Abstract: An apparatus for separating oxygen from a gas mixture includes an oxide layer having ion transport channels therein, which facilitate the migration of oxygen ions from a first side to a second side of the layer. Molecular oxygen is decomposed into oxygen ions at the first side, whereas oxygen ions recombine into molecular oxygen at the second side. A first chamber into which a gas mixture (e.g., air) is admitted is located on the first side of the oxide layer. A second chamber receives oxygen from the oxide layer, and is located on the second side of the oxide layer; the second chamber has a polarizable medium that is in contact with the oxide layer. A gate electrode in contact with the polarizable medium applies an electric field to the second side of the oxide layer, thereby driving oxygen ions across the oxide layer.

Abstract: A layered stack includes a first layer having a first spin polarization and a first magnetic moment, as well as a second layer (in contact with the first layer) having a second spin polarization a second magnetic moment. The first and second spin polarizations have the same orientation, but the first and second magnetic moments have orientations that partially cancel each other, thereby recommending the layered stack for applications in magnetic tunnel junctions, for example.

Abstract: A layered stack includes a first layer having a first spin polarization and a first magnetic moment, as well as a second layer (in contact with the first layer) having a second spin polarization a second magnetic moment. The first and second spin polarizations have the same orientation, but the first and second magnetic moments have orientations that partially cancel each other, thereby recommending the layered stack for applications in magnetic tunnel junctions, for example.

Abstract: Electrolyte gating with ionic liquids is a powerful tool for inducing conducting phases in correlated insulators. An archetypal correlated material is VO2 which is insulating only at temperatures below a characteristic phase transition temperature. We show that electrolyte gating of epitaxial thin films of VO2 suppresses the metal-to-insulator transition and stabilizes the metallic phase to temperatures below 5 K even after the ionic liquid is completely removed. We provide compelling evidence that, rather than electrostatically induced carriers, electrolyte gating of VO2 leads to the electric field induced creation of oxygen vacancies, and the consequent migration of oxygen from the oxide film into the ionic liquid.

Abstract: A structure includes a tetragonal Heusler of the form Mn1+cX, in which X includes an element selected from the group consisting of Ge and Ga, with 0?c?3. The tetragonal Heusler is grown directly on (or more generally, over) a substrate oriented in the direction (001) and of the form YMn1+d, wherein Y includes an element selected from the group consisting of Ir and Pt, with 0?d?4. The tetragonal Heusler and the substrate are in proximity with each other, thereby allowing spin-polarized current to pass from one through the other. This structure may form part of a magnetic tunnel junction magnetoresistive device, and an array of such magnetoresistive devices may together form an MRAM.

Abstract: A structure includes a tetragonal Heusler of the form Mn1+cX, in which X includes an element selected from the group consisting of Ge and Ga, with 0?c?3. The tetragonal Heusler is grown directly on (or more generally, over) a substrate oriented in the direction (001) and of the form YMn1+d, wherein Y includes an element selected from the group consisting of Ir and Pt, with 0?d?4. The tetragonal Heusler and the substrate are in proximity with each other, thereby allowing spin-polarized current to pass from one through the other. This structure may form part of a magnetic tunnel junction magnetoresistive device, and an array of such magnetoresistive devices may together form an MRAM.

Abstract: Electrolyte gating with ionic liquids is a powerful tool for inducing conducting phases in correlated insulators. An archetypal correlated material is VO2 which is insulating only at temperatures below a characteristic phase transition temperature. We show that electrolyte gating of epitaxial thin films of VO2 suppresses the metal-to-insulator transition and stabilizes the metallic phase to temperatures below 5 K even after the ionic liquid is completely removed. We provide compelling evidence that, rather than electrostatically induced carriers, electrolyte gating of VO2 leads to the electric field induced creation of oxygen vacancies, and the consequent migration of oxygen from the oxide film into the ionic liquid.

Abstract: A shadow masking device for use in the semiconductor industry includes self-aligning mechanical components that permit shadow masks to be exchanged while maintaining precise alignment with the target substrate. The misregistration between any two of the various layers in the formed structure can be kept to less than 40 microns.

Abstract: A magnetic tunnel junction (MTJ) memory cell and a magnetic random access memory (MRAM) incorporating the cells has upper and lower cell electrodes that are formed of bilayers that provide electrical connection between the cells and the copper word and bit lines of the MRAM. The bilayers are formed of a first layer of tantalum nitride or tungsten nitride and a second layer of tantalum or tungsten. In one embodiment TaN is formed directly on the copper and low-resistivity alpha-Ta is formed directly on the TaN. If the cells use an antiferromagnetic layer to fix the moment of the pinned ferromagnetic layer, then Pt—Mn is the preferred material formed over the alpha-Ta. The bilayer can function as a lateral electrode to connect a horizontally spaced-apart cell and a copper stud in the MRAM.