In some embodiments, the present disclosure relates to a method of operating an RRAM cell having a PMOS access transistor. The method may be performed by turning on a PMOS transistor having a drain terminal coupled to a lower electrode of an RRAM device. A first voltage is provided to a source terminal of the PMOS transistor, and a second voltage is provided to a bulk terminal of the PMOS transistor. The second voltage is larger than the first voltage. A third voltage is provided to an upper electrode of the RRAM device. The third voltage is larger than the first voltage.

Disclosed are methods, systems and devices for generation of a read signal to be applied across a load for use in detecting a current impedance state of the load. In one implementation, a voltage and current of a generated read signal may be controlled so as to maintain a current impedance state of the load.

A plurality of memory cells in a 3D cross-point array with improved endurance is disclosed. Each memory cell, disposed between first and second conductors, includes a switch in series with a pillar of phase change material. The pillar has a Te-rich material at one end proximal to the second conductor, and an Sb-rich material at the other end proximal to the first conductor, wherein the current direction is from the first conductor to the second conductor.

A three-dimensional semiconductor memory device includes first to third cell array layers sequentially stacked on a substrate. Each of the first to third cell array layers includes memory cells arranged along first and second directions crossing each other and parallel to a top surface of the substrate. Each of the memory cells includes a variable resistance element and a tunnel field effect transistor connected in series. The device further includes bit lines extending along the first direction between the first and second cell array layers and at least one source line extending along either the first direction or the second direction between the second and third cell array layers. The memory cells of the first and second cell array layers share the bit lines, and the memory cells of the second and third cell array layers share the source line.

A resistive memory device including a resistive memory pattern; and a selection element pattern electrically connected to the resistive memory pattern, the selection element pattern including a chalcogenide switching material and at least one metallic material, the chalcogenide switching material including germanium, arsenic, and selenium, and the at least one metallic material including aluminum, strontium, or indium, wherein the selection element pattern includes an inhomogeneous material layer in which content of the at least one metallic material in the selection element pattern is variable according to a position within the selection element pattern.

A method for manufacturing a memory resistor device. A first layer of a dielectric material is deposited onto a first electrode. A subsection of the first layer of the dielectric material is removed to expose one or more edges of the dielectric material and a second layer of the dielectric material is deposited to create one or more boundaries between the one or more edges of the first layer of the dielectric material and the second layer of the dielectric material. A second electrode is provided, wherein the one or more boundaries between the one or more edges of the first layer of the dielectric material and the second layer of the dielectric material extend at least partially from the first electrode to the second electrode.

A memory structured in lines and columns over several superimposed levels, each level comprising an array of memory elements and gate-all-around access transistors, each transistor including a semiconductor nanowire and each gate being insulated from the gates of the other levels, further comprising: conductive portions, each crossing at least two levels and coupled to first ends of the nanowires of one column of the levels; memory stacks, each crossing the levels and coupled to second ends of the nanowires of said column; first conductive lines, each connected to the conductive portions of the same column; word lines each extending in the same level while coupling together the gates of the same line and located in said level.

According to various embodiments, there is provided a memory cell. The memory cell may include a transistor, a dielectric member, an electrode and a contact member. The dielectric member may be disposed over the transistor. The electrode may be disposed over the dielectric member. The contact member has a first end and a second end opposite to the first end. The first end is disposed towards the transistor, and the second end is disposed towards the dielectric member. The contact member has a side surface extending from the first end to the second end. The second end may have a recessed end surface that has a section that slopes towards the side surface so as to form a tip with the side surface at the second end. The dielectric member may be disposed over the second end of the contact member and may include at least a portion disposed over the tip.

The disclosed subject matter relates generally to structures, memory devices and a method of forming the same. More particularly, the present disclosure relates to resistive random-access (ReRAM) memory devices with an electrode having tapered sides. The present disclosure provides a memory device including a first electrode having a tapered shape and including a tapered side, a top surface, and a bottom surface, in which the bottom surface has a larger surface area than the top surface, a resistive layer on and conforming to at least the tapered side of the first electrode, and a second electrode laterally adjacent to the tapered side of the first electrode, the second electrode including a top surface and a side surface abutting the resistive layer, in which the side surface forms an acute angle with the top surface.

An ovonic threshold switch (OTS) selector and a memory device including the OTS selector is provided. The OTS selector includes a switching layer formed of a GeCTe compound further doped with one or both of nitrogen and silicon, and exhibits improved thermal stability and electrical performance.