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.

Disclosed is a tunable inductor device having a substrate, a planar spiral conductor having a plurality of spaced-apart turns disposed over the substrate, and a phase change switch (PCS) having a patch of a phase change material (PCM) disposed over the substrate between and in contact with a pair of adjacent segments of the plurality of spaced-apart turns, wherein the patch of the PCM is electrically insulating in an amorphous state and electrically conductive in a crystalline state. The PCS further includes a thermal element disposed adjacent to the patch of PCM, wherein the thermal element is configured to maintain the patch of the PCM to within a first temperature range until the patch of the PCM converts to the amorphous state and maintain the patch of the PCM within a second temperature range until the first patch of PCM converts to the crystalline state.

Integrated circuit (IC) devices with stacked two-level backend memory, and associated systems and methods, are disclosed. An example IC device includes a front end of line (FEOL) layer, including frontend transistors, and a back end of line (BEOL) layer above the FEOL layer. The BEOL layer includes a first memory layer with memory cells of a first type, and a second memory layer with memory cells of a second type. The first memory layer may be between the FEOL layer and the second memory layer, thus forming stacked backend memory. Stacked backend memory architecture may allow significantly increasing density of memory cells in a memory array having a given footprint area, or, conversely, reducing the footprint area of the memory array with a given memory cell density. Implementing two different types of backend memory may advantageously increase functionality and performance of backend memory.

An integrated circuit (IC) is provided that includes a plurality of physical unclonable function (PUF) structures located in a PUF area. Each PUF structure of the plurality of PUF structures includes at least a PUF top electrically conductive structure containing random sidewall voids and random line openings which can provide an encrypted security code to the IC. The IC further includes a plurality of memory structures located in a memory area that is located laterally adjacent to the PUF area. Each memory structure of the plurality of memory structures includes a memory element sandwiched between a bottom electrically conductive structure and a top electrically conductive structure. The top electrically conductive structures are devoid of sidewall voids and line openings.

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.

A memory cell design is disclosed. The memory cell structure includes phase change and selector layers stacked between top and bottom electrodes. An ohmic contact may be included between the phase change and selector layers. A multi-layer liner structure is provided on sidewalls of the phase change layer. In some such cases, the liner structure is above and not on sidewalls of the selector layer. The liner structure includes a first dielectric layer, and a second dielectric layer on the first dielectric layer. The liner structure includes a third dielectric layer on the second dielectric layer and that is sacrificial in nature, and may not be present in the final structure. The second dielectric layer comprises a high-k dielectric material or a metal silicate material. The second dielectric layer protects the phase change layer from lateral erosion and physical vertical etch and provides etch selectivity during the fabrication process.

Methods, systems, and devices for memory arrays having graded memory stack resistances are described. An apparatus may include a first subset of memory stacks having a first resistance based on a physical and/or electrical distance of the first subset of memory stacks from at least one of a first driver component or a second driver component. The apparatus may include a second subset of memory stacks having a second resistance that is less than the first resistance based on a physical and/or electrical distance of the second subset of memory from at least one of the first driver component or the second driver component.

A method for forming a resistive random access memory structure. The resistive random access memory structure includes a bottom electrode; a variable resistance layer disposed on the bottom electrode; a top electrode disposed on the variable resistance layer; a protection layer surrounding the variable resistance layer, wherein a top surface of the protection layer and a top surface of the top electrode are coplanar; and an upper interconnect structure disposed on the top electrode, wherein the upper interconnect structure is electrically connected to the top electrode and directly contacts a sidewall of the protection layer.

At least a portion of a memory cell is formed over a first substrate and at least a portion of a steering element or word or bit line of the memory cell is formed over a second substrate. The at least a portion of the memory cell is bonded to at least a portion of a steering element or word or bit line. At least one of the first or second substrate may be removed after the bonding.