A semiconductor structure may include two vertical transport field effect transistors comprising a top source drain, a bottom source drain, and an epitaxial channel and a resistive random access memory between the two vertical transport field effect transistors, the resistive random access memory may include an oxide layer, a top electrode, and a bottom electrode, wherein the oxide layer may contact the top source drain of the two vertical field effect transistor. The top source drain may function as the bottom electrode of the resistive random access memory. The semiconductor structure may include a shallow trench isolation between the two vertical transport field effect transistors, the shallow trench isolation may be embedded in a first spacer, a doped source, and a portion of a substrate.

Provided are embodiments for method of fabricating a dual damascene crossbar array. The method includes forming a bottom electrode layer on a substrate and forming a first memory device on the bottom electrode layer. The method also includes forming a dual damascene structure on the first memory device, wherein the dual damascene structure includes a top electrode layer and a first via, wherein the first via is formed between the first memory device and the top electrode layer. Also provided are embodiments for the dual damascene crossbar and embodiments for disabling memory devices of the dual damascene crossbar array.

There is provided a three-terminal atomic switching device and a method of manufacturing the same, which belongs to the field of microelectronics manufacturing and memory technology. The three-terminal atomic switching device includes: a stack structure including a source terminal and a drain terminal; a vertical trench formed by etching the stack structure; an M.sub.8XY.sub.6 channel layer formed on an inner wall and a bottom of the vertical trench; and a control terminal formed on a surface of the M.sub.8XY.sub.6 channel layer, wherein the control terminal fills the vertical trench. The source terminal resistance and the drain terminal resistance are controlled by the control terminal. The invention is based on the three-terminal atomic switching device, and realizes high switching ratio characteristic, simple structure, easy integration, high density and low cost due to high non-linearity of the source-drain resistance with respect to the control terminal voltage, and thus can be used in a gated device in a cross-array structure to inhibit a crosstalk phenomenon caused by the leakage current. The three-terminal atomic switching device proposed by the invention is suitable for a planar stacked cross-array structure and a vertical cross-array structure, so as to realize high-density three-dimensional storage.

A memory structure includes a first dielectric layer, having a first top surface, over a conductive structure. A first opening in the first dielectric layer exposes an area of the conductive structure, and has an interior sidewall. A first electrode structure, having a first portion and a second portion, is over the exposed area of the conductive structure. The second portion extends upwardly along the interior sidewall. A resistance variable layer is disposed over the first electrode. A second electrode structure, having a third portion and a fourth portion, is over the resistance variable layer. The third portion has a second top surface below the first top surface of the first dielectric layer. The fourth portion extends upwardly along the resistance variable layer. A second opening is defined by the second electrode structure. At least a part of a second dielectric layer is disposed in the second opening.

In a method of manufacturing a semiconductor integrated circuit device, a pillar may be formed on a semiconductor substrate. A hard mask pattern may be formed on a top surface and a portion of a sidewall of the pillar. An electric field-buffering region may be formed in the sidewall of the pillar. A gate insulating layer may be formed on an outer surface of the pillar. A gate may be formed on the gate insulating layer.

A phase change memory element including at least one phase change material layer, and a heater conductor, wherein at least a portion of the heater conductor is circumferentially surrounded by the at least one phase change material layer. The phase change memory element is symmetrical. The phase change memory element can include a top electrode circumferentially surrounding and connected to the at least one phase change material layer, and a bottom electrode in contact with the heater conductor. The phase change memory element can include at least one resistive liner in contact with the at least one phase change material layer.

A memory cell with a recessed bottom electrode and methods of forming the memory cell are described. A bottom electrode can be deposited on a layer of a structure. A first insulator and a second insulator can be deposited on top of the bottom electrode. The first insulator and the second insulator can be spaced apart from one another to form an opening on top of the bottom electrode. A recess can be etched in the bottom electrode. The recess can be etched in a portion of the bottom electrode that is underneath the opening. The recess and the opening can form a pore. Phase change material can be deposited in the pore to form a memory cell.

A method of forming a disturb-resistant non volatile memory device includes providing a substrate and forming a first dielectric thereon, forming a first strip of material separated from a second strip of material from a first wiring material, and forming a second dielectric thereon to fill a gap between the first and second strips of material. Openings are formed in the second dielectric exposing portions of the first wiring material. Filing the openings by p+ polysilicon contact material, and then an undoped amorphous silicon material, and then a metal material. A second wiring structure is formed thereon to contact the metal material in the openings. Resistive switching cells are formed from the first wiring structure, the second wiring structure, the contact material, the undoped amorphous silicon material, and the metal material.

A method for fabricating a semiconductor device includes forming air gaps within respective dielectric layer portions to reduce thermal cross-talk between adjacent bits. Each of the dielectric portions is formed on a substrate each adjacent to sidewall liners formed on sidewalls of a phase change memory (PCM) layer. The method further includes forming a pillar including the sidewall liners and the PCM layer, and forming a selector layer on the pillar and the dielectric portions.

An electronic device includes a semiconductor memory including material layers each including one or more low-resistance areas and one or more high-resistance areas, insulating layers stacked alternately with the material layers and including protrusions extending more than the material layers, conductive pillars passing through the insulating layers and the low-resistance areas, conductive layers located between the protrusions, and variable resistance layers interposed between the low-resistance areas and the conductive layers.