Quantum acoustics unravels Planckian resistivity

Aydın, Alhun and Keski-Rahkonen, Joonas and Heller, Eric J. (2024) Quantum acoustics unravels Planckian resistivity. Proceedings of the National Academy of Sciences of the United States of America, 121 (28). ISSN 0027-8424 (Print) 1091-6490 (Online)

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Abstract

Strange metals exhibit universal linear-in-temperature resistivity described by a Planckian scattering rate, the origin of which remains elusive. By employing an approach inspired by quantum optics, we arrive at the coherent state representation of lattice vibrations: quantum acoustics. Utilizing this nonperturbative framework, we demonstrate that lattice vibrations could serve as active drivers in the Planckian resistivity phenomenon, challenging prevailing theories. By treating charge carriers as quantum wave packets negotiating the dynamic acoustic field, we find that a competition ensues between localization and delocalization giving rise to the previously conjectured universal quantum bound of diffusion, [Formula: see text], independent of temperature or any other material parameters. This leads to the enigmatic T-linear resistivity over hundreds of degrees, except at very low temperatures. Quantum diffusion also explains why strange metals have much higher electrical resistivity than typical metals. Our work elucidates the critical role of phonons in Planckian resistivity from a unique perspective and reconsiders their significance in the transport properties of strange metals.
Item Type: Article
Uncontrolled Keywords: coherent states; electron–phonon interaction; quantum diffusion; strange metals
Divisions: Faculty of Engineering and Natural Sciences
Depositing User: Alhun Aydın
Date Deposited: 29 Aug 2024 14:43
Last Modified: 29 Aug 2024 14:43
URI: https://research.sabanciuniv.edu/id/eprint/49600

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