Your search keyword '"Paschen, Silke"' showing total 294 results

1. Fully nonequilibrium Hall response from Berry curvature

Author

Sur, Shouvik, Chen, Lei, Wang, Yiming, Setty, Chandan, Paschen, Silke, and Si, Qimiao

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

In topological materials, Berry curvature leads to intrinsic Hall responses. Focusing on time-reversal symmetric systems with broken inversion symmetry, a spontaneoous (zero magnetic field) Hall effect is expected to develop under an applied electric field. Motivated by recent developments in Weyl-Kondo semimetals, here we advance a fully nonequilibrium (FNE) Hall response due to the Berry curvature. In particular, we show that, while the spontaneous Hall current is quadratic in the previously described regime of weak electric field, due to the contribution from the dipole moment of the Berry curvature, the FNE Hall response for non-perturbative electric fields is not controlled by the Berry curvature dipole. Remarkably, the FNE Hall response resembles what happens in systems that break the microscopic time-reversal symmetry. We illustrate the universality of these results by comparing them with their counterparts in systems with any higher-multipole of the Berry curvature. The implications of our results for the understanding of strongly correlated topological semimetals are discussed., Comment: 6 + 8 pages, 3 + 4 figures. v2) fixed equation numbering in the appendix; some clarifications added to main text

Published

2024

2. Quantum Fisher information in a strange metal

Author

Mazza, Federico, Biswas, Sounak, Yan, Xinlin, Prokofiev, Andrey, Steffens, Paul, Si, Qimiao, Assaad, Fakher F., and Paschen, Silke

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

A strange metal is an exotic state of correlated quantum matter; intensive efforts are ongoing to decipher its nature. Here we explore whether the quantum Fisher information (QFI), a concept from quantum metrology, can provide new insight. We use inelastic neutron scattering and quantum Monte Carlo simulations to study a Kondo destruction quantum critical point, where strange metallicity is associated with fluctuations beyond a Landau order parameter. We find that the QFI probed away from magnetic Bragg peaks, where the effect of magnetic ordering is minimized, increases strongly and without a characteristic scale as the strange metal forms with decreasing temperature, evidencing its unusual entanglement properties. Our work opens a new direction for studies across strange metal platforms., Comment: 17 pages, 4 figures

Published

2024

3. Magnetic Weyl-Kondo semimetals induced by quantum fluctuations

Author

Fang, Yuan, Chen, Lei, Prokofiev, Andrey, Robredo, Iñigo, Cano, Jennifer, Vergniory, Maia G., Paschen, Silke, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Weyl-Kondo semimetals are strongly correlated topological semimetals that develop through the cooperation of the Kondo effect with space group symmetries. The Kondo effect, capturing quantum fluctuations associated with strong correlations, is usually suppressed by magnetic order. Here we develop the theory of magnetic Weyl-Kondo semimetal. The key of the proposed mechanism is that the magnetic order comes from conduction $d$ electrons, such that the local $f$ moments can still fluctuate. We illustrate the extreme case where the magnetic space group symmetries prevent any spontaneous magnetization on the sites with the $f$-orbitals. In this case, topological degeneracies, including hourglass Weyl-Kondo nodal lines, appear when the magnetic space group symmetry constrains the Kondo-driven low-energy excitations; they lead to a third-order nonlinear anomalous Hall response. Based on the proposed mechanism, we explore the interplay between strong correlations and symmetries with database search leading to several candidate materials. The most prominent candidates are antiferromagnetic $\rm UNiGa$ and $\rm UNiAl$, with a third-order anomalous Hall response, as well as ferromagnetic $\rm USbTe$ and $\rm CeCoPO$, with a first-order one. Our findings pave the way for future experimental and theoretical investigations that promise to further advance the overarching theme of strongly correlated topology., Comment: 22 pages, 20 figures

Published

2024

4. Amplified multipartite entanglement witnessed in a quantum critical metal

Author

Fang, Yuan, Mahankali, Mounica, Wang, Yiming, Chen, Lei, Hu, Haoyu, Paschen, Silke, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Strong correlations in matter promote a landscape of quantum phases and associated quantum critical points. For metallic systems, there is increasing recognition that the quantum criticality goes beyond the Landau framework and, thus, novel means are needed to characterize the quantum critical fluid. Here we do so by studying an entanglement quantity, the quantum Fisher information, in a strange metal system, focusing on the exemplary case of an Anderson/Kondo lattice model near its Kondo destruction quantum critical point. The spin quantum Fisher information peaks at the quantum critical point and indicates a strongly entangled ground state. Our results are supported by the quantum Fisher information extracted from inelastic neutron scattering measurements in heavy fermion metals. Our work elucidates the loss of quasiparticles in strange metals, opens a quantum information avenue to advance the understanding of metallic quantum criticality in a broad range of strongly correlated systems, and points to a novel regime of quantum matter to realize amplified entanglement., Comment: 34 pages, 8 figures

Published

2024

5. Flat bands, strange metals and the Kondo effect

Author

Checkelsky, Joseph G., Bernevig, B. Andrei, Coleman, Piers, Si, Qimiao, and Paschen, Silke

Published

2024

6. Flat bands, strange metals, and the Kondo effect

Author

Checkelsky, Joseph G., Bernevig, B. Andrei, Coleman, Piers, Si, Qimiao, and Paschen, Silke

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Flat band materials such as the kagome metals or moir\'e superlattice systems are of intense current interest. Flat bands can result from the electron motion on numerous (special) lattices and usually exhibit topological properties. Their reduced bandwidth proportionally enhances the effect of Coulomb interaction, even when the absolute magnitude of the latter is relatively small. Seemingly unrelated to these cases is the large family of strongly correlated electron systems, which includes the heavy fermion compounds, cuprate and pnictide superconductors. In addition to itinerant electrons from large, strongly overlapping orbitals, they frequently contain electrons from more localized orbitals, which are subject to a large Coulomb interaction. The question then arises as to what commonality in the physical properties and microscopic physics, if any, exists between the two broad categories of materials? A rapidly increasing body of strikingly similar phenomena across the different platforms -- from electronic localization-delocalization transitions to strange metal behavior and unconventional superconductivity -- suggests that similar underlying principles could be at play. Indeed, it has recently been suggested that flat band physics can be understood in terms of Kondo physics. Inversely, the concept of electronic topology from lattice symmetry, which is fundamental in flat band systems, is enriching the field of strongly correlated electron systems where correlation-driven topological phases are increasingly being investigated. Here we elucidate this connection, survey the new opportunities for cross-fertilization in understanding across the platforms, and assess the prospect for new insights that may be gained into both the correlation physics and its intersection with electronic topology., Comment: 35 pages, 6 figures, perspective paper

