American Institute of Physics
SEARCH AIP
home contact us sitemap
Physics News Update
Number 564, November 7, 2001 by Phil Schewe, James Riordon, and Ben Stein

The Thinnest Superconducting Wires

The thinnest superconducting wires ever made, only 10 nm wide, have been used in an experiment showing how the superconducting state gets extinguished as the wire narrows.

Just as traffic becomes more problematic as you reduce flow on an interstate from four lanes down to three and then down to two and finally to one lane, so electron pairs (or Cooper pairs, which constitute the supercurrent) moving through very thin passages are sensitive to quantum effects not noticeable in larger wires.

A quantum phase slip (QPS) is one such effect. It is a quantum fluctuation in which the superconducting wavefunction spontaneously tunnels from one state into another, a process which results in a momentary voltage, and therefore a nonzero electrical resistance, even if the temperature could somehow be reduced to absolute zero.

Armed with thin wires (10-20 nm) consisting of molybdenum-germanium deposited onto carbon nanotubes, Michael Tinkham (Tinkham@RSJ.Harvard.edu) and his colleagues at Harvard have conducted the most thorough study yet made of this phenomenon and have definitely shown that resistance goes up as the wire gets thinner.

The quantum resistance effect only becomes noticeable for wires below about 30 nm in size, far smaller than most wires used in today's computers, so there is no bottleneck yet. Future advanced superconducting computers, however, might have trouble; by going to lower temperatures you can eliminate resistivity arising from thermal fluctuations, but not from quantum fluctuations. (Lau et al., Physical Review Letters, 19 November 2001.)

Pyroelectric Accelerator

In a pyroelectric crystal held below a critical temperature (the Curie temperature) heating or cooling causes distortions in the lattice of atoms which in turn creates strong electric fields at the surface of the crystal. James Brownridge of the State University of New York at Binghamton (jdbjdb@binghamton.edu) and Stephen Shafroth of the University of North Carolina (919-962-3015, shafroth@physics.unc.edu) have used these electric fields to create stable, self-focused electron beams with energies as high as 170 keV.

The energy conversion is not especially efficient: inputting watts of heating energy produces only microwatts of output electron beam energy, but this might not be important. Pyroelectric crystals (such as those made of LiNbO3) are widely used as detectors of infrared and THz radiation, but the discovery by Brownridge that they can also be used to produce energetic electron beams if heated or cooled in dilute gas atmospheres means that they can be used to produce x-ray fluorescence for elemental analysis of complex materials, such as tree leaves, rocks, air filters, blood samples, etc. Portable economical x-ray fluorescence is now a real possibility. (Applied Physics Letters, 12 Nov. 2001; also see Brownridge's website.)

Sound Waves Make Filters Finer

Generally, filters that remove particulates from fluids are limited by their pore sizes. That is, a filter with millimeter-sized pores isn't likely to catch many micron-sized particles. On the other hand, a filter with tiny pores can trap small particles at the expense of inhibiting fluid flow.

Donald Feke (Case Western Reserve University, dlf4@po.cwru.edu, 216-368-2750), however, has found a way to reduce the effective pore size in highly porous media without significantly hindering fluid flow. By applying a low power acoustic signal to a filter, Feke can trap particles as much as a hundred times smaller than the nominal filter pore size. An acoustically aided filter provides relatively little resistance to the fluid that passes through it, and yet collects particles as efficiently as a much finer filter. And once the filter has done its job, the trapped particles can be released at the flip of a switch that cuts off the acoustical signal (see figure).

The trapping arises because acoustic signals traveling through a porous material create patterns of standing waves that focus particulate matter toward certain positions on the walls of the pores. Rather than wending their way through the filter, particles headed for the focal points line up to form intricate, stable filaments. In other locations, groups of particles collect in regions of stability within the pores, where they orbit for as long as the signal persists.

In addition to novel filter designs, Feke proposes that acoustic manipulation may lead to efficient material sorting technologies or methods that aid in assembling microscopic structures. Feke presented his work at the 73rd Annual Society of Rheology meeting in Bethesda, Maryland.