Bulk Fermi Surface of Charge-Neutral Excitations in<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:mrow><mml:msub><mml:mrow><mml:mi>SmB</mml:mi></mml:mrow><mml:mrow><mml:mn>6</mml:mn></mml:mrow></mml:msub></mml:mrow></mml:math>or Not: A Heat-Transport Study

Xu, Yang; Cui, S. T.; Dong, J. K.; Zhao, Dan; Wu, Tingjun; Chen, X. H.; Sun, Kai; Yao, Hong; Li, S. Y.

doi:10.1103/physrevlett.116.246403

Cited by 38 publications

(37 citation statements)

References 48 publications

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“…In other words, as the bulk resistivity diverges as T → 0, the Lorentz number for the heat carrying quasiparticles also diverges. Thus the thermal conductivity and heat capacity data very strongly suggest the presence of highly mobile and gapless neutral fermion excitations in zero field, which are not observed in SmB 6 .…”

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confidence: 89%

“…At zero field, despite ρ xx being far larger than that of conventional metals, a sizable linear temperature dependent term in the thermal conductivity is clearly resolved in the zero-temperature limit (κ xx /T (T → 0) = κ 0 xx /T = 0), analogous to normal metallic behaviour. Such a residual κ 0 xx /T term at zero field, which is absent in SmB 6 [3,6,7], leads to a spectacular violation of the Wiedemann-Franz law: the Lorenz ratio L = κ xx ρ xx /T is 10 4 -10 5 times larger than that expected in conventional metals. These data indicate that YbB 12 is a charge insulator but a thermal metal, suggesting the presence of itinerant neutral fermions.…”

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confidence: 92%

“…In SmB 6 , although a finite linear heat-capacity coefficient γ is observed [2], there is no term in the zero-field thermal conductivity that is linear in T (i.e. κ 0 xx /T = 0) [3,6,7]. This suggests that itinerant gapless neutral fermions are absent in zero field.…”

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confidence: 99%

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Unconventional thermal metallic state of charge-neutral fermions in an insulator

et al. 2019

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Quantum oscillations (QOs) in transport and thermodynamic parameters at high magnetic fields are an unambiguous signature of the Fermi surface, the defining characteristic of a metal. Therefore, recent observations of QOs in insulating SmB 6 [1-4] and YbB 12 , in particular the QOs of the resistivity ρ xx in YbB 12 [5], have been a big surprise, pointing to the formation of a novel state of quantum matter. Despite the large charge gap inferred from the insulating behaviour of ρ xx , these compounds seemingly host a Fermi surface at high magnetic fields. However, the nature of the ground state in zero field has been little explored. Here we report the use of low-temperature heat-transport measurements to discover gapless, itinerant, charge-neutral excitations in the ground state of YbB 12 . At zero field, despite ρ xx being far larger than that of conventional metals, a sizable linear temperature dependent term in the thermal conductivity is clearly resolved in the zero-temperature limit (κ xx /T (T → 0) = κ 0 xx /T = 0), analogous to normal metallic behaviour. Such a residual κ 0 xx /T term at zero field, which is absent in SmB 6 [3, 6, 7], leads to a spectacular violation of the Wiedemann-Franz law: the Lorenz ratio L = κ xx ρ xx /T is 10 4 -10 5 times larger than that expected in conventional metals. These data indicate that YbB 12 is a charge insulator but a thermal metal, suggesting the presence of itinerant neutral fermions. Remarkably, more insulating crystals with larger activation energies exhibit a larger amplitude of the resistive QOs as well as a larger κ 0 xx /T , in stark contrast to conventional metals. Moreover, we find that these fermions couple to magnetic field, despite their charge neutrality. Our findings expose novel gapless and highly itinerant, charge-neutral quasiparticles in this unconventional quantum state.In intermetallic 4f and 5f compounds, strong hybridization between itinerant and predominately localized electrons often opens an insulating gap [8,9]. Among

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Unconventional thermal metallic state of charge-neutral fermions in an insulator

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“…[1,2] In some mixed-valence compounds, however, electron-electron interactions lead to the opening of a charge gap at low temperature, resulting in an insulating state which can be called a mixed-valence insulator (MVI). The nature of this insulating state has attracted much attention in recent years, following a proposal that some MVIs could host an interaction-induced three-dimensional topological insulator state [3][4][5], and the subsequent experimental observation of quantum oscillations coexisting with the insulating state in the MVIs SmB 6 [6,7] and YbB 12 [8,9].…”

Section: Introductionmentioning

confidence: 99%

Properties of the donor impurity band in mixed valence insulators

Skinner

2019

Phys. Rev. Materials

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In traditional semiconductors with large effective Bohr radius, an electron donor creates a hydrogen-like bound state just below the conduction band edge. The properties of the impurity band arising from such hydrogenic impurities have been studied extensively during the last 70 years. In this paper we consider whether a similar bound state and a similar impurity band can exist in mixed-valence insulators, where the gap arises at low temperature due to strong electron-electron interactions. We find that the structure of the hybridized conduction band leads to an unusual bound state that can be described using the physics of the one-dimensional hydrogen atom. The properties of the resulting impurity band are also modified in a number of ways relative to the traditional semiconductor case; most notably, the impurity band can hold a much larger concentration without inducing an insulator-to-metal transition. We estimate the critical doping associated with this transition, and then proceed to calculate the dc and ac conductivities and the specific heat. We discuss our results in light of recent measurements on the mixed-valence insulator SmB 6 , and find them to be consistent with the experiments.

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“…This report has of course aroused great interest and also raises a question as to how it relates to the earlier dHvA study [47] that reported two-dimensional surface states. Each of two recently published papers [98,99] offer both theoretical and experimental perspectives on this new and very different possibility for exciting physics in SmB 6 .…”

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confidence: 99%

Foreward for special issue of philosophical magazine on: topological correlated insulators and SmB₆

Allen

2016

Philosophical Magazine

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This Foreward briefly surveys the recent burst of research on the mixed valent insulator SmB 6 in the context of two questions, (1) is SmB 6 in fact the first example of a strongly correlated topological insulator, and (2) if so are there unique features of special interest for both topology and strong correlations? Accordingly, the papers of this special issue are situated within this general rubric.

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Bulk Fermi Surface of Charge-Neutral Excitations inSmB6or Not: A Heat-Transport Study

Cited by 38 publications

References 48 publications

Unconventional thermal metallic state of charge-neutral fermions in an insulator

Unconventional thermal metallic state of charge-neutral fermions in an insulator

Properties of the donor impurity band in mixed valence insulators

Foreward for special issue of philosophical magazine on: topological correlated insulators and SmB₆

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Bulk Fermi Surface of Charge-Neutral Excitations inSmB6or Not: A Heat-Transport Study

Cited by 38 publications

References 48 publications

Unconventional thermal metallic state of charge-neutral fermions in an insulator

Unconventional thermal metallic state of charge-neutral fermions in an insulator

Properties of the donor impurity band in mixed valence insulators

Foreward for special issue of philosophical magazine on: topological correlated insulators and SmB6

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Product

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Foreward for special issue of philosophical magazine on: topological correlated insulators and SmB₆