Resistivity saturation in Kondo insulators

Pickem, Matthias; Maggio, Emanuele; Tomczak, Jan M.

doi:10.1038/s42005-021-00723-z

Cited by 19 publications

(39 citation statements)

References 65 publications

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“…In this scenario, possible impurity states influence transport solely by limiting the lifetime of intrinsic carriers through scattering, not by providing additional carriers. Our findings establish a new phenomenology for transport properties in semiconductors: Below a temperature T * ρ , ρ saturates [22] instead of growing exponentially (see the Boltzmann result (dashed line) in Fig. 1).…”

Section: Introductionsupporting

confidence: 67%

“…This residual conductivity is at the heart of the resistivity saturation in (non-topological) Kondo insulators and has been discussed in detail in Ref. 22. Similarly, the Hall conductivity in Eq.…”

Section: A Low-temperature Expansionmentioning

confidence: 71%

“…Charge transport. One of the main observations is that in the zero temperature limit T → 0 the electrical (σ) [22] and Hall conductivity (σ B ) remain finite in the presence of residual scattering (Γ > 0). In Eqs.…”

Section: A Low-temperature Expansionmentioning

confidence: 99%

“…Here, our theory provides a complementary microscopic origin for the appearance of the chemical potential-driven characteristic temperature scales T µ ν and T µ ∆ . Note that for particle-hole symmetric systems, where the chemical potential is temperature independent, no such crossover exists and there is only one activation-like regime [22].…”

Section: Electric Resistivitymentioning

confidence: 99%

“…1. For instance, other marcasite compounds (FeAs 2 , RuSb 2 [17,[23][24][25], CrSb 2 [26]), silicides (FeSi [27][28][29], RuSi [30][31][32]), Heusler systems (e.g., Fe 2 VAl [33][34][35][36][37]), other intermetallic compounds [38] (e.g., FeGa 3 , RuGa 3 [18,39,40]), as well as Kondo insulators (e.g., Ce 3 Bi 4 Pt 3 [22,[41][42][43][44][45][46])-strongly suggesting that our scenario based on carriers with finite lifetimes is prototypical for a wide array of different systems.…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Prototypical many-body signatures in transport properties of semiconductors

Pickem,

Maggio,

Tomczak

2021

Preprint

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We devise a methodology for charge, heat, and entropy transport driven by carriers with finite lifetimes. Combining numerical simulations with analytical expressions for low temperatures, we establish a comprehensive and thermodynamically consistent phenomenology for transport properties in semiconductors. We demonstrate that the scattering rate (inverse lifetime) is a relevant energy scale: It causes the emergence of several characteristic features in each transport observable. The theory is capable to reproduce-with only a minimal input electronic structure-the full temperature profiles measured in correlated narrow-gap semiconductors. In particular, we account for the previously elusive low-T saturation of the resistivity and the Hall coefficient, as well as the (linear) vanishing of the Seebeck and Nernst coefficient in systems, such as FeSb2, FeAs2, RuSb2 and FeGa3.

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Section: Introductionsupporting

confidence: 67%

Section: A Low-temperature Expansionmentioning

confidence: 71%

Section: A Low-temperature Expansionmentioning

confidence: 99%

Section: Electric Resistivitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Prototypical many-body signatures in transport properties of semiconductors

Pickem,

Maggio,

Tomczak

2021

Preprint

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Resistance saturation in semi-conducting polyacetylene molecular wires

Valli

Tomczak

2023

J Comput Electron

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Realizing the promises of molecular electronic devices requires an understanding of transport on the nanoscale. Here, we consider a Su-Schrieffer-Heeger model for semi-conducting trans-polyacetylene molecular wires in which we endow charge carriers with a finite lifetime. The aim of this exercise is two-fold: (i) the simplicity of the model allows an insightful numerical and analytical comparison of the Landauer and Kubo linear-response formalism; (ii) we distill the prototypical characteristics of charge transport through gapped mesoscopic systems and compare these to bulk semiconductors. We find that both techniques yield a residual differential conductance at low temperatures for contacted polyacetylene chains of arbitrary length—in line with the resistivity saturation in some correlated narrow-gap semiconductors. Quantitative agreement, however, is limited to not too long molecules. Indeed, while the Landauer transmission is suppressed exponentially with the system size, the Kubo response only decays hyperbolically. Our findings inform the choice of transport methodologies for the ab initio modelling of molecular devices.

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Pressure-induced concomitant topological and metal-insulator quantum phase transitions in Ce3Pd3Bi4

Cao

Zhu

2022

npj Quantum Mater.

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The electronic property and magnetic susceptibility of Ce3Pd3Bi4 were systemically investigated from 18 to 290 K for varying values of cell volume using dynamic mean-field theory coupled with density functional theory. By extrapolating to zero temperature, the ground state of Ce3Pd3Bi4 at ambient pressure is found to be a correlated semimetal due to insufficient hybridization. Upon applying pressure, the hybridization strength increases and a crossover to the Kondo insulator is observed at finite temperatures. The characteristic temperature signaling the formation of Kondo singlet, as well as the characteristic temperature associated with f-electron delocalization–localization change, simultaneously vanishes around a critical volume of 0.992 V0, suggesting that such metal–insulator transition is possibly associated with a quantum critical point. Finally, Wilson’s loop calculations indicate that the Kondo insulating side is topologically trivial, thus a topological transition also occurs across the quantum critical point.

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Resistivity saturation in Kondo insulators

Cited by 19 publications

References 65 publications

Prototypical many-body signatures in transport properties of semiconductors

Prototypical many-body signatures in transport properties of semiconductors

Resistance saturation in semi-conducting polyacetylene molecular wires

Pressure-induced concomitant topological and metal-insulator quantum phase transitions in Ce3Pd3Bi4

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