An apparatus, includes an interconnect, including a conductive material, above a substrate and a resistive random access memory (RRAM) device coupled to the interconnect. The RRAM device includes an electrode structure above the interconnect, where an upper portion of the electrode structure has a first width. The RRAM device further includes a switching layer on the electrode structure, where the switching layer has the first width and an oxygen exchange layer, having a second width less than the first width, on a portion of the switching layer. The RRAM device further includes a top electrode above the oxygen exchange layer, where the top electrode has the second width and an encapsulation layer on a portion of the switching layer, where the switching layer extends along a sidewall of the oxygen exchange layer.

A method includes providing a substrate having a conductive column, a dielectric layer over the conductive column, and a plurality of sacrificial blocks over the dielectric layer, the plurality of sacrificial blocks surrounding the conductive column from a top view; depositing a sacrificial layer covering the plurality of sacrificial blocks, the sacrificial layer having a dip directly above the conductive column; depositing a hard mask layer over the sacrificial layer; removing a portion of the hard mask layer from a bottom of the dip; etching the bottom of the dip using the hard mask layer as an etching mask, thereby exposing a top surface of the conductive column; and forming a conductive material inside the dip, the conductive material being in physical contact with the top surface of the conductive column.

A network computation device includes a stack of a plurality of arrays of magnetic tunnel junctions that are spaced apart along a stack direction, and at least one filament-forming dielectric material layer located between each vertically neighboring pair of arrays of magnetic tunnel junctions selected from the plurality of magnetic tunnel junctions.

A 3D semiconductor device including: a first single crystal layer with first transistors; overlaid by a first metal layer; a second metal layer overlaying the first metal layer and being overlaid by a third metal layer; a logic gates including at least the first metal layer interconnecting the first transistors; second transistors disposed atop the third metal layer; third transistors disposed atop the second transistors; a top metal layer disposed atop the third transistors; and a memory array including word-lines, and at least four memory mini arrays, where each of the memory mini arrays includes at least four rows by four columns of memory cells, where each of the memory cells includes at least one of the second transistors or third transistors, sense amplifier circuit(s) for each of the memory mini arrays, the second metal layer provides a greater current carrying capacity than the third metal layer.

A memory device includes: a first conductor extending in parallel with a first axis; a first selector material comprising a first portion that extends along a first sidewall of the first conductor; a second selector material comprising a first portion that extends along the first sidewall of the first conductor; a first variable resistive material comprising a portion that extends along the first sidewall of the first conductor; and a second conductor extending in parallel with a second axis substantially perpendicular to the first axis, wherein the first portion of the first selector material, the first portion of the second selector material, and the portion of the first variable resistive material are arranged along a first direction in parallel with a third axis substantially perpendicular to the first axis and second axis.

The present disclosure relates to a method to form an integrated chip including a filament via. In some embodiments, a lower metal layer comprising a first metal line and a second metal line is formed over a substrate. A filament dielectric layer is formed over the lower metal layer. An upper metal layer comprising a first metal line and a second metal line is formed over the filament dielectric layer. A first contact is formed over the upper metal layer. A filament formation bias is applied through the first contact to form a first filament via through the filament dielectric layer and electrically connecting the first metal line of the lower metal layer and the first metal line of the upper metal layer.

Thermal field controlled electrical conductivity change devices and applications therefore are provided. In some embodiments, a thermal switch, comprises: a metal-insulator-transition (MIT) material; first and second terminals electrically coupled to the MIT material; and a heater disposed near the MIT material.

A memory cell includes: a resistive material layer comprising a first portion that extends along a first direction and a second portion that extends along a second direction, wherein the first and second directions are different from each other; a first electrode coupled to a bottom surface of the first portion of the resistive material layer; and a second electrode coupled to the second portion of the resistive material layer.

A resistive random access memory (RRAM) device and a method for constructing the device is described. A capping layer structure is provided over a bottom contact where the capping layer includes a recess situated over the bottom contact. A first portion of the recess is filled with a lower electrode such that the width of the recess defines the width of the lower electrode. A second portion of the recess is filled with a high-K layer so that a bottom surface of the high-K layer has a stepped profile. A top electrode is formed on the high-K layer and a top contact is formed on the top electrode. The width of the high-K layer is greater than the width of the lower electrode to prevent shorting between the top contact and the lower electrode of the RRAM device.

The present disclosure provides an apparatus, including: a substrate; a bottom electrode formed on the substrate; a first base oxide layer formed on the bottom electrode; a first geometric confining layer formed on the first base oxide layer, wherein the first geometric confining layer comprises a first plurality of pin-holes; a second base oxide layer formed on the first geometric confining layer and connected to a first top surface of the first base oxide layer via the first plurality of pin-holes; and a top electrode formed on the second base oxide layer. The first base oxide layer includes TaOx, HfOx, TiOx, ZrOx, or a combination thereof. The first geometric confining layer comprises Al.sub.2O.sub.3, SiO.sub.2, Si.sub.3N.sub.4, Y.sub.2O.sub.3, Gd.sub.2O.sub.3, Sm.sub.2O.sub.3, CeO.sub.2, Er.sub.2O.sub.3, or a combination thereof.