A device includes an upper metallic layer, a lower layer, and a memory array positioned between the upper and lower layers, wherein the memory electrical characteristic changes when storing data.

A device includes an upper metallic layer, a lower layer, and a memory array positioned between the upper and lower layers, wherein the memory electrical characteristic changes when storing data.

A processing device receives a request specifying a logical address associated with a host-initiated operation directed at a first portion of a memory device. The processing device accesses a second L2P table comprising a mapping between logical addresses and physical addresses in a second portion of the memory device. A physical location within the second portion of the memory device is identified based on the second L2P table. The physical location corresponds to a portion of a first L2P table that specifies a physical address within the first portion of the memory device that corresponds to the logical address. The physical address is identified based on the portion of the first L2P table and the host-initiated operation is performed at the physical address.

A method of fabricating an optical element comprises: providing a substrate of a transparent material; applying a plurality of circularly polarised focused femtosecond laser pulses to a volume within the substrate to create substantially spherical nanopores in the volume; and applying at least one and not more than ten non-circularly polarised focused femtosecond laser pulses to the volume to transform the spherical nanopores into oblate spheroidal nanopores.

Provided herein are compounds for use as photochromic molecular switches having very long thermal isomerization half-lives and switchable fluorescence properties both in solution and the solid state.

2D heterostructures comprising Bi.sub.2Se.sub.3/MoS.sub.2, Bi.sub.2Se.sub.3/MoSe.sub.2, Bi.sub.2Se.sub.3/WS.sub.2, Bi.sub.2Se.sub.3/MoSe.sub.2. .sub.2xS.sub.2x, or mixtures thereof in which oxygen is intercalated between the layers at selected positions provide high density storage devices, sensors, and display devices. The properties of the 2D heterostructures can be configured utilizing abeam of electromagnetic waves or particles in an oxygen controlled atmosphere.

2D heterostructures comprising Bi.sub.2Se.sub.3/MoS.sub.2, Bi.sub.2Se.sub.3/MoSe.sub.2, Bi.sub.2Se.sub.3/WS.sub.2, Bi.sub.2Se.sub.3/MoSe.sub.2. .sub.2xS.sub.2x, or mixtures thereof in which oxygen is intercalated between the layers at selected positions provide high density storage devices, sensors, and display devices. The properties of the 2D heterostructures can be configured utilizing abeam of electromagnetic waves or particles in an oxygen controlled atmosphere.

A device includes an upper metallic layer, a lower layer, and a nano sensor array positioned between the upper and lower layers to detect a presence of a gas, a chemical, or a biological object, wherein each sensor's electrical characteristic changes when encountering the gas, chemical or biological object.

A device includes an upper metallic layer, a lower layer, and a nano sensor array positioned between the upper and lower layers to detect a presence of a gas, a chemical, or a biological object, wherein each sensor's electrical characteristic changes when encountering the gas, chemical or biological object.

An optical mechanism and an optical system for optical-medium storage. The mechanism includes an optical-medium storage device, and an optical-medium transmission device. The optical-medium storage device is provided with an optical-medium storage module, configured to store an optical medium, and an optical-medium input-output end, configured to receive and transmit the optical medium to the optical-medium storage module and read data from the optical-medium storage module. The optical-medium receiving module is configured to receive the optical medium transmitted from outside and transmit the optical medium to the optical-medium storage module via the optical-medium input-output end, according to a receiving instruction. The optical-medium storing module is configured to form a storage path for the optical medium with the optical-medium storage module. The optical-medium reading module is configured to provide an interface for reading and read the optical medium stored in the optical-medium storage module, according to a reading instruction.