Abstract: A memory device structure includes a vertical transistor having a channel between a source and a drain, a gate electrode adjacent the channel, where the gate electrode is in a first direction orthogonal to a longitudinal axis of the channel. A gate dielectric layer is between the gate electrode and the channel A first terminal of a first interconnect is coupled with the source or the drain, where the first interconnect is colinear with the longitudinal axis. The memory device structure further includes a pair of memory cells, where individual ones of the memory cells includes a selector and a memory element, where a first terminal of the individual ones of the memory cell is coupled to a respective second and a third terminal of the first interconnect. A second terminal of the individual ones of the memory cell is coupled to individual ones of the pair of second interconnects.

Abstract: A memory device structure includes a first plurality of line structures, where each line structure, in the first plurality of line structures, includes a first transistor channel. The memory device structure further includes a second plurality of line structures substantially orthogonal to the first plurality of line structures, where each line structure, in the second plurality of line structures, includes a second transistor channel A memory cell is at each cross-point between the first plurality of line structures and the second plurality of line structures.

Abstract: A method for selectively removing nano-crystals on an insulating layer. The method includes providing an insulating layer with nano-crystals thereon; exposing the nano-crystals to a high density plasma comprising a source of free radical chlorine, ionic chlorine, or both to modify the nano-crystals; and removing the modified nano-crystals with a wet etchant.

Abstract: Methods of forming a metal oxide surface that is enriched with metal oxide in its higher oxidation state are provided. A metal oxide surface that is enriched with metal oxide in its higher oxidation state is also provided.

Abstract: A method for selectively removing nano-crystals on an insulating layer. The method includes providing an insulating layer with nano-crystals thereon; exposing the nano-crystals to a high density plasma comprising a source of free radical chlorine, ionic chlorine, or both to modify the nano-crystals; and removing the modified nano-crystals with a wet etchant.

Abstract: A method for selectively removing nano-crystals on an insulating layer. The method includes providing an insulating layer with nano-crystals thereon; exposing the nano-crystals to a high density plasma comprising a source of free radical chlorine, ionic chlorine, or both to modify the nano-crystals; and removing the modified nano-crystals with a wet etchant.

Abstract: A memory device comprising one or more recessed channel select gates and at least one charge trapping layer.

Abstract: A method for selectively removing nano-crystals on an insulating layer. The method includes providing an insulating layer with nano-crystals thereon; exposing the nano-crystals to a high density plasma comprising a source of free radical chlorine, ionic chlorine, or both to modify the nano-crystals; and removing the modified nano-crystals with a wet etchant.

Abstract: Methods of forming a metal oxide surface that is enriched with metal oxide in its higher oxidation state are provided. A metal oxide surface that is enriched with metal oxide in its higher oxidation state is also provided.

Abstract: Methods of forming a metal oxide surface that is enriched with metal oxide in its higher oxidation state are provided. A metal oxide surface that is enriched with metal oxide in its higher oxidation state is also provided.

Abstract: The invention encompasses a method of enhancing selectivity of etching silicon dioxide relative to one or more organic substances. A material comprising one or more elements selected from Group VIII of the periodic table is provided within a reaction chamber; and a substrate is provided within the reaction chamber. The substrate has both a silicon-oxide-containing composition and at least one organic substance thereover. The silicon-oxide-containing composition is plasma etched within the reaction chamber. The plasma etching of the silicon-oxide-containing composition has increased selectivity for the silicon oxide of the composition relative to the at least one organic substance than would plasma etching conducted without the material in the chamber. The invention also encompasses a plasma reaction chamber assembly. The assembly comprises at least one interior wall, and at least one liner along the at least one interior wall. The liner comprises one or more of Ru, Fe, Co, Ni, Rh, Pd, Os, W, Ir, Pt and Ti.

