Abstract: An integrated circuit transistor is fabricated with a trench gate having nonconductive sidewalls. The transistor is surrounded by an isolation trench filled with a nonconductive material. The sidewalls of the gate trench are formed of the nonconductive material and are substantially free of unetched substrate material. As a result, the sidewalls of the gate trench do not form an undesired conductive path between the source and the drain of the transistor, thereby advantageously reducing the amount of parasitic current that flows between the source and drain during operation.

Abstract: A multi-state NAND memory cell is comprised of two drain/source areas in a substrate. An oxide-nitride-oxide structure is formed above the substrate between the drain/source areas. The nitride layer acting as an asymmetric charge trapping layer. A control gate is located above the oxide-nitride-oxide structure. An asymmetrical bias on the drain/source areas causes the drain/source area with the higher voltage to inject an asymmetric distribution hole by gate induced drain leakage injection into the trapping layer substantially adjacent that drain/source area.

Abstract: Multi-layer memory arrays and methods are provided. A memory array has two or more layers of memory material, each layer of memory material having an array of memory cells. A first contact penetrates through each layer of memory material in a first plane and is electrically connected to each layer of memory material so as to electrically interconnect the layers of memory material in the first plane. A second contact penetrates through at least one of the layers of memory material in a second plane substantially perpendicular to the first plane.

Abstract: Floating-gate field-effect transistors or memory cells formed in isolated wells are useful in the fabrication of non-volatile memory arrays and devices. A column of such floating-gate memory cells are associated with a well containing the source/drain regions for each memory cell in the column. These wells are isolated from source/drain regions of other columns of the array. Fowler-Nordheim tunneling can be used to program and erase such floating-gate memory cells either on an individual basis or on a bulk or block basis.

Abstract: A method for forming a flash memory device having a local interconnect connecting source regions of a plurality of transistors within a sector allows for a highly selective wet etch of a dielectric region overlying the source region. An embodiment of the method comprises the use of an etch-resistant layer covering various features such as any gate oxide remaining over the source region, spacers along sidewalls of the transistor stacks, and a capping layer of the transistor. An in-process semiconductor device resulting from the inventive method is also disclosed.

Abstract: An integrated circuit transistor is fabricated with a trench gate having nonconductive sidewalls. The transistor is surrounded by an isolation trench filled with a nonconductive material. The sidewalls of the gate trench are formed of the nonconductive material and are substantially free of unetched substrate material. As a result, the sidewalls of the gate trench do not form an undesired conductive path between the source and the drain of the transistor, thereby advantageously reducing the amount of parasitic current that flows between the source and drain during operation.

Abstract: The invention encompasses methods of forming insulating materials between conductive elements. In one aspect, the invention includes a method of forming a material adjacent a conductive electrical component comprising: a) partially vaporizing a mass to form a matrix adjacent the conductive electrical component, the matrix having at least one void within it. In another aspect, the invention includes a method of forming a material between a pair of conductive electrical components comprising the following steps: a) forming a pair of conductive electrical components within a mass and separated by an expanse of the mass; b) forming at least one support member within the expanse of the mass, the support member not comprising a conductive interconnect; and c) vaporizing the expanse of the mass to a degree effective to form at least one void between the support member and each of the pair of conductive electrical components.

Abstract: A method of forming a memory transistor includes providing a substrate comprising semiconductive material and forming spaced-apart source/drain structures. At least one of the source/drain structures forms a Schottky contact to the semiconductive material. The method also includes forming a memory gate between the spaced-apart source/drain structures and forming a control gate disposed operatively over the memory gate.

Abstract: An integrated circuit transistor is fabricated with a trench gate having nonconductive sidewalls. The transistor is surrounded by an isolation trench filled with a nonconductive material. The sidewalls of the gate trench are formed of the nonconductive material and are substantially free of unetched substrate material. As a result, the sidewalls of the gate trench do not form an undesired conductive path between the source and the drain of the transistor, thereby advantageously reducing the amount of parasitic current that flows between the source and drain during operation.

Abstract: Methods and apparatus are described to facilitate forming memory devices with low resistance polysilicon local interconnects that allow a smaller array feature size and therefore facilitate forming arrays of a denser array format. Embodiments of the present invention are formed utilizing a wet etch process that has a high selectivity, allowing the deposition and etching of polysilicon local interconnects to source regions of array transistors. By providing for a local interconnect of polysilicon, a smaller source region and/or drain region can also be utilized, further decreasing the required word line spacing. Low resistance polysilicon local source interconnects can also couple to an increased number of memory cells, thereby reducing the number of contacts made to an array ground.

