Two-dimensional Fermi surfaces in Kondo insulator SmB
            <sub>6</sub>

Li, G.; Xiang, Ziji; Yu, Fan; Asaba, Tomoya; Lawson, Benjamin; Cai, Pengfei; Tinsman, Colin; Berkley, Adam; Wolgast, Steven; Eo, Yun Suk; Kim, Dae Jeong; Kurdak, Çağlıyan; Allen, J. W.; Sun, Kai; Chen, Xuanhu; Wang, Yuyan; Fisk, Z.; Li, Lü

doi:10.1126/science.1250366

Cited by 321 publications

(388 citation statements)

References 48 publications

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“…A recent quantum oscillation experiment reveals a 3D bulk Fermi surface in TKI SmB 6 , instead of 2D one as expected 19, 20. Surface magnetic ordering is also detected in the latest hysteretic magnetoresistance (MR) measurement of SmB 6 crystals below 600 mK 21.…”

Section: Introductionmentioning

confidence: 62%

Magnetoresistance Anomaly in Topological Kondo Insulator SmB₆ Nanowires with Strong Surface Magnetism

Gan

et al. 2018

Advanced Science

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Topological Kondo insulators (TKIs) are a new class of topological materials in which topological surface states dominate the transport properties at low temperatures. They are also an ideal platform for studying the interplay between strong electron correlations and topological order. Here, hysteretic magnetoresistance (MR) is observed in TKI SmB6 thin nanowires at temperatures up to 8 K, revealing the strong magnetism at the surface of SmB6. It is also found that such MR anomaly exhibits an intriguing finite size effect and only appears in nanowires with diameter smaller than 58 nm. These nontrivial phenomena are discussed in terms of the latest Kondo breakdown model, which incorporates the RKKY magnetic interaction mediated by surface states with the strong electron correlation in SmB6. It would provide new insight into the nature of TKI surface states. Additionally, a non‐monotonically temperature dependent positive magnetoresistance is observed at intermediate temperatures, suggesting the possible impurity‐band conduction in SmB6, other than the surface state transport at low temperatures and the bulk‐band transport at high temperatures.

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Section: Introductionmentioning

confidence: 62%

Magnetoresistance Anomaly in Topological Kondo Insulator SmB₆ Nanowires with Strong Surface Magnetism

Gan

et al. 2018

Advanced Science

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“…As a putative strong topological insulator (TI), SmB 6 is expected to have a metallic crystal boundary protected against any source of backscattering that respects the time-reversal (TR) symmetry. Indeed, several transport [23][24][25][26][27][28] , quantum oscillation 29 and surface spectroscopy [30][31][32][33][34] experiments have directly probed this metallic boundary and generally provided evidence for its existance. At the same time, SmB 6 has been heralded as the first true TI with a fully insulating bulk 35 , unlike the original bismuth-based TIs whose bulks remain weakly conducting due to statistically unavoidable crystal defects [36][37][38] .…”

Section: Introductionmentioning

confidence: 99%

In-gap collective mode spectrum of the topological Kondo insulatorSmB6

Fuhrman

Nikolić

2014

Phys. Rev. B

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Samarium hexaboride (SmB6) is the first strongly correlated material with a recognized nontrivial band-structure topology. Its electron correlations are seen by inelastic neutron scattering as a coherent collective excitation at the energy of 14 meV. Here we calculate the spectrum of this mode using a perturbative slave boson method. Our starting point is the recently constructed Anderson model that properly captures the band-structure topology of SmB6. Most self-consistent renormalization effects are captured by a few phenomenological parameters whose values are fitted to match the calculated and experimentally measured mode spectrum in the first Brillouin zone. A simple band-structure of low-energy quasiparticles in SmB6 is also modeled through this fitting procedure, because the important renormalization effects due to Coulomb interactions are hard to calculate by ab-initio methods. Despite involving uncontrolled approximations, the slave boson calculation is capable of producing a fairly good quantitative match of the energy spectrum, and a qualitative match of the spectral weight throughout the first Brillouin zone. We find that the "fitted" band-structure required for this match indeed puts SmB6 in the class of strong topological insulators. Our analysis thus provides a detailed physical picture of how the SmB6 band topology arises from strong electron interactions, and paints the collective mode as magnetically active exciton.