Published

2023

7. Topological Diagnosis of Strongly Correlated Electron Systems

Author

Setty, Chandan, Xie, Fang, Sur, Shouvik, Chen, Lei, Paschen, Silke, Vergniory, Maia G., Cano, Jennifer, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

The intersection of electronic topology and strong correlations offers a rich platform to discover exotic quantum phases of matter and unusual materials. An overarching challenge that impedes the discovery is how to diagnose strongly correlated electronic topology. Here, we develop a framework to address this outstanding question, and illustrate its power in the setting of electronic topology in Mott insulators. Based on single-particle Green's functions, the concept of a Green's function Berry curvature -- which is frequency dependent -- is introduced. We apply this notion in a system that contains symmetry-protected nodes in its noninteracting bandstructure; strong correlations drive the system into a Mott insulating state, creating contours in frequency-momentum space where the Green's function vanishes. The Green's function Berry flux of such zeros is found to be quantized, and is as such direct probe of the system's topology. Our framework allows for a systematic search of strongly correlated topological materials with Green's function topology., Comment: 38 pages, 13 figures including Supplemental Information

Published

2023

8. Emergent flat band and topological Kondo semimetal driven by orbital-selective correlations

Author

Chen, Lei, Xie, Fang, Sur, Shouvik, Hu, Haoyu, Paschen, Silke, Cano, Jennifer, and Si, Qimiao

Published

2024

9. How to identify and characterize strongly correlated topological semimetals

Author

Kirschbaum, Diana M., Lužnik, Monika, Roy, Gwenvredig Le, and Paschen, Silke

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

How strong correlations and topology interplay is a topic of great current interest. In this perspective paper, we focus on correlation-driven gapless phases. We take the time-reversal symmetric Weyl semimetal as an example because it is expected to have clear (albeit nonquantized) topological signatures in the Hall response and because the first strongly correlated representative, the noncentrosymmetric Weyl-Kondo semimetal Ce$_3$Bi$_4$Pd$_3$, has recently been discovered. We summarize its key characteristics and use them to construct a prototype Weyl-Kondo semimetal temperature-magnetic field phase diagram. This allows for a substantiated assessment of other Weyl-Kondo semimetal candidate materials. We also put forward scaling plots of the intrinsic Berry-curvature-induced Hall response vs the inverse Weyl velocity -- a measure of correlation strength, and vs the inverse charge carrier concentration -- a measure of the proximity of Weyl nodes to the Fermi level. They suggest that the topological Hall response is maximized by strong correlations and small carrier concentrations. We hope that our work will guide the search for new Weyl-Kondo semimetals and correlated topological semimetals in general, and also trigger new theoretical work., Comment: 22 pages, 5 figures, 2 tables

Published

2023

10. Metallic quantum criticality enabled by flat bands in a kagome lattice

Author

Chen, Lei, Xie, Fang, Sur, Shouvik, Hu, Haoyu, Paschen, Silke, Cano, Jennifer, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Condensed Matter - Superconductivity

Abstract

Strange metals arise in a variety of platforms for strongly correlated electrons, ranging from the cuprates, heavy fermions to flat band systems. Motivated by recent experiments in kagome metals, we study a Hubbard model on a kagome lattice whose noninteracting limit contains flat bands. A Kondo lattice description is constructed, in which the degrees of freedom are exponentially localized molecular orbitals. We identify an orbital-selective Mott transition through an extended dynamical mean field theory of the effective model. The transition describes a quantum critical point at which quasiparticles are lost and strange metallicity emerges. Our theoretical work opens up a new route for realizing beyond-Landau quantum criticality and emergent quantum phases that it nucleates., Comment: 38 pages, 11 figures

Published

2023

11. Dark Matter Detection with Strongly Correlated Topological Materials: Flatband Effect

Author

Huang, Zhao, Lane, Christopher, Grefe, Sarah E., Nandy, Snehasish, Fauseweh, Benedikt, Paschen, Silke, Si, Qimiao, and Zhu, Jian-Xin

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, High Energy Physics - Theory

Abstract

Dirac materials have been proposed as a new class of electron-based detectors for light dark-matter (DM) scattering or absorption, with predicted sensitivities far exceeding superconductors and superfluid helium. The superiority of Dirac materials originates from a significantly reduced in-medium dielectric response winning over the suppression of DM scattering owing to the limited phase space at the point-like Fermi surface. Here we propose a new route to enhance significantly the DM detection efficiency via strongly correlated topological semimetals. Specifically, by considering a strongly correlated Weyl semimetal model system, we demonstrate that the strong correlation-induced flatband effects can amplify the coupling and detection sensitivity to light DM particles by expanding the scattering phase space, while maintaining a weak dielectric in-medium response., Comment: 5+ pages, 4 embedded figures, and supplemental material

Published

2023

12. Size effect on the thermal conductivity of a type-I clathrate

Author

Lužnik, Monika, Lientschnig, Günther, Taupin, Mathieu, Steiger-Thirsfeld, Andreas, Prokofiev, Andrey, and Paschen, Silke

Subjects

Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Clathrates are a materials class with an extremely low phonon thermal conductivity, which is a key ingredient for a high thermoelectric conversion efficiency. Here, we present a study on the type-I clathrate La$_{1.2}$Ba$_{6.8}$Au$_{5.8}$Si$_{38.8}\square_{1.4}$ directed at lowering the phonon thermal conductivity even further by forming mesoscopic wires out of it. Our hypothesis is that the interaction of the low-energy rattling modes of the guest atoms (La and Ba) with the acoustic modes, which originate mainly from the type-I clathrate framework (formed by Au and Si atoms, with some vacancies $\square$), cuts off their dispersion and thereby tilts the balance of phonons relevant for thermal transport to long-wavelength ones. Thus, size effects are expected to set in at relatively long length scales. The structuring was carried out using a top-down approach, where the wires, ranging from 1260 nm to 630 nm in diameter, were cut from a piece of single crystal using a focused ion beam technique. Measurements of the thermal conductivity were performed with a self-heating $3\omega$ technique down to 80 K. Indeed, they reveal a reduction of the room-temperature phonon thermal conductivity by a sizable fraction of $\sim$40 % for our thinnest wire, thereby confirming our hypothesis.

