The present disclosure generally relates to memory devices and methods of forming the same. More particularly, the present disclosure relates to resistive random-access (ReRAM) memory devices. The present disclosure provides a memory device including an opening in a dielectric structure, the opening having a sidewall, a first electrode on the sidewall of the opening, a spacer layer on the first electrode, a resistive layer on the first electrode and upon an upper surface of the spacer layer, and a second electrode on the resistive layer.

A method is presented for enabling heat dissipation in resistive random access memory (RRAM) devices. The method includes forming a first thermal conducting layer over a bottom electrode, depositing a metal oxide liner over the first thermal conducting layer, forming a second thermal conducting layer over the metal oxide liner, recessing the second thermal conducting layer to expose the first thermal conducting layer, and forming a top electrode in direct contact with the first and second thermal conducting layers.

A via-level dielectric material layer is formed over a first dielectric material layer embedding a first conductive structure. A via cavity is formed through the via-level dielectric material layer. A least one straight sidewall vertically extends from a closed upper periphery of the via cavity at a top surface of the via-level dielectric material layer to a closed lower periphery of the via cavity that is adjoined to a top surface of the first conductive structure. A pillar stack structure is formed in the via cavity by sequentially forming a set of material portions containing a lower pillar structure and an upper pillar structure. The lower pillar structure and the upper pillar structure include a selector material pillar and a memory material pillar. A second conductive structure may be formed on a top surface of the pillar stack structure. The pillar stack structure may be used in an array configuration.

A method is presented for enabling heat dissipation in resistive random access memory (RRAM) devices. The method includes forming a first thermal conducting layer over a bottom electrode, depositing a metal oxide liner over the first thermal conducting layer, forming a second thermal conducting layer over the metal oxide liner, recessing the second thermal conducting layer to expose the first thermal conducting layer, and forming a top electrode in direct contact with the first and second thermal conducting layers.

A memory device may be provided including one or more bottom electrodes, one or more mask elements, one or more top electrodes and a switching layer. The bottom electrode(s) may include a first bottom electrode, the mask element(s) may include a first mask element and the top electrode(s) may include a first top electrode. The first mask element may be arranged over a first part of the first bottom electrode. The first top electrode may be arranged over and in contact with the first mask element. The switching layer may be arranged to extend over a second part of the first bottom electrode, and along a first side surface of the first mask element and further along a first side surface of the first top electrode. The first side surfaces of the first mask element and the first top electrode may face a same direction.

The present disclosure generally relates to memory devices and methods of forming the same. More particularly, the present disclosure relates to resistive random-access (ReRAM) memory devices. The present disclosure provides a memory device including a first electrode, a dielectric cap above the first electrode, a second electrode laterally adjacent to the first electrode, in which an upper surface of the second electrode is substantially coplanar with an upper surface of the dielectric cap, and a resistive layer between the first electrode and the second electrode. An edge of the first electrode is electrically coupled to an edge of the second electrode by at least the resistive layer.

Various embodiments of the present application are directed towards an integrated chip including a first conductive interconnect structure overlying a substrate. A first memory stack is disposed on the first conductive interconnect structure. A second conductive interconnect structure overlies the first memory stack. The second conductive interconnect structure is spaced laterally between opposing sidewalls of the first conductive interconnect structure. A third conductive interconnect structure is disposed on the first conductive interconnect structure. A top surface of the third conductive interconnect structure is vertically above the second conductive interconnect structure.

Provided is a memory device including a stack structure, a plurality of channel layers, a source line, a bit line, a switching layer, and a dielectric pillar. The stack structure has a plurality of dielectric layers and a plurality of conductive layers stacked alternately. The channel layers are respectively embedded in the conductive layers. The source line penetrates through the stack structure to be electrically connected to the channel layers at first sides of the channel layers. The bit line penetrates through the stack structure to be coupled to the channel layers at second sides of the channel layers. The switching layer wraps the bit line to contact the channel layers at the second sides of the channel layers. The dielectric pillar penetrates through the channel layers to divide each channel layer into a doughnut shape. A method of manufacturing a memory device is also provided.

A resistive memory device with an embedded shoulder pulled sidewall spacer and method of forming. The method includes providing a patterned film stack containing a lower electrode layer, a dielectric filament layer on the lower electrode layer, and an upper electrode layer on the dielectric filament layer, depositing a conformal cap layer on the patterned film stack, dry etching the conformal cap layer to form a sidewall spacer on sidewalls of the patterned film stack, where a top of the sidewall spacer is recessed to below a top of the upper electrode layer by the dry etching. The method further includes encapsulating the patterned film stack in an isolation layer, and etching the isolation layer to expose the upper electrode layer without exposing the sidewall spacer.

Provided is a semiconductor device including: a substrate, a plurality of isolation structures, a plurality of channel layers, and a gate structure. The substrate includes a plurality of fins thereon. The plurality of isolation structures are respectively disposed between the plurality of fins. A top surface of the plurality of isolation structures is higher than a top surface of the plurality of fins to form a plurality of openings. The plurality of channel layers are respectively disposed in the plurality of openings. Each channel layer is in contact with a corresponding fin and extends to cover a lower sidewall of a corresponding isolation structure, thereby forming a U-shaped structure. The gate structure is filled in the plurality of openings and extends to cover the top surface of the plurality of isolation structures.