Abstract: Floating-gate field-effect transistors or memory cells formed in isolated wells are useful in the fabrication of non-volatile memory arrays and devices. A column of such floating-gate memory cells are associated with a well containing the source/drain regions for each memory cell in the column. These wells are isolated from source/drain regions of other columns of the array. Fowler-Nordheim tunneling can be used to program and erase such floating-gate memory cells either on an individual basis or on a bulk or block basis.

Abstract: A method is provided for programming a memory cell of an electrically erasable programmable read only memory. The memory cell is fabricated on a substrate and comprises a source region, a drain region, a floating gate, and a control gate. The memory cell has a threshold voltage selectively configurable into one of at least three programming states. The method includes generating a drain current between the drain region and the source region by applying a drain-to-source bias voltage between the drain region and the source region. The method further includes injecting hot electrons from the drain current to the floating gate by applying a gate voltage to the control gate. A selected threshold voltage for the memory cell corresponding to a selected one of the programming states is generated by applying a selected constant drain-to-source bias voltage and a selected gate voltage.

Abstract: A method is provided for programming a memory cell of an electrically erasable programmable read only memory. The memory cell is fabricated on a substrate and comprises a source region, a drain region, a floating gate, and a control gate. The memory cell has a threshold voltage selectively configurable into one of at least three programming states. The method includes generating a drain current between the drain region and the source region by applying a drain-to-source bias voltage between the drain region and the source region. The method further includes injecting hot electrons from the drain current to the floating gate by applying a gate voltage to the control gate. A selected threshold voltage for the memory cell corresponding to a selected one of the programming states is generated by applying a selected constant drain-to-source bias voltage and a selected gate voltage.

Abstract: The present invention provides a method and apparatus for forming a double-doped polysilicon floating gate in a semiconductor memory element. The method includes forming a first dielectric layer on a semiconductor substrate and forming a floating gate above the first dielectric layer, the floating gate comprised of a first layer doped with a first type of dopant material and a second layer doped with a second type of dopant material that is opposite the first type of dopant material in the first layer. The method further includes forming a second dielectric layer above the floating gate, forming a control gate above the second dielectric layer, and forming a source and a drain in the substrate.

Abstract: This invention is a process for manufacturing a random access memory array. Each memory cell within the array which results from the process incorporates a stacked capacitor, a silicon nitride coated access transistor gate electrode, and a self-aligned high-aspect-ratio digit line contact having a tungsten plug which extends from the substrate to a metal interconnect structure located at a level above the stacked capacitor. The contact opening is lined with titanium metal which is in contact with the substrate, and with titanium nitride that is in contact with the plug. Both the titanium metal and the titanium nitride are deposited via chemical vapor deposition reactions.

Abstract: Methods and devices are disclosed which provide for memory devices having reduced memory cell square feature sizes. Such square feature sizes can permit large memory devices, on the order of a gigabyte or large, to be fabricated on one chip or die. The methods and devices disclosed, along with variations of them, utilize three dimensions as opposed to other memory devices which are fabricated in only two dimensions. Thus, the methods and devices disclosed, along with variations, contains substantially horizontal and vertical components.

Abstract: Methods and devices are disclosed which provide for memory devices having reduced memory cell square feature sizes. Such square feature sizes can permit large memory devices, on the order of a gigabyte or large, to be fabricated on one chip or die. The methods and devices disclosed, along with variations of them, utilize three dimensions as opposed to other memory devices which are fabricated in only two dimensions. Thus, the methods and devices disclosed, along with variations, contains substantially horizontal and vertical components.

Abstract: Floating-gate field-effect transistors or memory cells formed in isolated wells are useful in the fabrication of non-volatile memory arrays and devices. A column of such floating-gate memory cells are associated with a well containing the source/drain regions for each memory cell in the column. These wells are isolated from source/drain regions of other columns of the array. Fowler-Nordheim tunneling can be used to program and erase such floating-gate memory cells either on an individual basis or on a bulk or block basis.

Abstract: Floating-gate field-effect transistors or memory cells formed in isolated wells are useful in the fabrication of non-volatile memory arrays and devices. A column of such floating-gate memory cells are associated with a well containing the source/drain regions for each memory cell in the column. These wells are isolated from source/drain regions of other columns of the array. Fowler-Nordheim tunneling can be used to program and erase such floating-gate memory cells either on an individual basis or on a bulk or block basis.

Abstract: This invention is a process for manufacturing a random access memory array. Each memory cell within the array which results from the process incorporates a stacked capacitor, a silicon nitride-coated access transistor gate electrode, and a self-aligned high-aspect-ratio digit line contact having a tungsten plug which extends from the substrate to a metal interconnect structure located at a level above the stacked capacitor. The contact opening is lined with titanium metal that is in contact with the substrate and with titanium nitride that is in contact with the plug. Both the titanium metal and the titanium nitride are deposited via chemical vapor deposition reactions.