Published

2023

13. Symmetry constraints and spectral crossing in a Mott insulator with Green's function zeros

Author

Setty, Chandan, Sur, Shouvik, Chen, Lei, Xie, Fang, Hu, Haoyu, Paschen, Silke, Cano, Jennifer, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Lattice symmetries are central to the characterization of electronic topology. Recently, it was shown that Green's function eigenvectors form a representation of the space group. This formulation has allowed the identification of gapless topological states even when quasiparticles are absent. Here we demonstrate the profundity of the framework in the extreme case, when interactions lead to a Mott insulator, through a solvable model with long-range interactions. We find that both Mott poles and zeros are subject to the symmetry constraints, and relate the symmetry-enforced spectral crossings to degeneracies of the original non-interacting eigenstates. Our results lead to new understandings of topological quantum materials and highlight the utility of interacting Green's functions toward their symmetry-based design., Comment: To appear in PRR Letter. 7 pages, 2 figures + Supplemental Material

Published

2023

14. Emergent flat band and topological Kondo semimetal driven by orbital-selective correlations

Author

Chen, Lei, Xie, Fang, Sur, Shouvik, Hu, Haoyu, Paschen, Silke, Cano, Jennifer, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Flat electronic bands are expected to show proportionally enhanced electron correlations, which may generate a plethora of novel quantum phases and unusual low-energy excitations. They are increasingly being pursued in $d$-electron-based systems with crystalline lattices that feature destructive electronic interference, where they are often topological. Such flat bands, though, are generically located far away from the Fermi energy, which limits their capacity to partake in the low-energy physics. Here we show that electron correlations produce emergent flat bands that are pinned to the Fermi energy. We demonstrate this effect within a Hubbard model, in the regime described by Wannier orbitals where an effective Kondo description arises through orbital-selective Mott correlations. Moreover, the correlation effect cooperates with symmetry constraints to produce a topological Kondo semimetal. Our results motivate a novel design principle for Weyl Kondo semimetals in a new setting, viz. $d$-electron-based materials on suitable crystal lattices, and uncover interconnections among seemingly disparate systems that may inspire fresh understandings and realizations of correlated topological effects in quantum materials and beyond., Comment: To appear in Nature Communications; submitted version of the manuscript; 33 pages, 4 figures main text + 7 figures supplementary information

Published

2022

15. Shot noise and universal Fano factor as characterization of strongly correlated metals

Author

Wang, Yiming, Setty, Chandan, Sur, Shouvik, Chen, Liyang, Paschen, Silke, Natelson, Douglas, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Shot noise measures out-of-equilibrium current fluctuations and is a powerful tool to probe the nature of current-carrying excitations in quantum systems. Recent shot noise measurements in the heavy fermion strange metal YbRh$_2$Si$_2$ exhibit a strong suppression of the Fano factor ($F$) -- the ratio of the current noise to the average current in the DC limit. This system is representative of metals in which electron correlations are extremely strong. Here we carry out the first theoretical study on the shot noise of diffusive metals in the regime of strong correlations. A Boltzmann-Langevin equation formulation is constructed in a quasiparticle description in the presence of strong correlations. We find that $F = \sqrt{ 3}/{4}$ in such a correlation regime. Thus, we establish the aforementioned Fano factor as universal to Fermi liquids, and show that the Fano factor suppression observed in experiments on YbRh$_2$Si$_2$ necessitates a loss of the quasiparticles. Our work opens the door to systematic theoretical studies of shot noise as a means of characterizing strongly correlated metallic phases and materials., Comment: To appear in Phys. Rev. Research as a Letter, 5+5 pages, 2+1 figures

Published

2022

16. Shot noise in a strange metal

Author

Chen, Liyang, Lowder, Dale T., Bakali, Emine, Andrews, Aaron Maxwell, Schrenk, Werner, Waas, Monika, Svagera, Robert, Eguchi, Gaku, Prochaska, Lukas, Wang, Yiming, Setty, Chandan, Sur, Shouvik, Si, Qimiao, Paschen, Silke, and Natelson, Douglas

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Strange-metal behavior has been observed in materials ranging from high-temperature superconductors to heavy fermion metals. In conventional metals, current is carried by quasiparticles; although it has been suggested that quasiparticles are absent in strange metals, direct experimental evidence is lacking. We measured shot noise to probe the granularity of the current-carrying excitations in nanowires of the heavy fermion strange metal YbRh2Si2. When compared with conventional metals, shot noise in these nanowires is strongly suppressed. This suppression cannot be attributed to either electron-phonon or electron-electron interactions in a Fermi liquid, which suggests that the current is not carried by well-defined quasiparticles in the strange-metal regime that we probed. Our work sets the stage for similar studies of other strange metals., Comment: 22 pages, 4 figures; 21 pages supplementary text, 11 supplementary figures

Published

2022

17. Is the optical conductivity of heavy fermion strange metals Planckian?

Author

Li, Xinwei, Kono, Junichiro, Si, Qimiao, and Paschen, Silke

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Strange metal behavior appears across a variety of condensed matter settings and beyond, and achieving a universal understanding is an exciting prospect. The beyond-Landau quantum criticality of Kondo destruction has had considerable success in describing the behavior of strange metal heavy fermion compounds, and there is some evidence that the associated partial localization-delocalization nature can be generalized to diverse materials classes. Other potential overarching principles at play are also being explored. An intriguing proposal is that Planckian scattering, with a rate of $k_{\rm B}T/\hbar$, leads to the linear temperature dependence of the (dc) electrical resistivity, which is a hallmark of strange metal behavior. Here we extend a previously introduced analysis scheme based on the Drude description of the dc resistivity to optical conductivity data. When they are well described by a simple (ac) Drude model, the scattering rate can be directly extracted. This avoids the need to determine the ratio of charge carrier concentration to effective mass, which has complicated previous analyses based on the dc resistivity. However, we point out that strange metals typically exhibit strong deviations from Drude behavior, as exemplified by the ``extreme'' strange metal YbRh$_2$Si$_2$. This calls for alternative approaches, and we point to the power of strange metal dynamical (energy-over-temperature) scaling analyses for the inelastic part of the optical conductivity. If such scaling extends to the low-frequency limit, a strange metal relaxation rate can be estimated, and may ultimately be used to test whether strange metals relax in a Planckian manner., Comment: Perspective in the invited issue "New Heavy Fermion Superconductors", Frontiers in Electronic Materials; 21 pages, 7 figures

Published

2022

18. Are Heavy Fermion Strange Metals Planckian?

Author

Taupin, Mathieu and Paschen, Silke

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Strange metal behavior refers to a linear temperature dependence of the electrical resistivity at temperatures below the Mott-Ioffe-Regel limit. It is seen in numerous strongly correlated electron systems, from the heavy fermion compounds, via transition metal oxides and iron pnictides, to magic angle twisted bi-layer graphene, frequently in connection with unconventional or "high temperature" superconductivity. To achieve a unified understanding of these phenomena across the different materials classes is a central open problem in condensed matter physics. Tests whether the linear-in-temperature law might be dictated by Planckian dissipation - scattering with the rate $\sim k_{\rm B}T/\hbar$, are receiving considerable attention. Here we assess the situation for strange metal heavy fermion compounds. They allow to probe the regime of extreme correlation strength, with effective mass or Fermi velocity renormalizations in excess of three orders of magnitude. Adopting the same procedure as done in previous studies, i.e., assuming a simple Drude conductivity with the above scattering rate, we find that for these strongly renormalized quasiparticles, scattering is much weaker than Planckian, implying that the linear temperature dependence should be due to other effects. We discuss implications of this finding and point to directions for further work., Comment: 17 pages, 5 figures, invited perspectives paper for the special issue "New Spin on Metal-Insulator Transitions" of Crystals

