Separation of Energy Scales in Undoped YbRh<sub>2</sub>Si<sub>2</sub>Under Hydrostatic Pressure

Tokiwa, Y.; Gegenwart, P.; Geibel, C.; Steglich, F.

doi:10.1143/jpsj.78.123708

Cited by 38 publications

(66 citation statements)

References 43 publications

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“…This finding is confirmed by a study on pure YbRh 2 Si 2 under physical pressure. 35) Also no relation between the second transition at T L and the T (B) line is evident as only for Yb(Rh 0.93 Co 0.07 ) 2 Si 2 T L vanishes in proximity to B line rendering this an accidental coincidence. With B assigned to the Kondo breakdown, we infer from B N > B that the magnetism extends into the regime where the Kondo effect is operating.…”

Section: Detaching the Af Instability And Kondo Breakdown By Chemicalmentioning

confidence: 97%

Break Up of Heavy Fermions at an Antiferromagnetic Instability

et al. 2011

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We present results of high-resolution, low-temperature measurements of the Hall coefficient, thermopower, and specific heat on stoichiometric YbRh 2 Si 2 . They support earlier conclusions of an electronic (Kondo-breakdown) quantum critical point concurring with a field induced antiferromagnetic one. We also discuss the detachment of the two instabilities under chemical pressure. Volume compression/expansion (via substituting Rh by Co/Ir) results in a stabilization/weakening of magnetic order. Moderate Ir substitution leads to a non-Fermi-liquid phase, in which the magnetic moments are neither ordered nor screened by the Kondo effect. The so-derived zero-temperature global phase diagram promises future studies to explore the nature of the Kondo breakdown quantum critical point without any interfering magnetism.KEYWORDS: quantum criticality, heavy fermion, YbRh 2 Si 2 , Kondo breakdown Different types of quantum critical pointsQuantum phase transitions in matter arise due to competing interactions, which result in competing ground-state properties. When a quantum phase transition is continuous it marks a quantum critical point (QCP). In the last decade, antiferromagnetic (AF) heavy-fermion metals turned out to be model systems to study quantum criticality. In these systems, QCPs are caused by the competition between the local Kondo and the non-local Ruderman-Kittel-Kasuya-Yoshida (RKKY) interaction. Studies on the interplay between these two phenomena have revealed different types of QCPs.1) In the itinerant, spin-density-wave (SDW) scenario the heavy fermions keep their integrity at the QCP. In such a case the QCP can be treated as a continuous classical phase transition in an effective dimension d + z, where d is the spatial dimensionality and z, the dynamic exponent defined via ξ t ∼ ξ z r , describes the number of additional spatial dimensions that the time dimension corresponds to. ξ r and ξ t denote the correlation length and correlation time which both diverge at a QCP.2-4) Several heavy-fermion compounds, e. g., CeCu 2 Si 2 , 5) CeNi 2 Ge 2 6) and Ce 1−x La x Ru 2 Si 2 7) were found to exhibit this type of itinerant AF QCP.However, in a few heavy-fermion metals the AF instability appears to be accompanied by a breakdown of the Kondo effect, [8][9][10] 15)The two FL phases adjacent to the QCP appear to posses different Fermi surfaces as inferred from a variety of electronic transport measurements closely related to the Fermi surface properties. Most important evidence stems from Hall effect measurements in the so called crossed-field geometry. Here, two perpendicular magnets are used to disentangle the two tasks of the magnetic field: One field, B 1 , generates the Hall response, and a second field, B 2 , tunes the ground state of the sample. The power of the crossed-field setup lies in the ability to extract the initial-slope Hall coefficient as a linear response to B 1 despite measuring at a finite tuning field B 2 .Isotherms of the field dependent Hall coefficient R H (B 2 ) depicted in Fig. 1(a) show...

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Section: Detaching the Af Instability And Kondo Breakdown By Chemicalmentioning

confidence: 97%

Break Up of Heavy Fermions at an Antiferromagnetic Instability

et al. 2011

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“…To understand non-universal NFL behaviors [2] in a unified way, dynamics of Kondo holes in a quantum critical system should be further investigated, since heterogeneous electronic states appear to be realized in a variety of correlated electron systems. For instance, it is interesting to ask what is the degree and influence of electronic heterogeneity in YbRh 2 Si 2 , particularly, given the nearly field-independent local to itinerant crossover in pressure tuned and Co-and Ir-doped YbRh 2 Si 2 [45,46]. Moreover, a dynamical electronic heterogeneity at a QCP accessed by an applied magnetic field was also revealed by NMR studies even in pure YbRh 2 Si 2 [47].…”

mentioning

confidence: 99%

Microscopic investigation of electronic inhomogeneity induced by substitutions in a quantum critical metalCeCoIn5

et al. 2015

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“…The origin of the T Ã ðHÞ line is not clear at present. Recent experiments on YRS under pressure (12) or YRS doped with Co or Ir (13) have shown that while the critical field for the magnetic transition is found to shift, the T Ã line stays unchanged. This suggests that the T Ã feature is only weakly or not at all tied to the AFM transition.…”

