Nonvanishing Energy Scales at the Quantum Critical Point of CeCoIn5

Abstract

Heat and charge transport were used to probe the magnetic field-tuned quantum critical point in the heavy-fermion metal CeCoIn5. A comparison of electrical and thermal resistivities reveals three characteristic energy scales. A Fermi-liquid regime is observed below TFL, with both transport coefficients diverging in parallel and TFL 0 as H Hc, the critical field. The characteristic temperature of antiferromagnetic spin fluctuations, TSF, is tuned to a minimum but finite value at Hc, which coincides with the end of the T-linear regime in the electrical resistivity. A third temperature scale, TQP, signals the formation of quasiparticles, as fermions of charge e obeying the Wiedemann-Franz law. Unlike TFL, it remains finite at Hc, so that the integrity of quasiparticles is preserved, even though the standard signature of Fermi-liquid theory fails.

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