Various embodiments of the present disclosure are directed towards a method for forming an integrated chip, the method includes forming a bottom electrode over a substrate. A first switching layer is formed on the bottom electrode. The first switching layer comprises a dielectric material doped with a first dopant. A second switching layer is formed over the first switching layer. An atomic percentage of the first dopant in the second switching layer is less than an atomic percentage of the first dopant in the first switching layer. A top electrode is formed over the second switching layer.

A semiconductor storage device includes at least a first electrode layer including a first material; and a memory layer including a second material having a high-resistance state and a low-resistance state switchable based on electric heating. The memory layer has a side surface covered by a side wall layer, the side wall layer including a third material with a higher melting temperature than the second material. The first material has an amorphous structure, a thermal conductivity at least 2-digits lower than a thermal conductivity of a single phase metal, and a resistivity equal to or lower than 50 mΩ.Math.cm and a positive temperature dependence.

The present disclosure is directed toward carbon based diodes, carbon based resistive change memory elements, resistive change memory having resistive change memory elements and carbon based diodes, methods of making carbon based diodes, methods of making resistive change memory elements having carbon based diodes, and methods of making resistive change memory having resistive change memory elements having carbons based diodes. The carbon based diodes can be any suitable type of diode that can be formed using carbon allotropes, such as semiconducting single wall carbon nanotubes (s-SWCNT), semiconducting Buckminsterfullerenes (such as C60 Buckyballs), or semiconducting graphitic layers (layered graphene). The carbon based diodes can be pn junction diodes, Schottky diodes, other any other type of diode formed using a carbon allotrope. The carbon based diodes can be placed at any level of integration in a three dimensional (3D) electronic device such as integrated with components or wiring layers.

Memristor devices are provided. In an embodiment, a memristor device comprises a top electrode; a bottom electrode; a dielectric material between the top and bottom electrodes; and an ion-implanted conductive region embedded within the dielectric material, the ion-implanted conductive region comprising the dielectric material. The ion-implanted conductive region forms an interface with the dielectric material such that a voltage applied across the top and bottom electrodes causes electrons to cross the interface as they move between the top and bottom electrodes so that the memristor device exhibits memristance.

A resistive random access memory (ReRAM) device is provided. The ReRAM device includes a stack structure including a first electrode, a metal oxide layer in contact with the first electrode, and a second electrode in contact with the metal oxide layer. A portion of the stack structure is modified by ion implantation, and the modified portion of the stack structure is offset from edges of the stack structure.

A memory cell including a two-terminal re-writeable non-volatile memory element having at least two layers of conductive metal oxide (CMO), which, in turn, can include a first layer of CMO including mobile oxygen ions, and a second layer of CMO formed in contact with the first layer of CMO to cooperate with the first layer of CMO to form an ion obstruction barrier. The ion obstruction barrier is configured to inhibit transport or diffusion of a subset of mobile ion to enhance, among other things, memory effects and cycling endurance of memory cells. At least one layer of an insulating metal oxide that is an electrolyte to the mobile oxygen ions and configured as a tunnel barrier is formed in contact with the second layer of CMO.

A method for fabricating an electronic device including a semiconductor memory includes forming a chalcogenide layer, forming a first conductive layer on the chalcogenide layer, and increasing a density of an interface between the chalcogenide layer and the first conductive layer by injecting or irradiating ions onto the interface.

Various embodiments of the present disclosure are directed towards a memory cell including a data storage structure disposed between a top electrode and a bottom electrode. The data storage structure includes a lower switching layer overlying the bottom electrode, and an upper switching layer overlying the lower switching layer. The lower switching layer comprises a dielectric material doped with a first dopant.

A method of fabrication of a ferroelectric memory including a first electrode, a second electrode and a layer of active material made of hafnium dioxide HfO.sub.2 positioned between the first electrode and the second electrode, where the method includes depositing a first electrode layer; depositing the layer of active material; doping the layer of active material; depositing a second electrode layer; wherein the method includes sub-microsecond laser annealing of the layer of doped active material.

A method for fabricating an electronic device including a semiconductor memory including one or more memory elements, includes: forming a first insulating layer; forming a diffusion barrier layer over the first insulating layer; forming a second insulating layer over the diffusion barrier layer, the second insulating layer and the first insulating layer being formed of a common insulating material; doping one of a first dopant and a second dopant in the first insulating layer to form a selection element layer when the first dopant is doped or to form a variable resistance layer when the second dopant is doped; and doping the other one of the first dopant and the second dopant in the second insulating layer.