restricted with an overlying oxidation resistant layer that is not globally received within the array during formation of a sacrificial oxide layer prior to forming any transistor gate dielectric layer within the array. At least some FLASH field effect transistor gates having floating gate dielectric of a first thickness are formed within the array and at least some non-FLASH field effect transistor gates having gate dielectric of a second thickness are formed within the periphery, with the first and second thicknesses being different. Other aspects and implementations are disclosed.

Abstract: A floating gate memory cell includes isolation regions between adjacent cells, and a staggered pattern of columns of cells. Word lines are formed parallel to control gate structures.