Josephson junctions (JJ) based on bilayers of azimuthally misaligned two-dimensional materials having superconducting states are provided. Also provided are electronic devices and circuits incorporating the JJs as active components and methods of using the electronic devices and circuits. The JJs are formed from bilayers composed of azimuthally misaligned two-dimensional materials having a first superconducting segment and a second superconducting segment separated by a weak-link region that is integrated into the bilayer.

Techniques facilitating formation of amorphous superconducting alloys for superconducting circuits are provided. A device can comprise one or more superconducting components that comprise an amorphous superconducting alloy comprising two or more elements. At least one element of the two or more elements is a superconducting element.

Topological superconductive and memristive nanostructured toroidal-tower array devices are invented for direct electrochemical sensing of multiple biomarkers based on the biomimetic glucose . . . pyruvate . . . acetyl CoA (ACoA) fuel energy pathway of mitochondria. The device comprises flexible fractional Josephson junctions (FFJJ) made of innate organometallic protein cross-linked with conductive polymers forming a first layer membrane on the electrode surface, a medium comprising of glucose and acetyl CoA (ACoA) molecules (as the GA medium), serves as an insulator or a conductor when pyruvate molecules activated the medium, and the second layer comprising of an innate Heat Shock Protein (HSP) cross-linked with the similar polymers on top of the first layer. Cooper-pairs reentry between the state of superconductivity at room temperature and the memristive state are enabled through a molecular “Valve” GA medium activated by a biomarker to switch the electron move in a 3D horizontal-vertical pathway from low Josephson frequency to high Josephson frequency, enabled the device to direct sensitive and quantitative sensing multiple-biomarkers without antibody or labeling, wherein many applications are discussed.

A device includes a source region, a drain region, a channel region, a pair of depletion gates, an accumulation gate, and a superconductive resonator. The channel region is between the source region and the drain region. The pair of depletion gates are spaced apart from each other. The pair of depletion gates both overlap the channel region and define a quantum dot qubit region in the channel region and between the pair of depletion gates. The accumulation gate is above and crossing the pair of depletion gates. The superconductive resonator is laterally adjacent the quantum dot qubit region.

A superconductor tape and method for manufacturing, measuring, monitoring, and controlling same are disclosed. Embodiments are directed to a superconductor tape which includes a superconductor film overlying a buffer layer which overlies a substrate. In one embodiment, the superconductor film is defined as having a c-axis lattice constant higher than 11.74 Angstroms. In another embodiment, the superconductor film comprises BaMO.sub.3, where M=Zr, Sn, Ta, Nb, Hf, or Ce, and which has a (101) peak of BaMO.sub.3 elongated along an axis that is between 60° to 90° from an axis of the (001) peaks of the superconductor film. These and other embodiments achieve well-aligned nanocolumnar defects and thus a high lift factor, which can result in superior critical current performance of the tape in, for example, high magnetic fields.

A reinforced thin-film device is disclosed. The reinforced thin-film device comprising: a substrate having a top surface for supporting an epilayer; a mask layer patterned with a plurality of nanosize cavities disposed on said substrate to form a needle pad; a thin-film of, relative to the substrate, lattice-mismatched semiconductor disposed on said mask layer, wherein said thin-film comprises a plurality of in parallel spaced semiconductor needles of said lattice-mismatched semiconductor embedded in said thin-film, wherein said plurality of semiconductor needles are vertically disposed in the axial direction towards said substrate in said plurality of nanosize cavities of said mask layer; a, relative to the substrate, lattice-mismatched semiconductor epilayer provided on said thin-film and supported thereby; and a FinFET transistor arranged on the lattice-mismatched semiconductor epilayer. The FinFET transistor comprising: a fin semiconductor structure comprising an elongate protruding core portion, the fin semiconductor structure being arranged on the lattice-mismatched semiconductor epilayer, a first and a second nanostructured electrode radially enclosing respectively a source end and a drain end of the protruding core portion, and a nanostructured gate electrode radially enclosing a central portion of the protruding core portion, the central portion being a portion of the protruding core portion between the source end and the drain end.

A superconductor tape and method for manufacturing, measuring, monitoring, and controlling same are disclosed. Embodiments are directed to a superconductor tape which includes a superconductor film overlying a buffer layer which overlies a substrate. In one embodiment, the superconductor film is defined as having a c-axis lattice constant higher than 11.74 Angstroms. In another embodiment, the superconductor film comprises BaMO.sub.3, where M=Zr, Sn, Ta, Nb, Hf, or Ce, and which has a (101) peak of BaMO.sub.3 elongated along an axis that is between 60° to 90° from an axis of the (001) peaks of the superconductor film. These and other embodiments achieve well-aligned nanocolumnar defects and thus a high lift factor, which can result in superior critical current performance of the tape in, for example, high magnetic fields.

A tunable oscillator including a Josephson junction. In some embodiments, the tunable oscillator includes a first superconducting terminal, a second superconducting terminal, a graphene channel including a portion of a graphene sheet, and a conductive gate. The first superconducting terminal, the second superconducting terminal, and the graphene channel together may form a Josephson junction having an oscillation frequency, and the conductive gate may be configured, upon application of a voltage across the conductive gate and the graphene channel, to modify the oscillation frequency.

Techniques regarding qubit structures comprising ion implanted Josephson junctions are provided. For example, one or more embodiments described herein can comprise an apparatus that can include a strip of superconducting material coupling a first superconducting electrode and a second superconducting electrode. The strip of superconducting material can have a first region comprising an ion implant and a second region that is free from the ion implant.

The present description relates to a method and a device for providing anyons that may be used for topological quantum computation. The method comprises the steps of providing a magnetic material containing at least one magnetic texture providing a superconductor containing at least one vortex; creating at least one magnetic texture-vortex pair by coupling the magnetic material to the superconductor, wherein each magnetic texture-vortex pair binds an anyon being localized at the vortex of the respective magnetic texture-vortex pair in the superconductor.