Published

2022

19. The many faces (phases) of strong correlations

Author

Paschen, Silke and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

There has been considerable recent progress in discovering and understanding quantum phases and fluctuations produced by strong correlations. Heavy fermion systems are an ideal platform for systematic studies because low and competing energy scales make them highly tunable. As such the phases (faces) of strong correlations transform continuously into one another., Comment: 3 pages, 3 figures, 1 box

Published

2021

20. Topological semimetals without quasiparticles

Author

Hu, Haoyu, Chen, Lei, Setty, Chandan, Garcia-Diez, Mikel, Grefe, Sarah E., Prokofiev, Andrey, Kirchner, Stefan, Vergniory, Maia G., Paschen, Silke, Cano, Jennifer, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

The interplay between interactions and topology in quantum materials is of extensive current interest. Strong correlations are known to be important for insulating topological states, as exemplified by the fractional quantum Hall effect. For the metallic case, whether and how they can drive topological states that have no free-electron counterparts is an open and pressing question. We introduce a general framework for lattice symmetries to constrain single-particle excitations even when they are not quasiparticles, and substantiate it in a periodic Anderson model with two channels of conduction electrons. We demonstrate that symmetry constrains correlation-induced emergent excitations to produce non-Fermi liquid topological phases. The loss of quasiparticles in these phases is manifested in a non-Fermi liquid form of spectral and transport properties, whereas its topological nature is characterized by surface states and valley and spin Hall conductivities. We also identify candidate materials to realize the proposed phases. Our work opens a door to a variety of non-Fermi liquid topological phases in a broad range of strongly correlated materials., Comment: 46 pages, 3 figures main text + 11 figures supplementary information

Published

2021

21. Kondomania

Author

Kirchner, Stefan and Paschen, Silke

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Originally the Kondo effect describes a scattering mechanism of electrons in metals that have defects with internal quantum mechanical degrees of freedom. The characteristic dynamic interplay between localized and itinerant states occurs in many different forms. It is now clear that the Kondo effect shapes the properties of various classes of quantum materials and is a key to understanding their unusual properties. In the following we outline a selection of the most important developments in this Kondomania., Comment: 12 pages in preprint form, in German, 9 figures; invited contribution for publication in Physik in unserer Zeit

Published

2021

22. Topological Semimetal driven by Strong Correlations and Crystalline Symmetry

Author

Chen, Lei, Setty, Chandan, Hu, Haoyu, Vergniory, Maia G., Grefe, Sarah E., Fischer, Lukas, Yan, Xinlin, Eguchi, Gaku, Prokofiev, Andrey, Paschen, Silke, Cano, Jennifer, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Electron correlations amplify quantum fluctuations and, as such, they have been recognized as the origin of a rich landscape of quantum phases. Whether and how they lead to gapless topological states is an outstanding question, and a framework that allows for determining novel phases and identifying new materials is in pressing need. Here we advance a general approach, in which strong correlations cooperate with crystalline symmetry to drive gapless topological states. We test this materials design principle by exploring Kondo lattice models and materials whose space group symmetries may promote different kinds of electronic degeneracies, with a particular focus on square-net systems. Weyl-Kondo nodal-line semimetals -- with nodes pinned to the Fermi energy -- are identified. We describe how this approach can be applied to discover strongly correlated topological semimetals, identify three heavy fermion compounds as new candidates, provide first direct experimental evidence for our prediction in Ce$_2$Au$_3$In$_5$, and discuss how our approach may lead to many more. Our findings illustrate the potential of the proposed materials design principle to guide the search for new topological metals in a broad range of strongly correlated systems., Comment: To appear in Nature Physics; submitted version of the manuscript (the accepted version will appear in the journal); 35 pages, 4 figures main text + 8 figures supplementary information

Published

2021

23. Quantum Criticality Enabled by Intertwined Degrees of Freedom

Author

Liu, Chia-Chuan, Paschen, Silke, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Strange metals appear in a wide range of correlated materials. Electronic localization-delocalization and the expected loss of quasiparticles characterize beyond-Landau metallic quantum critical points and the associated strange metals. Typical settings involve local spins. Systems that contain entwined degrees of freedom offer new platforms to realize novel forms of quantum criticality. Here, we study the fate of an SU(4) spin-orbital Kondo state in a multipolar Bose-Fermi Kondo model, which provides an effective description of a multipolar Kondo lattice, using a renormalization-group method. We show that at zero temperature a generic trajectory in the model's parameter space contains two quantum critical points, which are associated with the destruction of Kondo entanglement in the orbital and spin channels respectively. Our asymptotically exact results reveal an overall phase diagram, provide the theoretical basis to understand puzzling recent experiments of a multipolar heavy fermion metal, and point to a means of designing new forms of quantum criticality and strange metallicity in a variety of strongly correlated systems., Comment: 43 pages, 9 figures. To appear in PNAS

Published

2021

24. Extreme topological tunability of Weyl-Kondo semimetal to Zeeman coupling

Author

Grefe, Sarah E., Lai, Hsin-Hua, Paschen, Silke, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

There is considerable interest in the intersection of correlations and topology, especially in metallic systems. Among the outstanding questions are how strong correlations drive novel topological states and whether such states can be readily controlled. Here we study the effect of a Zeeman coupling on a Weyl-Kondo semimetal in a nonsymmorphic and noncentrosymmetric Kondo-lattice model. A sequence of distinct and topologically nontrivial semimetal regimes are found, each containing Kondo-driven and Fermi-energy-bound Weyl nodes. The nodes annihilate at a magnetic field that is smaller than what it takes to suppress the Kondo effect. As such, we demonstrate an extreme topological tunability that is isolated from the tuning of the strong correlations per se. Our results are important for experiments in strongly correlated systems, and set the stage for mapping out a global phase diagram for strongly correlated topology., Comment: 6 pages, 5 figures

Published

2020

25. Quantum phases driven by strong correlations

Author

Paschen, Silke and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

It has long been thought that strongly correlated systems are adiabatically connected to their noninteracting counterpart. Recent developments have highlighted the fallacy of this traditional notion in a variety of settings. Here we use a class of strongly correlated electron systems as a platform to illustrate the kind of quantum phases and fluctuations that are created by strong correlations. Examples are quantum critical states that violate the Fermi liquid paradigm, unconventional superconductivity that goes beyond the BCS framework, and topological semimetals induced by the Kondo interaction. We assess the prospect of designing other exotic phases of matter, by utilizing alternative degrees of freedom or alternative interactions, and point to the potential of these correlated states for quantum technology., Comment: 55 pages in preprint format, 8 figures, 1 supplementary figure, 2 supplementary info boxes; 1 figure panel exchanged, text slightly amended

