Showing papers by "Chandra Mouli published in 2016"

Switching Dynamics and Hot Atom Damage in Landau Switches

Abstract: Among the various sub-60 mV/decade transistors proposed to reduce the supply voltage (and thereby, power dissipation) of an integrated circuit, a Landau switch achieves this goal by amplifying the gate voltage by replacing the gate dielectric (DE) with a ferroelectric (FE) that exhibits negative capacitance. The subthreshold swing (S) and power dissipation are indeed reduced, but one wonders if switching speed would suffer at the low operating voltage, and if the reliability would degrade due to polarization switching. Based on the coupled kinetics of FE–DE switching, and using the existing experimental data for the FE properties in doped HfO2, we predict that an FE Landau transistor would switch as fast as and would be more robust to hot atom damage-induced ac reliability degradation observed in the FE memory. These results encourage sustained development of this technology option.

Integrated structures comprising vertical channel material and having conductively-doped semiconductor material directly against lower sidewalls of the channel material

Abstract: Some embodiments include an integrated structure having vertically-stacked conductive levels. Upper conductive levels are memory cell levels, and a lower conductive level is a select device level. Conductively-doped semiconductor material is under the select device level. Channel material extends along the memory cell levels and the select device level, and extends into the conductively-doped semiconductor material. A region of the channel material that extends into the conductively-doped semiconductor material is a lower region of the channel material and has a vertical sidewall. Tunneling material, charge-storage material and charge-blocking material extend along the channel material and are between the channel material and the conductive levels. The tunneling material, charge-storage material and charge-blocking material are not along at least a portion of the vertical sidewall of the lower region of the channel material, and the conductively-doped semiconductor material is directly against such portion. Some embodiments include methods of forming integrated structures.

Transistors and methods of forming transistors

Abstract: Some embodiments include a transistor having a drain region and a source region. A conductive gate is between the source and drain regions. First channel material is between the gate and the source region. The first channel material is spaced from the gate by one or more insulative materials. Second channel material is between the first channel material and the source region, and directly contacts the source region. The first and second channel materials are transition metal chalcogenide. One of the source and drain regions is a hole reservoir region and the other is an electron reservoir region. Tunnel dielectric material may be between the first and second channel materials.

Integrated structures containing vertically-stacked memory cells

Abstract: Some embodiments include an integrated structure having a stack of alternating dielectric levels and conductive levels, and having vertically-stacked memory cells within the conductive levels. An opening extends through the stack. Channel material is within the opening and along the memory cells. At least some of the channel material contains germanium.

Memory Devices and Memory Device Forming 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.

***WITHDRAWN PATENT AS PER THE LATEST USPTO WITHDRAWN LIST***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.