Nature Communications (Nov 2023)

Evidence for charge delocalization crossover in the quantum critical superconductor CeRhIn5

  • Honghong Wang,
  • Tae Beom Park,
  • Jihyun Kim,
  • Harim Jang,
  • Eric D. Bauer,
  • Joe D. Thompson,
  • Tuson Park

DOI
https://doi.org/10.1038/s41467-023-42965-1
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 8

Abstract

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Abstract The nature of charge degrees-of-freedom distinguishes scenarios for interpreting the character of a second order magnetic transition at zero temperature, that is, a magnetic quantum critical point (QCP). Heavy-fermion systems are prototypes of this paradigm, and in those, the relevant question is where, relative to a magnetic QCP, does the Kondo effect delocalize their f-electron degrees-of-freedom. Herein, we use pressure-dependent Hall measurements to identify a finite-temperature scale E loc that signals a crossover from f-localized to f-delocalized character. As a function of pressure, E loc(P) extrapolates smoothly to zero temperature at the antiferromagnetic QCP of CeRhIn5 where its Fermi surface reconstructs, hallmarks of Kondo-breakdown criticality that generates critical magnetic and charge fluctuations. In 4.4% Sn-doped CeRhIn5, however, E loc(P) extrapolates into its magnetically ordered phase and is decoupled from the pressure-induced magnetic QCP, which implies a spin-density-wave (SDW) type of criticality that produces only critical fluctuations of the SDW order parameter. Our results demonstrate the importance of experimentally determining E loc to characterize quantum criticality and the associated consequences for understanding the pairing mechanism of superconductivity that reaches a maximum T c in both materials at their respective magnetic QCP.