Published

2020

26. Anisotropic Physical Properties of the Kondo Semimetal CeCu$_{1.11}$As$_2$

Author

Cvitkovich, Lukas, Zocco, Diego A., Eguchi, Gaku, Waas, Monika, Svagera, Robert, Stöger, Berthold, Mondal, Rajib, Thamizhavel, Arumugam, and Paschen, Silke

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The recently proposed novel materials class called Weyl-Kondo semimetal (WKSM) is a time reversal invariant but inversion symmetry broken Kondo semimetal in which Weyl nodes are pushed to the Fermi level by the Kondo interaction. Here we explore whether CeCu$_{1+x}$As$_2$ may be a new WKSM candidate. We report on its single-crystal growth, structure determination and physical properties investigation. Previously published studies on polycrystalline samples suggest that it is indeed a Kondo semimetal, which is confirmed by our investigations on single crystals. X-ray diffraction reveals that CeCu$_{1+x}$As$_2$ crystallizes in a tetragonal centrosymmetric structure, although the inversion symmetry could still be broken locally due to partially occupied Cu sites. Chemical analysis results in an average occupation $x$ = 0.11(1). The electrical resistivity increases logarithmically with decreasing temperature, and saturates below 10 K. A Kondo temperature $T_{\mathrm{K}}$ $\approx$ 4 K is extracted from entropy, estimated from the specific heat measurements. From Hall effect experiments, a charge carrier density of $8.8 \times 10^{20}$ cm$^{-3}$ is extracted, a value characteristic of a semimetal. The magnetization shows pronounced anisotropy, with no evidence of magnetic ordering down to 0.4 K. We thus classify CeCu$_{1.11}$As$_2$ as a tetragonal Kondo semimetal with anisotropic magnetic properties, with a possibly broken inversion symmetry, thus fulfilling the necessary conditions for a WKSM state., Comment: 6 pages, 4 figures, Proceedings of the International Conference on Strongly Correlated Electron Systems (SCES2019)

Published

2020

27. Weyl-Kondo Semimetal: Towards Control of Weyl Nodes

Author

Grefe, Sarah E., Lai, Hsin-Hua, Paschen, Silke, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Heavy fermion semimetals represent a promising setting to explore topological metals driven by strong correlations. In this paper, we i) summarize the theoretical results in a Weyl-Kondo semimetal phase for a strongly correlated model with inversion-symmetry-breaking and time-reversal invariance, and the concurrent work that has experimentally discovered this phase in the non-magnetic non-centrosymmetric heavy fermion system Ce$_3$Bi$_4$Pd$_3$; and ii) describe what is expected theoretically when the time-reversal symmetry is also broken., Comment: 6 pages, 3 figures; published version, and with updated references

Published

2020

28. $^{105}$Pd NMR and NQR study of the cubic heavy fermion system Ce$_3$Pd$_{20}$Si$_6$

Author

Jakovac, Ivan, Horvatić, Mladen, Schwier, Eike F., Prokofiev, Andrey, Paschen, Silke, Mitamura, Hiroyuki, Sakakibara, Toshiro, and Grbić, Mihael S.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We report $^{105}$Pd NMR and NQR measurements on a single crystal of Ce$_3$Pd$_{20}$Si$_6$, where antiferroquadrupolar and antiferromagnetic orders develop at low temperature. From the analysis of NQR and NMR spectra, we have determined the electric field gradient (EFG) tensors and the anisotropic Knight shift ($K$) components for both inequivalent Pd sites - Pd($32f$) and Pd($48h$). The observed EFG values are in excellent agreement with our state-of-the-art DFT calculations. The principal values of the quadrupolar coupling are $(20.37 \pm 0.02)$ MHz and $(5.45 \pm 0.02)$ MHz, for the Pd($32f$) and Pd($48h$) site, respectively, which is large compared to the Larmor frequency defined by the gyromagnetic constant $\gamma = 1.94838$ MHz/T for $^{105}$Pd. Therefore, the complete knowledge of $K$ and the EFG tensors is crucial to establish the correspondence between NMR spectra and crystallographic sites, which is needed for a complete analysis of the magnetic structure, static spin susceptibility, and the spin-lattice relaxation rate data and a better understanding of the groundstate of Ce$_3$Pd$_{20}$Si$_6$., Comment: 7 pages; 6 figures, 2 tables; accepted for publication in Journal of Physics: Condensed Matter

Published

2019

29. Weyl-Kondo semimetals in nonsymmorphic systems

Author

Grefe, Sarah E., Lai, Hsin-Hua, Paschen, Silke, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

There is considerable current interest to explore electronic topology in strongly correlated metals, with heavy fermion systems providing a promising setting. Recently, a Weyl-Kondo semimetal phase has been concurrently discovered in theoretical and experimental studies. The theoretical work was carried out in a Kondo lattice model that is time-reversal invariant but inversion-symmetry breaking. In this paper, we show in some detail how nonsymmorphic space-group symmetry and strong correlations cooperate to form Weyl nodal excitations with highly reduced velocity and pin the resulting Weyl nodes to the Fermi energy. A tilted variation of the Weyl-Kondo solution is further analyzed here, following the recent consideration of such effect in the context of understanding a large spontaneous Hall effect in Ce$_3$Bi$_4$Pd$_3$ (Dzsaber et al., arXiv:1811.02819). We discuss the implications of our results for the enrichment of the global phase diagram of heavy fermion metals, and for the space-group symmetry enforcement of topological semimetals in other strongly correlated settings., Comment: 13 pages, 7 figures; replaced with the published version

Published

2019

30. Comment on 'Tuning low-energy scales in YbRh$_2$Si$_2$ by non-isoelectronic substitution and pressure'

Author

Wirth, Steffen, Paschen, Silke, Si, Qimiao, and Steglich, Frank

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

In Ref. 1, Schubert et al. [Phys. Rev. Research 1, 032004 (2019)] reported measurements of the isothermal magnetoresistance of Fe- and Ni-substituted YbRh$_2$Si$_2$, based on which they raised questions about the Kondo destruction description for the magnetic field-induced quantum critical point (QCP) of pristine YbRh$_2$Si$_2$. Here we make three points. Firstly, as shown by studies on pristine YbRh$_2$Si$_2$ in Paschen et al. and Friedemann et al., isothermal crossed-field and single-field Hall effect measurements are necessary to ascertain the evolution of the Fermi surface across this QCP. Because Schubert et al. did not carry out such measurements, their results on Fe- and Ni-substituted YbRh$_2$Si$_2$ cannot be used to assess the validity of the Kondo destruction picture neither for substituted nor for pristine YbRh$_2$Si$_2$. Secondly, when referring to the data of Friedemann et al. on the isothermal crossover of YbRh$_2$Si$_2$, they did not recognize the implications of the crossover width, quantified by the full width at half maximum (FWHM), being linear in temperature, with zero offset, over about $1.5$ decades in temperature, from 30 mK to 1 K. Finally, in claiming deviations of Hall crossover FWHM data of Friedemann et al. from the above linear-in-$T$ dependence they neglected the error bars of these measurements and discarded some of the data points. The claims of Schubert et al. are thus not supported by data, neither previously published nor new (Ref. 1). As such they cannot invalidate the evidence that has been reported for Kondo destruction quantum criticality in YbRh$_2$Si$_2$., Comment: 3 pages, 1 figure; comment on Schubert et al., Phys. Rev. Research 1, 032004 (2019)

