Memory stacks and method of forming the same are provided. A memory stack includes a bottom electrode layer, a top electrode layer and a phase change layer between the bottom electrode layer and the top electrode layer. A width of the top electrode layer is greater than a width of the phase change layer. A first portion of the top electrode layer uncovered by the phase change layer is rougher than a second portion of the top electrode layer covered by the phase change layer.

An electronic device includes a semiconductor memory. A method for fabricating the electronic device includes forming a first memory cell extending vertically from a surface of substrate and having a first upper portion that protrudes laterally, forming a second memory cell extending vertically from the surface of the substrate and having a second upper portion that protrudes laterally towards the first upper portion, and forming a liner layer over the first and second memory cells, the liner layer having a first portion disposed over the first upper portion and a second portion disposed over the second upper portion, the first and second portions of the liner layer contacting each other.

Memory stacks and method of forming the same are provided. A memory stack includes a bottom electrode layer, a top electrode layer and a phase change layer between the bottom electrode layer and the top electrode layer. A width of the top electrode layer is greater than a width of the phase change layer. A first portion of the top electrode layer uncovered by the phase change layer is rougher than a second portion of the top electrode layer covered by the phase change layer.

A memory system may include separate amounts or types of resistive material that may be deposited over memory cells and conductive vias using separate resistive layers in the access lines. A first resistive material layer may be deposited over the memory cells prior to performing an array termination etch used to deposit the conductive via. The array termination etch may remove the first resistive material over the portion of the array used to deposit the conductive via. A second resistive material layer may be deposited after the etch has occurred and the conductive via has been formed. The second resistive material layer may be deposited over the conductive via.

A three terminal neuromorphic synaptic device and a method for manufacturing the same are provided. The three terminal neuromorphic synaptic device includes a substrate, source/drain electrodes provided on the substrate, a channel region electrically connected between the source electrode and the drain electrode, an ion transfer layer provided on the channel region, a gate electrode provided on the ion transfer layer, and a voltage application unit to apply a gate voltage to the gate electrode. The ion transfer layer includes an electrolyte material to transfer an active ion of the gate electrode between the gate electrode and the channel region, in response to the gate voltage applied to the gate electrode. The voltage application unit adjusts a resistance and a conductance of the channel region by changing an amount of active ions accumulated in the channel region, depending on the number of times that the gate voltage is applied.

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.

A memory device is provided. The memory device includes a bottom electrode, a first data storage layer, a second data storage layer, an interfacial conductive layer and a top electrode. The first data storage layer is disposed on the bottom electrode and in contact with the bottom electrode. The second data storage layer is disposed over the first data storage layer. The interfacial conductive layer is disposed between the first data storage layer and the second data storage layer. The top electrode is disposed over the second data storage layer.

Methods, systems, and devices for a low resistance crosspoint architecture are described. A manufacturing system may deposit a thermal barrier material, followed by a first layer of a first conductive material, on a layered assembly including a patterned layer of electrode materials and a patterned layer of a memory material. The manufacturing system may etch a first area of the layered assembly to form a gap in the first layer of the first conductive material, the thermal barrier material, the patterned layer of the memory material, and the patterned layer of electrode materials. The manufacturing system may deposit a second conductive material to form a conductive via in the gap, where the conductive via extends to a height within the layered assembly that is above the thermal barrier material.

There is provided a selection device that includes a first electrode, a second electrode opposed to the first electrode, a semiconductor layer provided between the first electrode and the second electrode, and including at least one kind of chalcogen element selected from tellurium (Te), selenium (Se), and sulfur (S), and at least one kind of first element selected from boron (B), aluminum (Al), gallium (Ga), phosphorus (P), arsenic (As), carbon (C), germanium (Ge), and silicon (Si), and a first heat bypass layer provided at least in a portion around the semiconductor layer between the first electrode and the second electrode and having higher thermal conductivity than the semiconductor layer.

A semiconductor memory device includes: a first wiring extending in a first direction; a second wiring extending in a second direction that intersects with the first direction; a resistance change film provided between the first wiring and the second wiring and including at least one element selected from a group consisting of germanium, antimony, and tellurium; an electrode provided between the resistance change film and the first wiring; and a first film selectively provided between the electrode and the first wiring, in which the electrode includes a surface in contact with both of the first wiring and the first film.