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Critical quasiparticle theory applied to heavy fermion metals near an antiferromagnetic quantum phase transition

Abrahams

Wölfle²

2012

Proc. Natl. Acad. Sci. U.S.A.

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We use the recently developed critical quasiparticle theory to derive the scaling behavior associated with a quantum critical point in a correlated metal. This is applied to the magnetic-field induced quantum critical point observed in YbRh 2 Si 2 , for which we also derive the critical behavior of the specific heat, resistivity, thermopower, magnetization and susceptibility, the Grüneisen coefficient, and the thermal expansion coefficient. The theory accounts very well for the available experimental results.dynamical scaling | non-Fermi-liquid properties | spin excitation spectrum | non-Gaussian fluctuations R ecent advances in low-temperature experimental techniques have stimulated much interest in quantum critical phenomena, which comprise phase transitions at zero temperature ("quantum critical point") and associated effects due to quantum fluctuations at very low temperatures. Ref. 1 gives an introductory review of the subject.These developments have generated a variety of difficult theoretical questions; among them is the issue of how to treat the regime of strongly interacting quantum fluctuations. In a recent paper (2), we developed an extension of the quasiparticle concept of Fermi liquid theory to the non-Fermi-liquid regime near a quantum critical point (QCP). In essence, the theory goes beyond the Gaussian regime of critical fluctuations by introducing interactions among the quantum fluctuations into the correlation function of the fluctuations. Central to the analysis is the concept of critical quasiparticles, which is based on the recognition that the single-particle spectral function can display a quasiparticle peak at nonzero excitation energy or temperature. This is expressed as a nonzero quasiparticle weight ZðωÞ for jωj not too small, although, as in a non-Fermi liquid, at the Fermi surface Zðω ¼ 0Þ ¼ 0.We realized the critical quasiparticle theory for the case of an antiferromagnetic quantum critical point and applied it to several quantities, principally resistivity and specific heat, for successful comparison to experimental results on the heavy-fermion metal YbRh 2 Si 2 (YRS), thereby showing that the theory, which describes a physically transparent scenario, is capable of accounting for experimental results on a quantum critical metal.The implementation of the theory for an antiferromagnetic (AFM) quantum critical point for a heavy-fermion compound is based on the recognition that below a "lattice Kondo temperature" T KL , hybridization between conduction (s, p, d) electrons and local magnetic moments (f orbitals) produces a heavyelectron liquid with an associated mass enhancement due to the originally localized character of the f electrons. However, the f electrons are also responsible for the antiferromagnetism in a region of the phase diagram of the material. Near the AFM critical point, critical spin fluctuations are enhanced and interact with the heavy quasiparticles. This produces further mass enhancement and occurs in two stages. Above a certain temperature T x but below T KL , the...

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Separation of Energy Scales in Undoped YbRh₂Si₂Under Hydrostatic Pressure

Cited by 38 publications

References 43 publications

Break Up of Heavy Fermions at an Antiferromagnetic Instability

Break Up of Heavy Fermions at an Antiferromagnetic Instability

Microscopic investigation of electronic inhomogeneity induced by substitutions in a quantum critical metalCeCoIn5

Critical quasiparticle theory applied to heavy fermion metals near an antiferromagnetic quantum phase transition

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Separation of Energy Scales in Undoped YbRh2Si2Under Hydrostatic Pressure

Cited by 38 publications

References 43 publications

Break Up of Heavy Fermions at an Antiferromagnetic Instability

Break Up of Heavy Fermions at an Antiferromagnetic Instability

Microscopic investigation of electronic inhomogeneity induced by substitutions in a quantum critical metalCeCoIn5

Critical quasiparticle theory applied to heavy fermion metals near an antiferromagnetic quantum phase transition

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Separation of Energy Scales in Undoped YbRh₂Si₂Under Hydrostatic Pressure