A method of forming a resistive random access memory cell includes the following steps. A first electrode layer, a blanket resistive switching material layer and a second electrode layer are formed on a layer sequentially. The second electrode layer is patterned to form a second electrode. The blanket resistive switching material layer is patterned to form a resistive switching material layer. An oxygen implanting process is performed to implant oxygen in two sidewall parts of the resistive switching material layer.

Provided is a non-volatile memory including a conductor layer, a memory device, and a selector. The selector is located between and electrically connected to the memory device and the conductive layer. The selector includes a metal filling layer, a barrier layer, and a rectify layer. The metal filling layer is electrically connected to the memory device. The barrier layer is located on the sidewall and the bottom surface of the metal filling layer. The rectify layer is wrapped around the barrier layer. The rectify layer includes a first portion and a second portion. The first portion is located between the barrier layer on the bottom surface of the metal filling layer and the conductive layer. The second portion and the metal filling layer sandwich the barrier layer on the sidewall of the metal filling layer. The first portion has more diffusion paths of metal ions than the second portion.

The present disclosure provides a conductive bridge semiconductor device and a method of manufacturing the same. The conductive bridge semiconductor device includes a lower electrode, a resistive switching functional layer, an ion barrier layer and an active upper electrode from bottom to top, wherein the ion barrier layer is provided with certain holes through which active conductive ions pass. Based on this structure, the precise designing of the holes on the barrier layer facilitates the modulation of the quantity, size and density of the conduction paths in the conductive bridge semiconductor device, which enables that the conductive bridge semiconductor device can be modulated to be a nonvolatile conductive bridge resistive random access memory or a volatile conductive bridge selector. Based on the above method, ultra-low power nonvolatile conductive bridge memory and high driving-current volatile conductive bridge selector with controllable polarity are completed.

A phase-change memory device with reduced heater size includes a first conductive structure within a first dielectric layer. A heater element is located within a second dielectric layer disposed above the first conductive structure. The heater element includes a third dielectric layer defining a perimeter, a top portion of a heater material layer partially overlapping the perimeter of the third dielectric layer, and a bottom portion of the heater material layer overlapping the perimeter of the third dielectric layer. The bottom portion of the heater material layer is in contact with the first conductive structure. A phase-change material is located above the heater element with a bottom surface of the phase-change material being in contact with the top portion of the heater material layer. The phase-change memory device further includes a second conductive structure located above the phase-change material.

In a method for forming a semiconductor device, a plurality of conductive lines is formed as a part of a first wiring level of the semiconductor device. The first wiring level is positioned over a first level having a plurality of transistor devices. The plurality of conductive lines extends parallel to the first level. In addition, a programmable horizontal bridge is formed that extends parallel to the first level, and electrically connects a first conductive line and a second conductive line of the plurality of conductive lines in the first wiring level. The programmable horizontal bridge is formed based on a programmable material that changes phase between a conductive state and a non-conductive state according to a current pattern delivered to the programmable horizontal bridge.

A method for co-manufacturing a FeRAM and an OxRAM includes depositing a layer of first electrode carried out identically for a zone Z1 and a zone Z2; depositing a layer of hafnium dioxide-based active material carried out identically for Z1 and Z2; depositing a first conductive layer carried out identically for Z1 and Z2; making a mask at Z2, leaving Z1 free; removing the layer at Z1, with Z2 being protected by the mask; removing the mask at Z2; and depositing a second conductive layer in contact with the layer at Z2 and in contact with the layer at Z1, the material of the layer being chosen to create oxygen vacancies in the active layer and depositing a third conductive layer carried out identically for Z1 and Z2.

A method for fabricating a semiconductor device may include: forming a first line over a substrate; forming a variable resistance layer on the first line; forming a first dielectric layer on the first line and the variable resistance layer; forming a second dielectric layer on the first dielectric layer; removing a portion of the interlayer dielectric layer to expose a portion of the first dielectric layer; and incorporating a dopant into an exposed portion of the first dielectric layer by performing an ion implantation process to convert the portion of the first dielectric layer into a selector layer.

Provided are a resistive random access memory and a manufacturing method thereof. The resistive random access memory includes a substrate having a pillar protruding from a surface of the substrate, a gate surrounding a part of a side surface of the pillar, a gate dielectric layer, a first electrode, a second electrode, a variable resistance layer, a first doped region and a second doped region. The gate dielectric layer is disposed between the gate and the pillar. The first electrode is disposed on a top surface of the pillar. The second electrode is disposed on the first electrode. The variable resistance layer is disposed between the first electrode and the second electrode. The first doped region is disposed in the pillar below the gate and in a part of the substrate below the pillar. The second doped region is disposed in the pillar between the gate and the first electrode.

Methods and devices based on the use of dopant-modulated etching are described. During fabrication, a memory storage element of a memory cell may be non-uniformly doped with a dopant that affects a subsequent etching rate of the memory storage element. After etching, the memory storage element may have an asymmetric geometry or taper profile corresponding to the non-uniform doping concentration. A multi-deck memory device may also be formed using dopant-modulated etching. Memory storage elements on different memory decks may have different taper profiles and different doping gradients.

Provided are a resistive random access memory and a manufacturing method thereof. The resistive random access memory includes a substrate having a pillar protruding from a surface of the substrate, a gate surrounding a part of a side surface of the pillar, a gate dielectric layer, a first electrode, a second electrode, a variable resistance layer, a first doped region and a second doped region. The gate dielectric layer is disposed between the gate and the pillar. The first electrode is disposed on a top surface of the pillar. The second electrode is disposed on the first electrode. The variable resistance layer is disposed between the first electrode and the second electrode. The first doped region is disposed in the pillar below the gate and in a part of the substrate below the pillar. The second doped region is disposed in the pillar between the gate and the first electrode.