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“…At low temperatures, however, bulk excitations vanishes because of the energy gap, and surface signals become dominant. The existence of the metallic surface states is now well established and observed in a number of experiments [18][19][20][21][22][23][24][25][26][27][28][29][30][31].Although electric transport measurements so far show that the bulk of SmB 6 has no gapless charge carriers (namely a finite charge-gap), there exist other experiments suggesting possible gapless excitations in the bulk. Especially, the recent quantum oscillation measurement claims multiple Fermi seas in the bulk of an insulating SmB 6 sample [20], in direct contradiction with transport measurements.…”

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confidence: 99%

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

Cui

Dong

et al. 2016

Phys. Rev. Lett.

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Recently there have been increasingly hot debates on whether a bulk Fermi surface of chargeneutral excitations exists in the topological Kondo insulator SmB6. To unambiguously resolve this issue, we performed the low-temperature thermal conductivity measurements of a high-quality SmB6 single crystal down to 0.1 K and up to 14.5 T. Our experiments show that the residual linear term of thermal conductivity at zero field is zero, within the experimental accuracy. Furthermore, the thermal conductivity is insensitive to magnetic field up to 14.5 T. These results exclude the existence of fermionic charge-neutral excitations in bulk SmB6, such as scalar Majorana fermions or spinons, thus put a strong constraint on the explanation of the quantum oscillations observed in SmB6.Topological insulator is a novel quantum state of matter, and has been suggested theoretically and observed experimentally [1][2][3][4][5]. Like the edge channel found in the quantum Hall system, the strong spin-orbit coupling in a three dimensional topological insulator leads to a nontrivial and robust conducting surface state. This metallic state is protected by the time-reversal symmetry. Studies on topological insulators have later stimulated the search for many other topological materials, such as topological crystalline insulators, Weyl and Dirac semimetals, and topological Kondo insulator [6][7][8][9]. Especially, interaction effect could play an important role in topological Kondo insulators and render exotic physics in them.As one of the most historical heavy-fermion (HF) materials, SmB 6 has been studied for more than 50 years [10,11] and was recently shown to be a topological Kondo insulator [12]. For decades, the low-temperature conductivity in SmB 6 remains puzzling: its resistivity shows insulating behavior down to a few Kelvins but saturates down to the lowest temperature upon further reducing the temperature. This puzzle was successfully resolved by recent transport experiments, which show that the material is a bulk insulator but with a metallic surface [13,14], consistent with the theoretical prediction that SmB 6 is a topological Kondo insulator [9,[15][16][17]. At high temperatures, transport properties are dominated by thermal excitations in the insulating bulk, and thus insulating behaviors are observed. At low temperatures, however, bulk excitations vanishes because of the energy gap, and surface signals become dominant. The existence of the metallic surface states is now well established and observed in a number of experiments [18][19][20][21][22][23][24][25][26][27][28][29][30][31].Although electric transport measurements so far show that the bulk of SmB 6 has no gapless charge carriers (namely a finite charge-gap), there exist other experiments suggesting possible gapless excitations in the bulk. Especially, the recent quantum oscillation measurement claims multiple Fermi seas in the bulk of an insulating SmB 6 sample [20], in direct contradiction with transport measurements. As the electrical transport only measures the ch...

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Two-dimensional Fermi surfaces in Kondo insulator SmB ₆

Cited by 321 publications

References 48 publications

Magnetoresistance Anomaly in Topological Kondo Insulator SmB₆ Nanowires with Strong Surface Magnetism

Magnetoresistance Anomaly in Topological Kondo Insulator SmB₆ Nanowires with Strong Surface Magnetism

In-gap collective mode spectrum of the topological Kondo insulatorSmB6

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

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Two-dimensional Fermi surfaces in Kondo insulator SmB 6

Cited by 321 publications

References 48 publications

Magnetoresistance Anomaly in Topological Kondo Insulator SmB6 Nanowires with Strong Surface Magnetism

Magnetoresistance Anomaly in Topological Kondo Insulator SmB6 Nanowires with Strong Surface Magnetism

In-gap collective mode spectrum of the topological Kondo insulatorSmB6

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

Contact Info

Product

Resources

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Two-dimensional Fermi surfaces in Kondo insulator SmB ₆

Magnetoresistance Anomaly in Topological Kondo Insulator SmB₆ Nanowires with Strong Surface Magnetism

Magnetoresistance Anomaly in Topological Kondo Insulator SmB₆ Nanowires with Strong Surface Magnetism