Alexey Bezryadin, a professor of physics at Illinois, has created high-quality superconducting wires with molecular dimensions, and measured their behavior in magnetic fields of various strengths. The observational results have confirmed that theories developed for bulk superconductors also apply to molecular-scale superconductors.
CHAMPAIGN, Ill. – Ultrathin superconducting wires can withstand stronger magnetic fields than larger wires made from the same material, researchers now report. This finding may be useful for technologies that employ superconducting magnets, such as magnetic resonance imaging.
As described in the Jan. 14 issue of the journal Physical Review Letters, researchers at the University of Illinois at Urbana-Champaign have created high-quality superconducting wires with molecular dimensions, and measured their behavior in magnetic fields of various strengths. The observational results have confirmed that theories developed for bulk superconductors also apply to molecular-scale superconductors.
The diagram shows the principle of molecular templating, i.e. a method of nanofabrication used to make superconducting nanowires with molecular dimensions. The substrate is a Si wafer with thin films of silicon oxide (SiO2) and silicon nitride (SiN) deposited over it. A 100 nm wide trench is formed in the SiN-SiO2 bilayer. Nanotubes are placed across the trench from a solution. The sample then is sputter-coated with a desired material, i.e. a superconducting amorphous alloy in Bezryadin’s case. The inset shows a scanning electron micrograph of a nanowire produced by molecular templating.
“Our experimental results show an excellent agreement with the theory of pair-breaking perturbations, even at high magnetic fields,” said Alexey Bezryadin, a professor of physics at Illinois. “The theory takes into account both spin and orbital contributions.”
To study this phenomenon, the researchers began by placing a single-wall carbon nanotube across a narrow trench (about 100 nanometers wide) etched in the surface of a silicon wafer. The nanotube was then coated with a thin film of superconducting material (molybdenum-germanium), chilled below its critical temperature, and its properties measured in the presence of a magnetic field.
“Usually, when you apply a magnetic field to a superconductor, the field suppresses or even destroys the superconductivity,” Bezryadin said. “The magnetic field pulls apart the two electrons forming Cooper pairs and also rotates their spins. As the superconductor becomes smaller, however, the destructive effects of the magnetic field become weaker.”
The magnetic field showed a remarkably weak effect on nanowires, the researchers report. Both the orbital and the spin pair-breaking effects were strongly suppressed in the nanowires. The orbital effect was weak because of the small dimensions of the wire (about 10 nanometers in diameter) and the spin effect was weakened by spin-orbit interactions.
“One should not set a goal of reducing the wire’s diameter indefinitely, however,” Bezryadin said. “As the diameter is decreased, disorder and boundary effects become more and more important. These factors also weaken superconductivity.”
In fact, the researchers’ results show that thin wires do not really have zero resistance, as bulk samples do. They also show that the thinner the wire the higher its electrical resistance is.
Because nanoscale superconductors don’t repel magnetic fields, they could prove useful in a variety of superconducting applications. By incorporating nanowires as filaments in bigger superconducting wires, for example, more current could be carried without being destroyed by a magnetic field.
“Again, one needs to optimize the diameters of the wires in order to produce cables with the highest ability to carry strong currents and withstand strong magnetic fields,” Bezryadin said. “The nanowire should not be too thick, in order to be less sensitive to magnetic fields; but it also should not be too thin, in order to be fully superconducting. A correct balance should be achieved.”
The work was performed by Bezryadin, postdoctoral research associate Andrey Rogachev and graduate research assistant Anthony Bollinger. Funding came from the National Science Foundation, the Alfred P. Sloan Foundation and the U.S. Department of Energy.
Editor’s note: To reach Alexey Bezryadin, call 217-333-9580; e-mail: bezryadi@illinois.edu.
