In certain nanomaterials, electrons are able to race through custom-built roadways just one atom wide. To achieve excellent efficiency, these one-dimensional paths must be paved with absolute perfection--a single errant atom can stop racing¹ electrons in their tracks or even launch it backwards². Unfortunately, such imperfections are inevitable³. Now, a pair of scientists from the U.S. Department of Energy's Brookhaven National Laboratory and Ludwig Maximilian University in Munich have proposed the first solution to such subatomic stoppage: a novel way to create a more robust⁴ electron wave by binding⁵ together the electron's direction of movement and its spin. The trick, as described in a paper published November 16 in Physical Review Letters and featured as an Editor's Selection, is to exploit magnetic ions lacing the electron racetrack. The theory could drive advances in nanoscale engineering for data- and energy-storage technologies. 

 

"One-dimensional materials can only be very good conductors if they are defect-free, but nothing in this world is perfect," said Brookhaven physicist⁶ Alexei Tsvelik, one of two authors on the paper. "Our theory, the first of its kind, lays out a way to protect electron waves and optimize⁷ these materials."

 

The work relies on a model system called a Kondo chain, where flowing electrons interact with local magnetic moments within a material. Properly harnessed, this powerful interaction could allow materials to behave like perfect conductors and offer high efficiency. 

 

 

Atom-wide channels only allow motion in one of two opposing directions: right or left. Electrons traveling through such a narrow path--racing along in what are called charge-density waves--can be easily reversed by virtually any obstacle. 

 

"The wave rises like an electronic tsunami⁸ that is expected to carry electrons smoothly⁹ in one direction," Tsvelik said. "But it turns out that this tsunami can be very easily pinned by disorder¹⁰, by impurities¹¹ in the material."

 

This "tsunami" shifts direction through a conductivity-smothering phenomenon called backscattering--like a wave breaking against sheer cliffs. But while direction is easily reversed, another feature of the electron is much more resilient: spin. The spin of an electron--like a perpetually spinning quantum top--can only be described as either up or down, and it is impervious¹² to simple imperfections in the material. The trick, then, is to teach the directional wave to lean on spin for support.

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