Showing papers by "Chandra Mouli published in 2001"

Method of fabricating an isolation structure on a semiconductor substrate

Abstract: A method of forming an isolated structure of sufficient size to permit the fabrication of an active device thereon is comprised of the steps of depositing a gate oxide layer on a substrate. Material, such as a polysilicon layer and a nitride layer, is deposited on the gate oxide layer to protect the gate oxide layer. An active area is defined, typically by patterning a layer of photoresist. The protective material, the layer of oxide, and finally the substrate are etched to form a trench around the active area. Spacers are formed on the sides of the active area. The substrate is etched to deepen the trench around the active area to a point below the spacers. The substrate is oxidized at the bottom of the trench and horizontally under the active area to at least partially isolate the active area from the substrate. Oxide spacers are formed on the sides of the active area to fill exposed curved oxide regions and the remainder of the trench may be filled with an oxide.

Method of making insulator for electrical structures

Abstract: Structures and methods are disclosed for insulating a polysilicon gate adjacent to an electrically active region with a silicon base layer. A layer of silicon nitride having a thickness in a range from about 100 Å to about 150 Å is conformally deposited over the polysilicon gate. A layer of silicon dioxide is formed over the layer of silicon nitride on the polysilicon gate. The layer of silicon dioxide is subjected to a spacer etch to form spacers upon the layer of silicon nitride and on lateral sidewalls of the polysilicon gate. A portion of the layer of silicon nitride situated between the polysilicon gate and the spacer is removed by an etching process that is selective to silicon dioxide and to polysilicon. The etch forms a recess defined between the polysilicon gate, and each respective spacer. A cover layer is formed to close an opening to the recess so as to enclose a void therein. Alternatively, the etch can be a series of selective etches that extends the recess into the silicon base layer, after which the silicon base layer is implanted so that the recess isolates electrically active areas in the silicon base layer. A void is then enclosed below the opening to the recess within the silicon base layer by a cover layer deposited non-conformally thereover.

Methods of forming field effect transistors and field effect transistor circuitry

Abstract: Methods of forming field effect transistors and resultant field effect transistor circuitry are described. In one embodiment, a semiconductive substrate includes a field effect transistor having a body. A first resistive element is received by the substrate and connected between the transistor's gate and the body. A second resistive element is received by the substrate and connected between the body and a reference voltage node. The first and second resistive elements form a voltage divider which is configured to selectively change threshold voltages of the field effect transistor with state changes in the gate voltage. In a preferred embodiment, first and second diode assemblies are positioned over the substrate and connected between the gate and body, and the body and a reference voltage node to provide the voltage divider.

Field effect transistor assemblies, integrated circuitry, and methods of forming field effect transistors and integrated circuitry

Abstract: The invention encompasses integrated circuitry which includes a semiconductive material substrate and a first field effect transistor supported by the substrate. The first field effect transistor comprises a first transistor gate assembly which includes a first layer of conductively doped semiconductive material and only one layer of conductive nitride. The integrated circuitry further comprises a second field effect transistor supported by the substrate. The second field effect transistor comprises a second transistor gate assembly which includes a second layer of conductively doped semiconductor material and at least two layers of conductive nitride. The invention also encompasses a field effect transistor assembly which includes a channel region and an insulative material along the channel region. The transistor assembly further includes a gate stack proximate the channel region. The gate stack includes a first conductive nitride layer separated from the channel region by the insulative material. The stack further includes a conductively doped semiconductive material proximate the first conductive nitride layer, and a second conductive nitride layer separated from the first conductive nitride layer by the conductively doped semiconductive material. Additionally, the invention encompasses methods of forming field effect transistors, and methods of forming integrated circuitry.

Semiconductor raised source-drain structure

Abstract: A semiconductor structure which includes a raised source and a raised drain. The structure also includes a gate located between the source and drains. The gate defines a first gap between the gate and the source and a second gap between the gate and the drain.

Methods of forming field effect transistors; methods of forming DRAM circuitry

Abstract: Embodiments of the present invention provide methods of forming field effect transistors (FETs) that include at least partially forming a patterned transistor gate stack, at least partially defining a channel region therebeneath, and at least partially forming source/drain regions operably adjacent the gate stack and the channel region. Such embodiments include conducting one or more ion implantations through the at least partially formed gate stack and the at least partially formed source/drain regions to appropriately form Vt adjust regions within the channel regions and minority carrier barrier regions below formed, or to be formed, source/drain regions. Some embodiments of the present invention encompass forming such regions for memory FETs employed in DRAM or other memory circuitry.

Methods of forming field effect transistors and integrated circuitry including TiN gate element

Abstract: The invention encompasses integrated circuitry which includes a semiconductive material substrate and a first field effect transistor supported by the substrate. The first field effect transistor comprises a first transistor gate assembly which includes a first layer of conductively doped semiconductive material and only one layer of conductive nitride. The integrated circuitry further comprises a second field effect transistor supported by the substrate. The second field effect transistor comprises a second transistor gate assembly which includes a second layer of conductively doped semiconductor material and at least two layers of conductive nitride. The invention also encompasses a field effect transistor assembly which includes a channel region and an insulative material along the channel region. The transistor assembly further includes a gate stack proximate the channel region. The gate stack includes a first conductive nitride layer separated from the channel region by the insulative material. The stack further includes a conductively doped semiconductive material proximate the first conductive nitride layer, and a second conductive nitride layer separated from the first conductive nitride layer by the conductively doped semiconductive material. Additionally, the invention encompasses methods of forming field effect transistors, and methods of forming integrated circuitry.

***WITHDRAWN PATENT AS PER THE LATEST USPTO WITHDRAWN LIST***Isolated structure and method of fabricating such a structure on a substrate

Abstract: A method of forming an isolated structure of sufficient size to permit the fabrication of an active device thereon is comprised of the steps of depositing a gate oxide layer on a substrate. Material, such as a polysilicon layer and a nitride layer, is deposited on the gate oxide layer to protect the gate oxide layer. An active area is defined, typically by patterning a layer of photoresist. The protective material, the layer of oxide, and finally the substrate are etched to form a trench around the active area. Spacers are formed on the sides of the active area. The substrate is etched to deepen the trench around the active area to a point below the spacers. The substrate is oxidized at the bottom of the trench and horizontally under the active area to at least partially isolate the active area from the substrate. Oxide spacers are formed on the sides of the active area to fill exposed curved oxide regions and the remainder of the trench may be filled with an oxide.