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Physics News Update

Number 553, August 23, 2001 by Phil Schewe, James Riordon, and Ben Stein

Superheavy Hydrogen

Superheavy hydrogen, a nucleus with one proton and four neutrons, has been made by Russian, French, and Japanese physicists at the accelerator at the Joint Institute for Nuclear Physics (JINR) near Moscow.

An exotic beam of helium-6 nuclei struck a hydrogen target, resulting in the occasional production of a hydrogen-5 nucleus plus a helium-2 nucleus. These unstable particles quickly fly apart. The debris--two protons from the 2He breakup and a triton and two neutrons from the 5H breakup--tell the story.

If the two-nucleon version of hydrogen is called deuterium and the three-nucleon hydrogen is called triton, what would one call a five-nucleon (intensely neutron rich) hydrogen--pentium? (Korsheninnikov et al., Physical Review Letters, 27 August 2001.)

A Superconducting Single-Photon Detector

A superconducting single-photon detector has been built by a Russian-US collaboration (Roman Sobolewski, University of Rochester, 716-275-1551, sobolewski@ece.rochester.edu), offering immediate applications in testing computer chips and more speculative applications for Mars-Earth communications.

The researchers fabricated extremely thin strips of niobium nitride, a metallic compound that becomes superconducting in liquid helium near absolute zero. Then, they made a detector based on these strips, each only a micron wide and several atoms thick.

The detector enabled the researchers to observe single visible and infrared photons. That's because the superconducting strips lack the electrical noise that ordinarily obscures a single-photon signal.

The detector can record the small amount of infrared light that is released when a transistor switches on or off. A California company is using the detector for this purpose. Since the detector can detect bursts as short as picoseconds, they can determine whether or not high-speed transistors are switching on at the right time.

In more speculative applications, this detector could be employed as an efficient detector of optical signals for wireless communications between Mars and Earth. (Gol'tsman et al., Applied Physics Letters, 6 August 2001; also see Rochester press release.)

An Electromechanical Transistor

An electromechanical transistor (EMT) developed at the University of Munich shuttles a single electron from one electrode to another at 100 MHz rates. There was a time when solid state devices, in which only electrons are moving, were preferable to mechanical devices with lots of moving parts. But this attitude is changing as new advances come about in the field of nanomechanical systems (NEMS).

Artur Erbe (artur.erbe@physik.uni-meunchen.de, 49-89-2180-3349) and his colleagues have succeeded in placing a metal island atop a swinging silicon pendulum oscillating at radio frequencies between two other electrodes. One can think of the pendulum as the clapper of a bell resonating at a frequency of 100 MHZ, or the whole device as a transistor in which a single electron is being shoveled from a "source" electrode to a "drain" electrode.

The Munich setup may afford a new way of establishing a high-precision current standard since although somewhat slower than some other single electron transistors (SET) it allows the single electron only one way (riding on the moving island) of getting from one electrode to the other, in comparison to other metallic SETs in which the electron can tunnel in a variety of paths, a habit which actually lowers the effective control one has over the electron. With the mechanical approach to transferring single electrons, the high sensitivity to environmental conditions may allow the SET to serve as an ultra-sensitive position, gas, or force sensor. (Erbe et al., Physical Review Letters, 27 August 2001.)

Crystalline Ion Beams

Crystalline ion beams have been created by scientists at the Ludwig-Maximilians University (LMU) in Munich. Even as beams of positively charged ions zip around an accelerator at high longitudinal speeds, they can be "cooled" in the transverse direction through the mediation of electrons or laser light. This allows the beam to become denser.

The LMU scientists went about their business in the following way: first they cooled the ions, using two laser beams, and then accelerated the ion-crystal with the same lasers. The Mg ion crystal moves through the PALLAS storage ring at 2800 m/sec (equivalent to a beam energy of 1 eV) around a track with a diameter of about 12 cm. The crystal can survive for up to about 3000 circuits. (Schatz et al., Nature, 16 August 2001.)