Abstract: An integrated circuit includes a substrate pump circuit developing an internal back-bias voltage on an output, and an external terminal adapted to receive an external back-bias voltage. A semiconductor substrate is coupled to the external terminal and to the output of the substrate pump circuit. The semiconductor substrate includes at least one transistor formed in the semiconductor substrate which has a first threshold voltage when the internal back-bias voltage is applied to the substrate. The at least one transistor has a second threshold voltage greater than the first threshold voltage when the external back-bias voltage is received on the external terminal.

Abstract: Methods of forming conductive lines and insulative spacers thereover are described. In accordance with one aspect of the invention, a substrate is provided having a first area and a second area relative to which conductive lines are to be formed. A layer of conductive material is formed over the first and second substrate areas and a layer of insulative material is formed over the conductive material. In a preferred implementation, insulative material is removed from the second area and conductive lines are subsequently patterned and etched in both the first and second areas. In another preferred implementation, conductive lines are first patterned and etched with insulative material in the second area being subsequently removed. The patterned and etched conducted lines have respective sidewalls.

Abstract: An integrated circuit includes a substrate pump circuit developing an internal back-bias voltage on an output, and an external terminal adapted to receive an external back-bias voltage. A semiconductor substrate is coupled to the external terminal and to the output of the substrate pump circuit. The semiconductor substrate includes at least one transistor formed in the semiconductor substrate which has a first threshold voltage when the internal back-bias voltage is applied to the substrate. The at least one transistor has a second threshold voltage greater than the first threshold voltage when the external back-bias voltage is received on the external terminal.

Abstract: The invention encompasses methods of forming individual silicon-on-insulator layers having varying thicknesses within the individual layers. The invention also encompasses methods of forming transistor devices from silicon-on insulator layers. Additionally, the invention encompasses semicondutor devices and assemblies utilizing silicon-on-insulator layers.

Abstract: An integrated circuit includes a substrate pump circuit developing an internal back-bias voltage on an output, and an external terminal adapted to receive an external back-bias voltage. A semiconductor substrate is coupled to the external terminal and to the output of the substrate pump circuit. The semiconductor substrate includes at least one transistor formed in the semiconductor substrate which has a first threshold voltage when the internal back-bias voltage is applied to the substrate. The at least one transistor has a second threshold voltage greater than the first threshold voltage when the external back-bias voltage is received on the external terminal.

Abstract: Integrated circuitry fuse forming methods, integrated circuity programming methods, and related integrated circuitry are described. In one implementation, a first layer comprising a first conductive material is formed over a substrate. A second layer comprising a second conductive material different from the first conductive material is formed over the first layer and in conductive connection therewith. A fuse area is formed by removing at least a portion of one of the first and second layers. In a preferred aspect, an assembly of layers comprising one layer disposed intermediate two conductive layers is provided. At least a portion of the one layer is removed from between the two layers to provide a void therebetween. In another aspect, programming circuitry is provided over a substrate upon which the assembly of layers is provided.

Abstract: Methods of forming conductive lines and insulative spacers thereover are described. In accordance with one aspect of the invention, a substrate is provided having a first area and a second area relative to which conductive lines are to be formed. A layer of conductive material is formed over the first and second substrate areas and a layer of insulative material is formed over the conductive material. In a preferred implementation, insulative material is removed from the second area and conductive lines are subsequently patterned and etched in both the first and second areas. In another preferred implementation, conductive lines are first patterned and etched with insulative material in the second area being subsequently removed. The patterned and etched conducted lines have respective sidewalls.

Abstract: A semiconductor substrate structure includes a conductor supported by a substrate, and has an outer surface and a pair of spaced-apart conductive sidewalls joining with the outer surface at respective corners. A first layer of material is disposed over the substrate over all of one of the sidewalls, over only a portion of the outer surface and over only a portion of the other sidewall. The first layer of material has a generally uniform thickness over the conductor outer surface, the conductive sidewalls and the corners. A second layer of material having a generally non-uniform thickness is disposed over the substrate. Such has a non-planar outer surface, and an opening therethrough to the conductor's outer surface and the other sidewall which do not have first layer material disposed thereover.

Abstract: The invention encompasses methods of forming individual silicon-on-insulator layers having varying thicknesses within the individual layers. The invention also encompasses methods of forming transistor devices from silicon-on-insulator layers. Additionally, the invention encompasses semiconductor devices and assemblies utilizing silicon-on-insulator layers. The invention includes a method comprising: a) providing a substrate; b) providing an insulator layer over the substrate; c) providing a semiconductive layer over the insulator layer, the semiconductive layer having a first portion and a second portion; d) forming a depletion region within the semiconductive layer and proximate the insulator layer, the depletion region having a different thickness in the first portion than in the second portion; and f) etching the semiconductive layer to about the depletion region.

Abstract: Integrated circuitry fuse forming methods, integrated circuitry programming methods, and related integrated circuitry are described. In one implementation, a first layer comprising a first conductive material is formed over a substrate. A second layer comprising a second conductive material different from the first conductive material is formed over the first layer and in conductive connection therewith. A fuse area is formed by removing at least a portion of one of the first and second layers. In a preferred aspect, an assembly of layers comprising one layer disposed intermediate two conductive layers is provided. At least a portion of the one layer is removed from between the two layers to provide a void therebetween. In another aspect, programming circuitry is provided over a substrate upon which the assembly of layers is provided.