Abstract: A method of forming a magnetic random access memory (MRAM) using a sacrificial cap layer on top of the memory cells and the structure resulting therefrom are described. A plurality of individual magnetic memory devices with cap layers are fabricated on a substrate. A continuous first insulator layer is deposited over the substrate and the magnetic memory devices. Portions of the first insulator layer are removed at least over the magnetic memory devices and then the cap layers are selectively removed from the magnetic memory devices, thus exposing active top surfaces of the magnetic memory devices. The top surfaces of the magnetic memory devices are recessed below the top surface of the first insulator layer. Top conductors are formed in contact with the active top surfaces of the magnetic memory devices. In an illustrated embodiment, spacers are also formed along the sides of the magnetic memory devices before the first insulator layer is deposited.

Abstract: A method of high aspect ratio contact etching a substantially vertical contact hole in an oxide layer using a hard photoresist mask is described. The oxide layer is deposited on an underlying substrate. A plasma etching gas is formed from a carbon source gas. Dopants are mixed into the gas. The doped plasma etching gas etches a substantially vertical contact hole through the oxide layer by doping carbon chain polymers formed along the sidewalls of the contact holes during the etching process into a conductive state. The conductive state of the carbon chain polymers reduces the charge buildup along sidewalls to prevent twisting of the contact holes by bleeding off the charge and ensuring proper alignment with active area landing regions. The etching stops at the underlying substrate.

Abstract: Methods of forming a metal oxide surface that is enriched with metal oxide in its higher oxidation state for use in a semiconductor device are provided. A metal oxide surface that is enriched with metal oxide in its higher oxidation state for use in a semiconductor device is also provided.

Abstract: Methods for forming conductive vias in a substrate include oxidizing at least a portion of a metallic structure that is exposed through an opening in a substrate to form an oxidation injury in the metallic structure. The oxidation injury is at least partially reversed, and conductive material is provided within the opening in the substrate. Electronic devices and systems include at least one conductive via extending through a substrate and contacting at least one conductive interconnect structure along an interface. The conductive interconnect structure includes an at least partially reversed oxidation injury at the interface between the conductive via and the interconnect structure.

Abstract: Methods of forming a metal oxide surface that is enriched with metal oxide in its higher oxidation state are provided. A metal oxide surface that is enriched with metal oxide in its higher oxidation state is also provided.

Abstract: The invention includes etching and contact opening forming methods. In one implementation, a plasma etching method includes providing a bottom powered plasma chamber that includes a plasma generating electrode powerable at different first and second frequencies, with the first frequency being lower than the second frequency. A substrate is positioned over the electrode. A plasma is generated over the substrate with the electrode from a first applied power at the first frequency and a second applied power at the second frequency. A ratio of the first applied power to the second applied power is from 0 to 0.25 or at least 6.0. Material is etched from the substrate with the plasma.

Abstract: Organic etch residues are often left within vias formed by etching through resist masks. Since the etch is designed to expose an underlying metal layer and is directional in order to produce vertical via sidewalls, the residue often incorporates metal. The present invention discloses a method of removing such etch residues while passivating exposed metal, including exposing the residue to ammonia. In the disclosed embodiment, ammonia and oxygen are mixed in a plasma step, such that the resist can be burned off at the same time as the residue treatment. The residue can thus be easily rinsed away.

Abstract: Methods of forming a metal oxide surface that is enriched with metal oxide in its higher oxidation state for use in a semiconductor device are provided. A metal oxide surface that is enriched with metal oxide in its higher oxidation sate for used in a semiconductor device is also provided.

Abstract: The invention includes etching and contact opening forming methods. In one implementation, a plasma etching method includes providing a bottom powered plasma chamber that includes a plasma generating electrode powerable at different first and second frequencies, with the first frequency being lower than the second frequency. A substrate is positioned over the electrode. A plasma is generated over the substrate with the electrode from a first applied power at the first frequency and a second applied power at the second frequency. A ratio of the first applied power to the second applied power is from 0 to 0.25 or at least 6.0. Material is etched from the substrate with the plasma.