Published

2019

31. Controlling electronic topology in a strongly correlated electron system

Author

Dzsaber, Sami, Zocco, Diego A., McCollam, Alix, Weickert, Franziska, McDonald, Ross, Taupin, Mathieu, Yan, Xinlin, Prokofiev, Andrey, Tang, Lucas M. K., Vlaar, Bryan, Winter, Laurel E., Jaime, Marcelo, Si, Qimiao, and Paschen, Silke

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Combining strong electron correlations [1-4] and nontrivial electronic topology [5] holds great promise for discovery. So far, this regime has been rarely accessed and systematic studies are much needed to advance the field. Here we demonstrate the control of topology in a heavy fermion system. We use magnetic field to manipulate Weyl nodes in a Weyl-Kondo semimetal [6-8], up to the point where they annihilate in a topological quantum phase transition. The suppression of the topological characteristics occurs in an intact and only weakly varying strongly correlated "background". Thus, topology is changing per se and not as a consequence of a change of the correlation state, for instance across a magnetic, electronic or structural phase transition. Our demonstration of genuine topology tuning in a strongly correlated electron system sets the stage for establishing global phase diagrams of topology, an approach that has proven highly valuable to explore and understand topologically trivial strongly correlated electron systems [1-4]. Our work also lays the ground for technological exploitations of controlled electronic topology., Comment: 4 figures, 17 pages

Published

2019

32. Dynamical Kondo effect and Kondo destruction in effective models for quantum-critical heavy fermion metals

Author

Cai, Ang, Hu, Haoyu, Ingersent, Kevin, Paschen, Silke, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Quantum criticality in certain heavy-fermion metals is believed to go beyond the Landau framework of order-parameter fluctuations. In particular, there is considerable evidence for Kondo destruction: a disappearance of the static Kondo singlet amplitude that results in a sudden reconstruction of Fermi surface across the quantum critical point and an extra critical energy scale. This effect can be analyzed in terms of a dynamical interplay between the Kondo and RKKY interactions. In the Kondo-destroyed phase, a well-defined Kondo resonance is lost, but Kondo singlet correlations remain at nonzero frequencies. This dynamical effect allows for mass enhancement in the Kondo-destroyed phase. Here, we elucidate the dynamical Kondo effect in Bose-Fermi Kondo/Anderson models, which unambiguously exhibit Kondo-destruction quantum critical points. We show that a simple physical quantity---the expectation value $\langle {\bf S}_{f} \cdot {\bf s}_{c} \rangle$ for the dot product of the local ($f$) and conduction-electron ($c$) spins---varies continuously across such quantum critical points. A nonzero $\langle {\bf S}_{f} \cdot {\bf s}_{c} \rangle$ manifests the dynamical Kondo effect that operates in the Kondo-destroyed phase. Implications are discussed for the stability of Kondo-destruction quantum criticality as well as the understanding of experimental results in quantum critical heavy-fermion metals., Comment: 10 pages, 6 figures; minor changes for more streamlined presentation, and references added

Published

2019

33. Topological semimetal driven by strong correlations and crystalline symmetry

Author

Chen, Lei, Setty, Chandan, Hu, Haoyu, Vergniory, Maia G., Grefe, Sarah E., Fischer, Lukas, Yan, Xinlin, Eguchi, Gaku, Prokofiev, Andrey, Paschen, Silke, Cano, Jennifer, and Si, Qimiao

Published

2022

34. Giant spontaneous Hall effect in a nonmagnetic Weyl-Kondo semimetal

Author

Dzsaber, Sami, Yan, Xinlin, Taupin, Mathieu, Eguchi, Gaku, Prokofiev, Andrey, Shiroka, Toni, Blaha, Peter, Rubel, Oleg, Grefe, Sarah E., Lai, Hsin-Hua, Si, Qimiao, and Paschen, Silke

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Nontrivial topology in condensed matter systems enriches quantum states of matter, to go beyond either the classification into metals and insulators in terms of conventional band theory or that of symmetry broken phases by Landau's order parameter framework. So far, focus has been on weakly interacting systems, and little is known about the limit of strong electron correlations. Heavy fermion systems are a highly versatile platform to explore this regime. Here we report the discovery of a giant spontaneous Hall effect in the Kondo semimetal Ce3Bi4Pd3 that is noncentrosymmetric but preserves time reversal symmetry. We attribute this finding to Weyl nodes - singularities of the Berry curvature - that emerge in the immediate vicinity of the Fermi level due to the Kondo interaction. We stress that this phenomenon is distinct from the previously detected anomalous Hall effect in materials with broken time reversal symmetry; instead, it manifests an extreme topological response that requires a beyond-perturbation-theory description of the previously proposed nonlinear Hall effect. The large magnitude of the effect in even tiny electric and zero magnetic fields, as well as its robust bulk nature may aid the exploitation in topological quantum devices., Comment: preprint (including supplementary information) of 29 pages, 4 main figures, 12 supplementary figures; to appear in Proc. Natl. Acad. Sci. U.S.A

Published

2018

35. Heavy-electron quantum criticality and single-particle spectroscopy

Author

Kirchner, Stefan, Paschen, Silke, Chen, Qiuyun, Wirth, Steffen, Feng, Donglai, Thompson, Joe D., and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Materials Science

Abstract

Angle-resolved photoemission spectroscopy (ARPES) and scanning tunneling microscopy (STM) have become indispensable tools in the study of correlated quantum materials. Both probe complementary aspects of the single-particle excitation spectrum. Taken together, ARPES and STM have the potential to explore properties of the electronic Green's function, a central object of many-body theory. This review explicates this potential with a focus on heavy-electron quantum criticality, especially the role of Kondo destruction. A discussion on how to probe the Kondo destruction effect across the quantum-critical point using ARPES and STM measurements is presented. Particular emphasis is placed on the question of how to distinguish between the signatures of the initial onset of hybridization-gap formation, which is the "high-energy" physics to be expected in all heavy-electron systems, and those of Kondo destruction, which characterizes the low-energy physics and, hence, the nature of quantum criticality. Recent progress and possible challenges in the experimental investigations are surveyed, the STM and ARPES spectra for several quantum-critical heavy-electron compounds are compared, and the prospects for further advances are outlined., Comment: 23 pages, 13 figures, 1 table; Colloquia section of Reviews of Modern Physics

