Quantum simulation reveals mobility edge in a low-dimensional disordered landscape

Quantum simulation reveals mobility edge in a low-dimensional disordered landscape
University of Illinois Professor of Physics Bryce Gadway (right) and graduate student Fangzhao Alex An build a quantum simulation experiment at Loomis Laboratory of Physics in Urbana, Illinois. Photo by L. Brian Stauffer, University of Illinois at Urbana-Champaign

A recent flood of research scholarship on electronic transport in low-dimensional (2D or 1D) materials like graphene or carbon nanotubes reflect the tremendous potential of these materials to unveil a deeper understanding of the laws that govern the sometimes surprising emergent behavior of electrons. Scientists have probed novel materials like these to uncover the physics of topological superconductivity and topological insulators. But one of the biggest challenges researchers face in studying real materials is the presence of uncontrolled impurities that influence electronic transport.

One way to get around this dirty issue of disorder is to study the same types of physical phenomena in artificial materials that have no natural imperfections. In recent decades, researchers have used neutral atoms moving in pristine crystals formed by laser light to perform quantum simulations to observe physical effects that would be hard to see in real electronic materials.

Now scientists at the University of Illinois at Urbana-Champaign using an innovative quantum simulation technique have made one of the first observations of a mobility edge in a low-dimensional system. Physics professor Bryce Gadway and graduate student Fangzhao Alex An were able to combine a disordered virtual material—in this case, a pair of coupled 1D chains—with artificial magnetic fields to explore this phenomenon.

An explains, “The artificial magnetic field we engineered causes the neutral atoms in our experiment to behave like electrons in extremely large magnetic fields, equivalent to applying hundreds of Tesla-level magnets. We were able to vary the strength of our artificial magnetic field to tune the properties of our atoms and strongly modify the observed mobility edge.”

So what exactly is a mobility edge? It’s an energy-dependent insulator-to-conductor transition that occurs in disordered systems—a regime of metallic transport that arises out of a special kind of insulator called an Anderson insulator. Only two groups have ever observed a mobility edge in 3D, and the first was U of I physics professor Brian DeMarco’s research group in 2011. Importantly, the phenomenon is induced by disorder, and according to the laws of localization physics, a mobility edge, let alone any kind of metallic behavior, should not occur in 2D or 1D materials.

Gadway comments, “This observation is truly noteworthy—this kind of behavior shouldn’t occur in lower dimensional systems with a random disorder. There’s a subtlety to realizing it in one or two dimensions that relies on a sort of pseudo-random disorder. There are correlations in the disorder we engineered. It turns out this can allow for a metal-insulator transition.”

Read more: Quantum simulation reveals mobility edge in a low-dimensional disordered landscape

thumbnail courtesy of physics.illinois.edu

Related Links

One-dimensional material for next generation electronics

A unique combination of catalysts opens doors to making useful compounds

Researchers improve textile composite manufacturing