A memory cell includes a memory device, a connecting structure, an insulating layer and a selector. The connecting structure is disposed on and electrically connected to the memory device. The insulating layer covers the memory device and the connecting structure. The selector is located on and electrically connected to the memory device, where the selector is disposed on the insulating layer and connected to the connecting structure by penetrating through the insulating layer.

A phase-change memory cell includes a heater, a memory region made of a phase-change material located above said heater, and an electrically conductive element positioned adjacent to the memory region and the heater at a first side of the heater. The electrically conductive element extends parallel to a first axis and has, parallel to the first axis, a first dimension at the first side that is greater than a second dimension at a second side opposite to the first side.

The present invention discloses a method for manufacturing a phase change memory and a phase change memory. The method comprises: forming a first wafer having a semiconductor-on-insulator structure; forming a memory material layer on the semiconductor-on-insulator structure; and forming a first metal material layer on the memory material layer to form a first semiconductor element.

In fabrication of a phase change random access memory (PCRAM), a field effect transistor (FET) logic layer is formed on a first wafer, including a heating FET for each storage cell. The FET logic layer is transferred from the first wafer to a carrier wafer. Thereafter, a storage layer of the PCRAM is formed on the exposed surface of the FET logic layer, including a region of a phase change material for each storage cell that is electrically connected to a channel of the heating FET of the storage cell. The storage layer further includes a second heating transistor for each storage cell that is electrically connected to a channel of the second heating transistor.

A phase-change memory (PCM) cell is provided to include a first electrode, a second electrode, and a phase-change feature disposed between the first electrode and the second electrode. The phase-change feature is configured to change its data state based on a write operation performed on the PCM cell. The write operation includes a reset stage and a set stage. In the reset stage, a plurality of reset current pulses are applied to the PCM cell, and the reset current pulses have increasing current amplitudes. In the set stage, a plurality of set current pulses are applied to the PCM cell, and the set current pulses exhibit an increasing trend in current amplitude. The current amplitudes of the set current pulses are smaller than those of the reset current pulses.

A method of forming a germanium antimony tellurium (GeSbTe) layer includes forming a germanium antimony (GeSb) layer by repeatedly performing a GeSb supercycle; and forming the GeSbTe layer by performing a tellurization operation on the GeSb layer, wherein the GeSb supercycle includes performing at least one GeSb cycle; and performing at least one Sb cycle, the GeSbTe has a composition of Ge.sub.2Sb.sub.2+aTe.sub.5+b, in which a and b satisfy the following relations: −0.2<a<0.2 and −0.5<b<0.5.

Devices with settable resistance and methods of forming the same include forming vertical dielectric structures from heterogeneous dielectric materials on a first electrode. A second electrode is formed on the vertical dielectric structures.

A three-dimensional array device with multiple layers in height direction includes a first two-dimensional array circuit located in a first layer; and a second two-dimensional array circuit located in a second layer adjacent to the first layer and overlapped in a plan view with the first two-dimensional array circuit. Each of the first two-dimensional array circuit and the second two-dimensional array circuit has a first wiring group, an input part that inputs signals to the first wiring group, a second wiring group that intersects the first wiring group and an output part that outputs signals from the second wiring group. The output part in the first two-dimensional array circuit is overlapped in a plan view on the input part in the second two-dimensional array circuit and is connected in a signal transferable manner.

Provided is a memory device and an electronic device including the same. The memory device according to an example embodiment may include: a two-dimensional material layer including a two-dimensional material; a contact region in contact with an edge of the two-dimensional material layer; and an electrode which is electrically connected to the contact region and changes a domain of a region adjacent to the contact region of the two-dimensional material layer by an applied voltage.

A method of controlling the forming voltage of a dielectric film in a resistive random access memory (ReRAM) device. The method includes depositing a dielectric film contains intrinsic defects on a substrate, forming a plasma-excited treatment gas containing H.sub.2 gas, and exposing the dielectric film to the plasma-excited treatment gas to create additional defects in the dielectric film without substantially changing a physical thickness of the dielectric film, where the additional defects lower the forming voltage needed for generating an electrically conducting filament across the dielectric film. The dielectric film can include a metal oxide film and the plasma-excited treatment gas may be formed using a microwave plasma source.