Published

2018

36. Kondo Destruction and Multipolar Order-- Implications for Heavy Fermion Quantum Criticality

Author

Lai, Hsin-Hua, Nica, Emilian M., Hu, Wen-Jun, Gong, Shou-Shu, Paschen, Silke, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Quantum criticality beyond the Landau paradigm represents a fundamental problem in condensed matter and statistical physics. Heavy fermion systems with multipolar degrees of freedom can play an important role in the search for its universal description. We consider a Kondo lattice model with both spin and quadrupole degrees of freedom, which we show to exhibit an antiferroquadrupolar phase. Using a field theoretical representation of the model, we find that Kondo couplings are exactly marginal in the renormalization group sense in this phase. This contrasts with the relevant nature of the Kondo couplings in the paramagnetic phase and, as such, it implies that a Kondo destruction and a concomitant small to large Fermi surface jump must occur as the system is tuned from the antiferroquadrupolar ordered to the paramagnetic phase. Implications of our results for multipolar heavy fermion physics in particular and metallic quantum criticality in general are discussed., Comment: 4 and 1/2 page for the main texts plus supplemental material

Published

2018

37. Determining the local low-energy excitations in the Kondo semimetal CeRu$_4$Sn$_6$ using resonant inelastic x-ray scattering

Author

Amorese, Andrea, Kummer, Kurt, Brookes, Nickolas B., Stockert, Oliver, Adroja, Devashibhai T., Stryodm, Andre M., Sidorenko, Andrey, Winkler, Hannes, Zocco, Diego A., Prokofiev, Andrey, Paschen, Silke, Haverkort, Maurits W., Tjeng, Liu Hao, and Severing, Andrea

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We have investigated the local low-energy excitations in CeRu$_4$Sn$_6$, a material discussed recently in the framework of strongly correlated Weyl semimetals, by means of Ce $M_5$ resonant inelastic x-ray scattering (RIXS). The availability of both $^2$F$_\frac{5}{2}$ and $^2$F$_\frac{7}{2}$ excitations of the Ce $4f^1$ configuration in the spectra allows for the determination of the crystal-electric field parameters that explain quantitatively the temperature dependence and anisotropy of the magnetic susceptibility. The absence of an azimuthal dependence in the spectra indicates that all crystal-electric field states are close to being rotational symmetric. We show further that the non-negligible impact of the $\check A_6^0$ parameter on the ground state of CeRu$_4$Sn$_6$ leads to a reduction of the magnetic moment due to multiplet intermixing. The RIXS results are consistent with inelastic neutron scattering (INS) data and are compared to the predictions from \textsl{ab-initio} based electronic structure calculations., Comment: 9 pages and 7 figures, submitted

Published

2018

38. Low-carrier density and fragile magnetism in a Kondo lattice system

Author

Rai, Binod K., Oswald, Iain W. H., Ban, Wenjing, Huang, C. -L., Loganathan, V., Hallas, A. M., Wilson, M. N., Luke, G. M., Harriger, L., Huang, Q., Li, Y., Dzsaber, Sami, Chan, Julia Y., Wang, N. L., Paschen, Silke, Lynn, J. W., Nevidomskyy, Andriy H., Dai, P., Si, Q., and Morosan, E.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Kondo-based semimetals and semiconductors are of extensive current interest as a viable platform for strongly correlated states. It is thus important to understand the routes towards such dilute-carrier correlated states. One established pathway is through Kondo effect in metallic non-magnetic analogues. Here we advance a new mechanism, through which Kondo-based semimetals develop out of conduction electrons with a low carrier-density in the presence of an even number of rare-earth sites. We demonstrate this effect by studying the Kondo material Yb3Ir4Ge13 along with its closed-f-shell counterpart, Lu3Ir4Ge13. Through magnetotransport, optical conductivity and thermodynamic measurements, we establish that the correlated semimetallic state of Yb3Ir4Ge13 below its Kondo temperature originates from the Kondo effect of a low carrier conduction-electron background. In addition, it displays fragile magnetism at very low temperatures, which, in turn, can be tuned to a non Fermi liquid regime through Lu-for-Yb substitution. These findings are connected with recent theoretical studies in simplified models. Our results open an entirely new venue to explore the strong correlation physics in a semimetallic environment.

Published

2018

39. Suppression of vacancies boosts thermoelectric performance in type-I clathrates

Author

Yan, Xinlin, Ikeda, Matthias, Zhang, Long, Bauer, Ernst, Rogl, Peter, Giester, Gerald, Prokofiev, Andrey, and Paschen, Silke

Subjects

Condensed Matter - Materials Science

Abstract

Intermetallic type-I clathrates continue to attract attention as promising thermoelectric materials. Here we present structural and thermoelectric properties of single crystalline Ba8(Cu,Ga,Ge,v)46, where v denotes a vacancy. By single crystal X-ray diffraction on crystals without Ga we find clear evidence for the presence of vacancies at the 6c site in the structure. With increasing Ga content, vacancies are successively filled. This increases the charge carrier mobility strongly, even within a small range of Ga substitution, leading to reduced electrical resistivity and enhanced thermoelectric performance. The largest figure of merit ZT =0.9 at 900 K is found for a single crystal of approximate composition Ba8Cu4.6Ga1.0Ge40.4. This value, that may further increase at higher temperatures, is one of the largest to date found in transition metal element-based clathrates., Comment: 9 pages

Published

2017

40. Strange metal state near a heavy-fermion quantum critical point

Author

Chang, Yung-Yeh, Paschen, Silke, and Chung, Chung-Hou

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Recent experiments on quantum criticality in the Ge-substituted heavy-electron material YbRh2Si2 under magnetic field have revealed a possible non-Fermi liquid (NFL) strange metal (SM) state over a finite range of fields at low temperatures, which still remains a puzzle. In the SM region, the zero-field antiferromagnetism is suppressed. Above a critical field, it gives way to a heavy Fermi liquid with Kondo correlation. The T (temperature)-linear resistivity and the T-logarithmic followed by a power-law singularity in the specific heat coefficient at low T, salient NFL behaviours in the SM region, are un-explained. We offer a mechanism to address these open issues theoretically based on the competition between a quasi-2d fluctuating short-ranged resonant- valence-bonds (RVB) spin-liquid and the Kondo correlation near criticality. Via a field-theoretical renormalization group analysis on an effective field theory beyond a large-N approach to an anti- ferromagnetic Kondo-Heisenberg model, we identify the critical point, and explain remarkably well both the crossovers and the SM behaviour., Comment: 6 pages, 3 figures and Supplementary Materials

