Electrical devices operating in a range of 273 C. to 100 C. are disclosed. The devices include an insulating substrate. A U0.sub.2+x crystal or oriented crystal U0.sub.2+x film is on a first portion of the substrate. The U0.sub.2+x crystal or film originates and hosts a non-equilibrium polaronic quantum phase-condensate. A first lead on a second portion of the substrate is in electrical contact with the U0.sub.2+x crystal or film. A second lead on a third portion of the surface is in electrical contact with the U0.sub.2+x crystal or film. The leads are isolated from each other. A U0.sub.2+x excitation source is in operable communication with the UO.sub.2+x crystal or film. The source is configured to polarize a region of the crystal or film thereby activating the non-equilibrium quantum phase-condensate. One source state causes the UO.sub.2+x crystal or film to be conducting. Another source state causes the U0.sub.2+x crystal or film to be non-conductive.

A method of manufacturing a storage device for storing information, apparatus for storing information, an optical memristor device and a memory cell are disclosed. A method comprises providing at least one first electrode and at least one further electrode and providing each of at least one region of a first material between, and in electrical connection with, a respective first electrode and a further electrode whereby said step of providing at least one region comprises providing in the first material, a plurality of changeable particles that have charge storage capacity and at least one electrical property that is reversibly changeable responsive to absorption of incident electromagnetic radiation.

Described is a method comprising directing an ultra-low voltage electron beam to a surface of a first insulating layer. The first insulating layer is disposed on a second insulating layer. The method includes modifying, by the application of the ultra-low voltage electron beam, the surface of the first insulating layer to selectively switch an interface between a first state having a first electronic property and a second state having a second electronic property.

A switch based on a phase change material including: a region in said phase change material that couples the first and second conductive electrodes of the switch; and a waveguide including a first end in line with a face of the region in said phase change material and a second end, opposed to the first end, designed to be illuminated by a laser source.

A method of laser-writing submicron pixels with tunable circular polarization and write-read-erase-reuse capability on Bi.sub.2Se.sub.3/WS.sub.2 at room temperature, comprising the steps of applying a laser to the Bi.sub.2Se.sub.3/WS.sub.2, writing a submicron pixel, wherein the submicron pixel has a circular polarization, modifying the circular polarization, allowing the circular polarization to be tuned across a range of 39.9%, tuning photoluminescence intensity, and tuning photoluminescence peak position. A method of growing Bi.sub.2Se.sub.3/WS.sub.2 as a nano-material or two-dimensional heterostructure for laser-writing submicron pixels with tunable circular polarization and write-read-erase-reuse capability on the Bi.sub.2Se.sub.3/WS.sub.2 heterostructure at room temperature.

A method of manufacturing an electronic circuit comprises: providing an electronic circuit having a first configuration in which the circuit comprises a resistive element having a first resistance, and irradiating at least a part of the resistive element with electromagnetic radiation to change the resistance of the resistive element from the first resistance to a second resistance, the second resistance being lower than the first resistance. A method of storing data comprises: receiving a piece of data to be stored; determining a number according to the data; and irradiating at least part of a resistive element with that number of pulses of electromagnetic radiation to change a resistance of the resistive element from a first resistance to a second resistance, the second resistance being lower than the first resistance. A difference between the first resistance and the second resistance is dependent on the number. Corresponding circuits and data storage systems are disclosed.

The present disclosure, in some embodiments, relates to a memory device. The memory device includes a bottom electrode via and a bottom electrode over a top of the bottom electrode via. A data storage layer is over the bottom electrode and a top electrode is over the data storage layer. A top electrode via is on an upper surface of the top electrode and is centered along a first line that is laterally offset from a second line centered upon a bottommost surface of the bottom electrode via. The first line is perpendicular to the upper surface of the top electrode and parallel to the second line.

A method of manufacturing an electronic circuit comprises: providing an electronic circuit having a first configuration in which the circuit comprises a resistive element having a first resistance, and irradiating at least a part of the resistive element with electromagnetic radiation to change the resistance of the resistive element from the first resistance to a second resistance, the second resistance being lower than the first resistance. A method of storing data comprises: receiving a piece of data to be stored; determining a number according to the data; and irradiating at least part of a resistive element with that number of pulses of electromagnetic radiation to change a resistance of the resistive element from a first resistance to a second resistance, the second resistance being lower than the first resistance. A difference between the first resistance and the second resistance is dependent on the number. Corresponding circuits and data storage systems are disclosed.

The present disclosure relates to a resistive random access memory (RRAM) device. The RRAM device has a bottom electrode arranged over a bottom electrode via. A variable resistive dielectric layer is arranged over the bottom electrode. The variable resistive dielectric layer extends to within a recess in an upper surface of the bottom electrode. A top electrode is disposed over the variable resistive dielectric layer. A top electrode via extends outward from an upper surface of the top electrode at a position centered along a first axis that is laterally offset from a second axis centered upon the recess within the upper surface of the bottom electrode. The top electrode via has a smaller total width than the top electrode.

A device for switchably influencing electromagnetic radiation includes a phase change material and an optically responsive structure. The phase change material is switchable between at least a first state and a second state. The first state and the second state have different electrical and/or magnetic properties. The optically responsive structure is in contact with the phase change material and has at least a first nanostructure and a second nanostructure. The first nanostructure is being different from the second nanostructure. The first nanostructure is optically responsive at a predetermined electromagnetic wavelength when the phase change material is in its first state, and non-responsive at the predetermined wavelength when the phase change material is in its second state. The second nanostructure is optically responsive at the predetermined electromagnetic wavelength when the phase change material is in its second state, and non-responsive at the predetermined wavelength when the phase change material is in its first state.