Abstract: A method includes providing a superconducting material having pinning sites that can pin magnetic vortices within the superconducting material. The method also includes pinning one or more magnetic vortices at one or more of the pinning sites. An information storage apparatus includes a superconducting material, doped particles within the superconducting material that can pin dipole magnetic vortices, a magnetic tip that generates pinned magnetic vortices and a magnetic detector that detects pinned magnetic vortices.

Abstract: A novel nonvolatile memory element or cell comprising a memory means consisting of at least one superconducting ring (21, 22) and a detector means consisting of a MOSFET. The superconducting ring and the MOSFET are arranged in such a manner that a magnetic flux created by the superconducting ring (21, 22) passes through a channel zone of the MOSFET. Information is held in the superconducting ring in a form of permanent current and is detected electrically as variation in the conductivity of the channel zone of the MOSFET.

Abstract: A planar type superconductive thin film transistor using oxide superconductive materials and utilizing a long distance proximity effect is obtained with a good reproducibility.In order to obtain the planar type superconductive transistor utilizing the long distance proximity effect, an interlayer separating film that plays a similar role with resists is used together with conventional resists in high temperature annealing process.

Abstract: This invention relates to a magnetic memory including a first superconductor wire, a second superconductor wire disposed in such a manner as to cross the first superconductor wire substantially orthogonally, a first magnetic film disposed at the point of intersection between the first and second superconductor wires and a second magnetic film interposed between the first magnetic film and the first or second superconductor films, wherein at least one of the uniaxial magnetic anisotropy within the plane of the films and coercive force of the first and second magnetic films is mutually different. Furthermore, a superconductor film containing a large number of microscopic Josephson junctions is disposed between the first and second magnetic films or on the other side of the superconductor wire connected to the magnetic film, and a lead wire for applying a current is connected to the superconductor film.

Abstract: A noble unit cell structure in a magnetic memory is disclosed, in which a ferromagnetic film is sandwiched between first and second wires at a cross-over area, and third and fourth wires are provided so as to sandwich the first wire. The third wire is contacted with the first wire so as to form a ring portion surrounding the ferromagnetic film and the second wire. The fourth wire is isolated from the first wire. At least the first, second and third wires are made of superconductive material. The ferromagnetic film has a uniaxial anisotropy along the second wire and its magnetization direction can be reversed by applying pulse currents to the second and fourth wires in an information writing process. In a reading process, the magnetization direction of the ferromagnetic film can be recognized by detecting either one of a superconductive state or a normal conductive state at the ring portion of the first and third wires.

Abstract: This fast-access data storage circuit is made of a semiconductor material with a two-dimensional carrier gas between two of its layers. The material is rendered superconducting by a suitable choice of the temperature and magnetic field conditions. The circuit is formed by a plurality of memory cells, each of which is formed by two selection transistors, a semiconductor loop, ohmic contacts and a grid which is arranged on the loop and one of the contacts. The superconductivity reduces the access time. One selection controls the reading of data or the writing of a state "1" in the loop, while the other selection transistor controls the cancellation of the data and hence the writing of a state "0" by means of the grid arranged on the loop.