Showing papers by "Chandra Mouli published in 2009"

Memory cells, memory cell constructions, and memory cell programming methods

Abstract: Some embodiments include memory cells including a memory component having a first conductive material, a second conductive material, and an oxide material between the first conductive material and the second conductive material. A resistance of the memory component is configurable via a current conducted from the first conductive material through the oxide material to the second conductive material. Other embodiments include a diode comprising metal and a dielectric material and a memory component connected in series with the diode. The memory component includes a magnetoresistive material and has a resistance that is changeable via a current conducted through the diode and the magnetoresistive material.

Memory devices, memory device constructions, constructions, memory device forming methods, current conducting devices, and memory cell programming methods

Abstract: Some embodiments include memory devices having a wordline, a bitline, a memory element selectively configurable in one of three or more different resistive states, and a diode configured to allow a current to flow from the wordline through the memory element to the bitline responsive to a voltage being applied across the wordline and the bitline and to decrease the current if the voltage is increased or decreased. Some embodiments include memory devices having a wordline, a bitline, memory element selectively configurable in one of two or more different resistive states, a first diode configured to inhibit a first current from flowing from the bitline to the wordline responsive to a first voltage, and a second diode comprising a dielectric material and configured to allow a second current to flow from the wordline to the bitline responsive to a second voltage.

1T/0C RAM cell with a wrapped-around gate device structure

Abstract: A memory device and a method of forming the memory device. The memory device comprises a storage transistor at a surface of a substrate comprising a body portion between first and second source/drain regions, wherein the source/drain regions are regions of a first conductivity type. The storage transistor also comprises a gate structure that wraps at least partially around the body portion in at least two spatial planes. A bit line is connected to the first source/drain region and a word line connected to the gate structure. The memory device does not require an additional capacitive storage element.

3D Simulation Study of Cell-Cell Interference in Advanced NAND Flash Memory

Abstract: A new Technology CAD (TCAD) methodology has been applied to accurately extract cell-cell interference. The new method uses a "DeltaVt ratio" model instead of the conventional "capacitance ratio" model. The new method will be introduced and validated by recent experimental data. The predictions of the cell-cell interference on sub-40 nm floating gate (FG) cells and charge trapped flash (CTF) cells will be discussed. Finally, the implications and challenges of Multilevel Cell (MLC) applications will be made.

Vertically-oriented semiconductor selection device for cross-point array memory

Abstract: A vertical semiconductor material mesa upstanding from a semiconductor base that forms a conductive channel between first and second doped regions. The first doped region is electrically coupled to one or more first silicide layers on the surface of the base. The second doped region is electrically coupled to a second silicide layer on the upper surface of the mesa. A gate conductor is provided on one or more sidewalls of the mesa.

Oc dram cell with increased sense margin

Abstract: A memory device and method of making the memory device. The memory device comprises a storage transistor at a surface of a substrate. The storage transistor comprises a body portion between first and second source/drain regions, wherein the source/drain regions are regions of a first conductivity type. The storage transistor also comprises a gate structure that wraps at least partially around the body portion in at least two spatial planes. A bit line is connected to the first source/drain region and a word line is connected to the gate structure.

Diodes, and methods of forming diodes

Abstract: Some embodiments include methods of forming diodes in which a first electrode is formed to have a pedestal extending upwardly from a base. At least one layer is deposited along an undulating topography that extends across the pedestal and base, and a second electrode is formed over the least one layer. The first electrode, at least one layer, and second electrode together form a structure that conducts current between the first and second electrodes when voltage of one polarity is applied to the structure, and that inhibits current flow between the first and second electrodes when voltage having a polarity opposite to said one polarity is applied to the structure. Some embodiments include diodes having a first electrode that contains two or more projections extending upwardly from a base, having at least one layer over the first electrode, and having a second electrode over the at least one layer.

Methods of forming and programming floating-gate memory cells having carbon nanotubes

Abstract: Floating-gate memory cells having carbon nanotubes interposed between the substrate and the tunnel dielectric layer facilitate ballistic injection of charge into the floating gate. The carbon nanotubes may extend across the entire channel region or a portion of the channel region. For some embodiments, the carbon nanotubes may be concentrated near the source/drain regions. For some embodiments, the tunnel dielectric layer may adjoin the substrate in at least a portion of the channel region.

Methods of forming semiconductor packages

Abstract: The invention includes semiconductor packages having grooves within a semiconductor die backside; and includes semiconductor packages utilizing carbon nanostructures (such as, for example, carbon nanotubes) as thermally conductive interface materials. The invention also includes methods of cooling a semiconductor die in which coolant is forced through grooves in a backside of the die, and includes methods of making semiconductor packages.

Memory cells, and methods of forming memory cells

Abstract: Some embodiments include memory cells that contain floating bodies and diodes. The diodes may be gated diodes having sections doped to a same conductivity type as the floating bodies, and such sections of the gated diodes may be electrically connected to the floating bodies. The floating bodies may be adjacent channel regions, and spaced from the channel regions by a dielectric structure. The dielectric structure of a memory cell may have a first portion between the floating body and the diode, and may have a second portion between the floating body and the channel region. The first portion may be more leaky to charge carriers than the second portion. The diodes may be formed in semiconductor material that is different from a semiconductor material that the channel regions are in. The floating bodies may have bulbous lower regions. Some embodiments include methods of making memory cells.

Using TCAD, Response Surface Model and Monte Carlo Methods to Model Processes and Reduce Device Variation

Abstract: Reduction of electrical parameter variation is essential to achieve high yield and reliability in semiconductor devices. However, variation depends on a large number of process factors, which are often interdependent. In this work, well-calibrated Technology Computer-Aided-Design process and device simulations were performed in a designed experiment to develop an efficient, surrogate response surface model (RSM) of the device parameters as a function of key process factors. Monte Carlo simulations were performed with the RSM to estimate variation and design systems to reduce variation. The approach, illustrated here specifically for peripheral n-type field-effect transistors in a dynamic random-access-memory process flow, is general, easy-to-implement, and a cost-effective way to systematically identify, model, and analyze process variation.

Structures for resistance random access memory and methods of forming the same

Abstract: Memory cells and methods of forming the same and devices including the same. The memory cells have first and second electrodes. An amorphous semiconductor material capable of electronic switching and having a first band gap is between the first and second electrodes. A material is in contact with the semiconductor material and having a second band gap, the second band gap greater than the first band gap.