A magnetic topological nanowire structure comprises a superconductor and a quasi-1D magnetic nanowire. The quasi-1D magnetic nanowire is coupled to or embedded in the superconductor to produce a self-contained interaction resulting in a spatially separated pair of Majorana fermions. The pair of Majorana fermions corresponds to the topological superconductor and each of the pair of the Majorana fermions are localized near a respective endpoint of the nanowire.

A magnetoresistance effect element includes a recording layer containing a ferromagnetic body, and including a first fixed and second magnetization regions having magnetization components fixed substantially in a direction antiparallel to the in-plane direction to each other, and a free magnetization region disposed between the first and second fixed magnetization regions and having a magnetization component invertible in the in-plane direction, a domain wall disposed between the first fixed magnetization region and the free magnetization region, and being movable within the free magnetization region, and a magnetic nanowire having a width of 40 nm or less. The thickness of the recording layer is 40 nm or less and at least half but no more than twofold the width of the magnetic nanowire. The element further includes a barrier layer disposed on the recording layer, and a reference layer disposed on the barrier layer and containing a ferromagnetic body.

Described are coated iron oxide nanorods (IONRs) containing an iron oxide core and a coating surrounding the core, and pharmaceutical compositions containing these coated IONRs. The iron oxide core of the coated IONRs has strong magnetic property, i.e., a magnetic flux density of at least 10 emu/g, induced using 1 T magnetizing field strength, at room temperature. The coating of the coated IONRs can be formed by a polymer, such as an amphiphilic polymer. The coated IONRs are stable in an aqueous medium for at least 30 mins, at room temperature, while maintain the superior magnetic property of the core, achieving a separation efficiency of at least 80% within only 1 min of magnet time. Optionally, the coated IONRs contain one or more active agents embedded in the coating of the coated IONRs, for systemic or local delivery.

The present invention is in the field of spintronics, and relates to a highly efficient spin filter device, such as a spin-polarizer or a spin valve, and a method for fabrication thereof.

The present invention includes nanotubes or rods, methods and arrays using plasmonic-magnetic bifunctional nanotubes or rods comprising: one or more silica nanotubes or rods; one or more nanomagnets embedded in a portion of the silica nanotubes or rods; and plasmonic metal nanoparticles uniformly coating in or on at least a portion of the surface of the nanomagnets and the silica nanotubes surface-coated.

The present invention includes nanotubes or rods, methods and arrays using plasmonic-magnetic bifunctional nanotubes or rods comprising: one or more silica nanotubes or rods; one or more nanomagnets embedded in a portion of the silica nanotubes or rods; and plasmonic metal nanoparticles uniformly coating in or on at least a portion of the surface of the nanomagnets and the silica nanotubes surface-coated.

Provided in one embodiment is a dynamically tunable structure including an elastic layer, and a plurality of ferromagnetic micropillars disposed over the elastic layer. The elastic layer may have an elasticity that is greater than an elasticity of the micropillars.

The present invention achieves a high-energy product using Ferromagnetic 3D elements such as nanowires and methods of making the same. The high energy products or magnets of the invention are able to achieve high magnetization and maintain the magnetic properties at a greater range of temperatures than currently known magnets. For example, a high energy product includes at least one material A selected from the group consisting essentially of Fe, Co, and Ni, wherein material A is in the form of nanowires formed by a solvothermal chemical process. A high energy product may also include at least one material A selected from the group consisting essentially of Fe, Co, and Ni, and at least one material B selected from the group consisting essentially of Fe, Co, and Ni, wherein material A and material B are in the form of an alloy of nanowires formed by a solvothermal chemical process.

The present invention provides a ferromagnetic metal nanowire dispersion having an excellent dispersibility, from which a ferromagnetic metal nanowire film having an excellent electrical conductivity can be made. The present invention relates to a ferromagnetic metal nanowire dispersion comprising a ferromagnetic metal nanowire and a polymer compound.

Various embodiments include an electrical device comprising an antiferromagnetic topological insulator having a surface comprising a bulk domain wall configured to support a first type of 1D chiral channel, a surface step configured to support a second 1D chiral channel and intersecting the bulk domain wall to form thereat a quantum point junction.