Systems, methods, and apparatus are provided for tuning a memristive property of a device. The device (500) includes a layer of a dielectric material (507) disposed over and forming an interface with a layer of an electrically conductive material (506), and a gate electrode (508) disposed over the dielectric material. The dielectric material layer includes at least one ionic species (302) having a high ion mobility. The electrically conductive material is configured such that a potential difference applied to the device can cause the at least one ionic species to migrate reversibly across the interface into or out of the electrically conductive material layer, to modify the resistive state of the electrically conductive material layer.

Systems, methods, and apparatus are provided for tuning a memristive property of a device. The device (500) includes a layer of a dielectric material (507) disposed over and forming an interface with a layer of an electrically conductive material (506), and a gate electrode (508) disposed over the dielectric material. The dielectric material layer includes at least one ionic species (302) having a high ion mobility. The electrically conductive material is configured such that a potential difference applied to the device can cause the at least one ionic species to migrate reversibly across the interface into or out of the electrically conductive material layer, to modify the resistive state of the electrically conductive material layer.

A method of manufacturing a doped polycrystalline ceramic optical device includes mixing a plurality of transition metal complexes and a plurality of rare-earth metal complexes to form a metal salt solution, heating the metal salt solution to form a heated metal salt solution, mixing the heated metal salt solution and an organic precursor to induce a chemical reaction between the heated metal salt solution and the organic precursor to produce a plurality of rare-earth doped crystalline nanoparticles, and sintering the plurality of rare-earth doped nanoparticles to form a doped polycrystalline ceramic optical device having a rare-earth element dopant that is uniformly distributed within a crystal lattice of the doped polycrystalline ceramic optical device.

A method of manufacturing a doped polycrystalline ceramic optical device includes mixing a plurality of transition metal complexes and a plurality of rare-earth metal complexes to form a metal salt solution, heating the metal salt solution to form a heated metal salt solution, mixing the heated metal salt solution and an organic precursor to induce a chemical reaction between the heated metal salt solution and the organic precursor to produce a plurality of rare-earth doped crystalline nanoparticles, and sintering the plurality of rare-earth doped nanoparticles to form a doped polycrystalline ceramic optical device having a rare-earth element dopant that is uniformly distributed within a crystal lattice of the doped polycrystalline ceramic optical device.

The present invention relates to a data storage system and a method which has high storing capacity and high data access rate and low power consumption. The said data storage system essentially includes at least two optical layers, and which have at least one active layer in which the light is generated, at least one lower electric contact enabling the electric energy to be transferred to the active layer and at least one upper electric contact, at least two reflecting layers reflecting the light generated in the active layer; at least one thermal insulator; at least one magnetic layer, which has at least one storage bit, at least one lower buffer bit, at least one upper buffer bit enabling the data to be transferred up; at least one transparent layer and transfers the light generated by the optical unit to the magnetic layer.

The present invention relates to a data storage system and a method which has high storing capacity and high data access rate and low power consumption. The said data storage system essentially includes at least two optical layers, and which have at least one active layer in which the light is generated, at least one lower electric contact enabling the electric energy to be transferred to the active layer and at least one upper electric contact, at least two reflecting layers reflecting the light generated in the active layer; at least one thermal insulator; at least one magnetic layer, which has at least one storage bit, at least one lower buffer bit, at least one upper buffer bit enabling the data to be transferred up; at least one transparent layer and transfers the light generated by the optical unit to the magnetic layer.

Disclosed is a device for recording information on a magnetic data storage medium which comprises a magnetic field source designed to be capable of generating a magnetic field in the region where the magnetic data storage medium is arranged; a source of electromagnetic radiation at a matrix of controllable mirrors; and a matrix of controllable mirrors mounted in a housing so as to be capable of reflecting electromagnetic radiation by means of the controllable mirrors into the region where the magnetic data storage medium is arranged and/or in another direction. The present invention makes it possible to record information on a fixed magnetic data storage medium.

Memory devices might include control circuitry that, when checking for a match of a stored digit of data and a received digit of data, might be configured to cause the memory device to apply a first voltage level to a control gate of a first memory cell of a memory cell pair, apply a second voltage level different than the first voltage level to a control gate of a second memory cell of that memory cell pair, determine whether that memory cell pair is deemed to be activated or deactivated in response to applying the first and second voltage levels, and deem a match between the stored digit of data and a received digit of data in response, in part, to whether that memory cell pair is deemed to be deactivated.

Memory devices might include control circuitry that, when checking for a match of a stored digit of data and a received digit of data, might be configured to cause the memory device to apply a first voltage level to a control gate of a first memory cell of a memory cell pair, apply a second voltage level different than the first voltage level to a control gate of a second memory cell of that memory cell pair, determine whether that memory cell pair is deemed to be activated or deactivated in response to applying the first and second voltage levels, and deem a match between the stored digit of data and a received digit of data in response, in part, to whether that memory cell pair is deemed to be deactivated.

A component includes a memory region containing optically active material, a control arrangement configured to provide at least one control signal configured to change optical properties of the optically active material, and a detector configured to detect a change in the optical properties of the optically active material. The detector includes an evaluation input region configured to receive at least one evaluation input signal and an evaluation output region configured to provide an evaluation output signal. The memory region is arranged between the evaluation input region and the evaluation output region, and the control arrangement adjoins the memory region.