Abstract: The invention encompasses methods of forming individual silicon-on-insulator layers having varying thicknesses within the individual layers. The invention also encompasses methods of forming transistor devices from silicon-on-insulator layers. Additionally, the invention encompasses semiconductor devices and assemblies utilizing silicon-on-insulator layers. The invention includes a method comprising: a) providing a substrate; b) providing an insulator layer over the substrate; c) providing a semiconductive layer over the insulator layer, the semiconductive layer having a first portion and a second portion; d) forming a depletion region within the semiconductive layer and proximate the insulator layer, the depletion region having a different thickness in the first portion than in the second portion; and f) etching the semiconductive layer to about the depletion region.

Abstract: Integrated circuitry fuse forming methods, integrated circuitry programming methods, and related integrated circuitry are described. In one implementation, a first layer comprising a first conductive material is formed over a substrate. A second layer comprising a second conductive material different from the first conductive material is formed over the first layer and in conductive connection therewith. A fuse area is formed by removing at least a portion of one of the first and second layers. In a preferred aspect, an assembly of layers comprising one layer disposed intermediate two conductive layers is provided. At least a portion of the one layer is removed from between the two layers to provide a void therebetween. In another aspect, programming circuitry is provided over a substrate upon which the assembly of layers is provided.

Abstract: Methods of forming conductive lines and insulative spacers thereover are described. In accordance with one aspect of the invention, a substrate is provided having a first area and a second area relative to which conductive lines are to be formed. A layer of conductive material is formed over the first and second substrate areas and a layer of insulative material is formed over the conductive material. In a preferred implementation, insulative material is removed from the second area and conductive lines are subsequently patterned and etched in both the first and second areas. In another preferred implementation, conductive lines are first patterned and etched with insulative material in the second area being subsequently removed. The patterned and etched conducted lines have respective sidewalls.

Abstract: Integrated circuitry fuse forming methods, integrated circuitry programming methods, and related integrated circuitry are described. In one implementation, a first layer comprising a first conductive material is formed over a substrate. A second layer comprising a second conductive material different from the first conductive material is formed over the first layer and in conductive connection therewith. A fuse area is formed by removing at least a portion of one of the first and second layers. In a preferred aspect, an assembly of layers comprising one layer disposed intermediate two conductive layers is provided. At least a portion of the one layer is removed from between the two layers to provide a void therebetween. In another aspect, programming circuitry is provided over a substrate upon which the assembly of layers is provided.

Abstract: An SRAM cell is described which has a reduced cell area, and a reduced processing cost from conventional SRAM's. A fabrication process is described where self-aligned contacts to substrate active area and contact to a first layer of polysilicon are formed in one etch step. Electrical connection between the substrate and polysilicon is provided through a conductive layer coupled to the contacts. Self aligned contacts are fabricated to contact the active area.

Abstract: Integrated circuitry fuse forming methods, integrated circuitry programming methods, and related integrated circuitry are described. In one implementation, a first layer comprising a first conductive material is formed over a substrate. A second layer comprising a second conductive material different from the first conductive material is formed over the first layer and in conductive connection therewith. A fuse area is formed by removing at least a portion of one of the first and second layers. In a preferred aspect, an assembly of layers comprising one layer disposed intermediate two conductive layers is provided. At least a portion of the one layer is removed from between the two layers to provide a void therebetween. In another aspect, programming circuitry is provided over a substrate upon which the assembly of layers is provided.

Abstract: An integrated circuit includes a substrate pump circuit developing an internal back-bias voltage on an output, and an external terminal adapted to receive an external back-bias voltage. A semiconductor substrate is coupled to the external terminal and to the output of the substrate pump circuit. The semiconductor substrate includes at least one transistor formed in the semiconductor substrate which has a first threshold voltage when the internal back-bias voltage is applied to the substrate. The at least one transistor has a second threshold voltage greater than the first threshold voltage when the external back-bias voltage is received on the external terminal.

Abstract: A method of fabricating integrated circuitry comprises forming a conductive line having opposing sidewalls over a semiconductor substrate. An insulating layer is then deposited. The insulating layer is etched proximate the line along at least a portion of at least one sidewall of the line. An insulating spacer forming layer is then deposited over the substrate and the line. It is anisotropically etched to form an insulating sidewall spacer. A method of forming a local interconnect comprises forming at least two transistor gates over a semiconductor substrate. A local interconnect layer is deposited to overlie at least one of the transistor gates and interconnect at least one source/drain region of one of the gates with semiconductor substrate material proximate another of the transistor gates.

Abstract: The invention encompasses methods of forming individual silicon-on-insulator layers having varying thicknesses within the individual layers. The invention also encompasses methods of forming transistor devices from silicon-on-insulator layers. Additionally, the invention encompasses semiconductor devices and assemblies utilizing silicon-on-insulator layers. The invention includes a method comprising: a) providing a substrate; b) providing an insulator layer over the substrate; c) providing a semiconductive layer over the insulator layer, the semiconductive layer having a first portion and a second portion; d) forming a depletion region within the semiconductive layer and proximate the insulator layer, the depletion region having a different thickness in the first portion than in the second portion; and f) etching the semiconductive layer to about the depletion region.

Abstract: In a flash memory, flash cells are paired off so each pair includes a memory cell for storing data and a query cell for storing a characteristic analog value representative of the erase or programming speed of the memory cell. To erase a memory cell, the value stored in the query cell with which it is associated is retrieved, the current state of the memory cell is read, and an erase pulse having a pulse width (or amplitude) that is a function of the value retrieved from the query cell and the current state of the memory cell is then sent to the memory cell to erase it. To program a data bit into a memory cell, the value stored in the query cell with which it is associated is retrieved, and a programming pulse having a pulse width that is a function of the data bit and the value retrieved from the query cell is then to the memory cell to program it.