A semiconductor structure comprises an active device stack comprising one or more layers, the one or more layers comprising a top electrode. The semiconductor structure also comprises an additional layer disposed over the active device stack, an encapsulation layer surrounding the active device stack and the additional layer, and a contact to the top electrode coupled to the additional layer.

System and method to localize a position of an RRAM filament of resistive memory device at very low bias voltages using a scanning laser beam. The approach is non-invasive and allows measurement of a large number of devices for creating statistics relating to the filament formation. A laser microscope system is configured to perform a biasing the RRAM cell with voltage (or current). Concurrent to the applied bias, a laser beam is generated and aimed at different positions of the RRAM cell (e.g., by a raster scanning). Changes in the current (or voltage) flowing through the cell are measured. The method creates a map of the current (or voltage) changes at the different laser positions and detects a spot in the map corresponding to higher (or lower) current (or voltage). The method determines the (x,y) position of the spot compared to the edge/center of the RRAM cell.

The present invention provides a neuromorphic memristor device, which includes a resistive switching layer formed on a lower electrode; and an upper electrode formed on the resistive switching layer, in which the resistive switching layer includes an organic metal halide having a perovskite crystal structure.

In one embodiment, a mask set for use in fabricating thin film tunneling devices includes a first photomask configured to form bottom electrodes of the devices, the first photomask comprising a first alignment mark including multiple corner markers, and a second photomask configured to form a continuous top layer of the devices, the second photomask comprising a second alignment mark including a corner marker configured to be aligned with one of the corner markers of the first photomask, wherein a degree of overlap between the bottom electrodes and the continuous top layer depends upon the corner marker of the first photomask with which the corner marker of the second photomask aligns.

A method for manufacturing a resistive device, includes depositing a first electrically conductive layer on a substrate; forming an etching mask on the first conductive layer; etching the first conductive layer through the mask, such as to obtain a plurality of electrically conductive pillars separated from one another; and forming storage elements with variable electrical resistance at the tops of the electrically conductive pillars, such that each storage element is supported by one of the electrically conductive pillars, the step of forming the storage elements including the following operations depositing a first layer by non-collimated cathode sputtering at normal incidence relative to the substrate; and depositing a second layer on the first layer by cathode sputtering, the second layer including a first chemical species sputtered at an oblique incidence.

A two-terminal device comprises a bottom electrode. A device element is formed upon the bottom electrode. The two-terminal device also comprises a top electrode that is formed upon the device element. The bottom electrode and the top electrode are aligned. The bottom electrode and top electrode also have a same width and depth.

A bottom electrode is deposited on a substrate. A dielectric layer is deposited on the bottom electrode. One or more structures are patterned within the dielectric layer. A liner layer is deposited on top of the dielectric layer and the bottom electrode. A selectivity promotion layer is deposited on top of the liner layer. The selectivity promotion layer is etched to expose a top surface of the dielectric layer and a portion of the bottom electrode. A phase change memory material layer is deposited within a void of the one or more structures between the selectivity promotion layer.

A stacked phase change memory structure having a cross-point architecture is provided. The stacked phase change memory structure includes at least two phase change material element-containing structures stacked one atop the other. Each phase change material element-containing structure of the plurality of phase change material element-containing structures has a cross-point architecture and includes, from bottom to top, at least one bottom electrode, a phase change material element, and a top electrode.

A variable resistance memory device includes a substrate, a first conductive line on the substrate, the first conductive line extending in a first horizontal direction, a second conductive line extending on the first conductive line in a second horizontal direction perpendicular to the first horizontal direction, and a memory cell at an intersection between the first conductive line and the second conductive line, the memory cell having a selection element layer, an intermediate electrode layer, and a variable resistance layer, and the variable resistance layer having a shape of stairs with a concave center.

A crystallization seed layer in a substrate, a phase change material layer, the phase change material layer includes a similar lattice constant as a lattice constant of the crystallization seed layer, a top electrode adjacent to a first vertical side surface and a bottom electrode adjacent to a second vertical side surface of the phase change material layer. A plurality of memory structures configured in a crossbar array, each including a crystallization seed layer, a phase change material layer above, a top electrode adjacent to a first vertical side surface and a bottom electrode adjacent to a second vertical side surface of the phase change material layer. A method including forming a crystallization seed layer, forming a phase change material layer, forming a top electrode and a bottom electrode on the substrate, each adjacent to a vertical side surface of the phase change material layer.