In a process analogous to how solids melt into liquids, the electrons in many different metals form crystal-like patterns that can deform and melt, opening new pathways for neuromorphic computing and superconductors, University of Michigan Engineering researchers have found.
"Our work shows that these quantum structures, which are often thought to have a highly ordered structure, actually span a continuum of disorder that could be leveraged to engineer and control these materials," said Robert Hovden, associate professor of materials science and engineering and corresponding author of the study published in Matter.
"Metallurgists often control defects, or disorder, in metals to produce specific properties," Hovden said. "A similar approach might help us harness the potential of quantum materials in future devices. Quantum metallurgy could be the future."
The ability to precisely edit the structure of these electron crystals, also called charge density waves, could open new pathways for controlling superconductors—materials that transport electric current without resistance—since superconducting states can coincide with defects in charge density waves.
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