Published

2017

41. Author Correction: Control of electronic topology in a strongly correlated electron system

Author

Dzsaber, Sami, Zocco, Diego A., McCollam, Alix, Weickert, Franziska, McDonald, Ross, Taupin, Mathieu, Eguchi, Gaku, Yan, Xinlin, Prokofiev, Andrey, Tang, Lucas M. K., Vlaar, Bryan, Winter, Laurel E., Jaime, Marcelo, Si, Qimiao, and Paschen, Silke

Published

2022

42. Control of electronic topology in a strongly correlated electron system

Author

Dzsaber, Sami, Zocco, Diego A., McCollam, Alix, Weickert, Franziska, McDonald, Ross, Taupin, Mathieu, Eguchi, Gaku, Yan, Xinlin, Prokofiev, Andrey, Tang, Lucas M. K., Vlaar, Bryan, Winter, Laurel E., Jaime, Marcelo, Si, Qimiao, and Paschen, Silke

Published

2022

43. Weyl-Kondo Semimetal in Heavy Fermion Systems

Author

Lai, Hsin-Hua, Grefe, Sarah E., Paschen, Silke, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Insulating states can be topologically nontrivial, a well-established notion that is exemplified by the quantum Hall effect and topological insulators. By contrast, topological metals have not been experimentally evidenced until recently. In systems with strong correlations, they have yet to be identified. Heavy fermion semimetals are a prototype of strongly correlated systems and, given their strong spin-orbit coupling, present a natural setting to make progress. Here we advance a Weyl-Kondo semimetal phase in a periodic Anderson model on a noncentrosymmetric lattice. The quasiparticles near the Weyl nodes develop out of the Kondo effect, as do the surface states that feature Fermi arcs. We determine the key signatures of this phase, which are realized in the heavy fermion semimetal Ce$_3$Bi$_4$Pd$_3$. Our findings provide the much-needed theoretical foundation for the experimental search of topological metals with strong correlations, and open up a new avenue for systematic studies of such quantum phases that naturally entangle multiple degrees of freedom., Comment: Final version, PNAS, Early Edition published online on Dec 18, 2017. 5 pages in PNAS format + 4 figures + supplementary information

Published

2016

44. Giant isotropic Nernst effect in an anisotropic Kondo semimetal

Author

Stockert, Ulrike, Sun, Peije, Oeschler, Niels, Steglich, Frank, Takabatake, Toshiro, Coleman, Piers, and Paschen, Silke

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The "failed Kondo insulator" CeNiSn has long been suspected to be a nodal metal, with a node in the hybridization matrix elements. Here we carry out a series of Nernst effect experiments to delineate whether the severely anisotropic magnetotransport coefficients do indeed derive from a nodal metal or can simply be explained by a highly anisotropic Fermi surface. Our experiments reveal that despite an almost 20-fold anisotropy in the Hall conductivity, the large Nernst signal is isotropic. Taken in conjunction with the magnetotransport anisotropy, these results provide strong support for an isotropic Fermi surface with a large anisotropy in quasiparticle mass derived from a nodal hybridization., Comment: 4.5 pages, 4 figures

Published

2016

45. Global Phase Diagram and Momentum Distribution of Single-Particle Excitations in Kondo insulators

Author

Pixley, J. H., Yu, Rong, Paschen, Silke, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Kondo insulators are emerging as a simplified setting to study both magnetic and metal-to-insulator quantum phase transitions. Here, we study a half-filled Kondo lattice model defined on a magnetically frustrated Shastry-Sutherland geometry. We determine a "global" phase diagram that features a variety of zero-temperature phases; these include Kondo-destroyed antiferromagnetic and paramagnetic metallic phases in addition to the Kondo-insulator phase. Our result provides the theoretical basis for understanding how applying pressure to a Kondo insulator can close its hybridization gap, liberate the local-moment spins from the conduction electrons, and lead to a magnetically correlated metal. We also study the momentum distribution of the single-particle excitations in the Kondo insulating state, and illustrate how Fermi-surface-like features emerge as a precursor to the actual Fermi surfaces of the Kondo-destroyed metals. We discuss the implications of our results for Kondo insulators including SmB$_6$., Comment: 5 pages, 5 figures, supplemental material 3 pages, 2 figures

Published

2015

46. Anomalous Hall effect and quantum criticality in geometrically frustrated heavy fermion metals

Author

Ding, Wenxin, Grefe, Sarah, Paschen, Silke, and Si, Qimiao

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Studies on the heavy-fermion pyrochlore iridate (Pr$_2$Ir$_2$O$_7$) point to the role of time-reversal-symmetry breaking in geometrically frustrated Kondo lattices. With this motivation, here we study the effect of Kondo coupling and chiral spin liquids in a frustrated $J_1-J_2$ model on a square lattice. We treat the Kondo effect within a slave-fermion approach, and discuss our results in the context of a proposed global phase diagram for heavy fermion metals. We calculate the anomalous Hall response for the chiral states of both the Kondo destroyed and Kondo screened phases. Across the quantum critical point, a reconstruction of the Fermi surface leads to a sudden change of the Berry curvature distribution and, consequently, a jump of the anomalous Hall conductance. We discuss the implications of our results for the heavy-fermion pyrochlore iridate and propose an interface structure based on Kondo insulators to further explore such effects., Comment: v3: 6 pages, 3 figures, plus supplementary material; to appear in Phys. Rev. Lett

Published

2015

47. Quantum phases driven by strong correlations

Author

Paschen, Silke and Si, Qimiao

Published

2021

48. Sequential localization of a complex electron fluid

Author

Martelli, Valentina, Cai, Ang, Nica, Emilian M., Taupin, Mathieu, Prokofiev, Andrey, Liu, Chia-Chuan, Lai, Hsin-Hua, Yu, Rong, Ingersent, Kevin, Küchler, Robert, Strydom, André M., Geiger, Diana, Haenel, Jonathan, Larrea, Julio, Si, Qimiao, and Paschen, Silke

Published

2019

49. Quantum phase transitions in heavy fermion metals and Kondo insulators

Author

Si, Qimiao and Paschen, Silke

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

Abstract

Strongly correlated electron systems at the border of magnetism are of active current interest, particularly because the accompanying quantum criticality provides a route towards both strange-metal non-Fermi liquid behavior and unconventional superconductivity. Among the many important questions is whether the magnetism acts simply as a source of fluctuations in the textbook Landau framework, or instead serves as a proxy for some unexpected new physics. We put into this general context the recent developments on quantum phase transitions in antiferromagnetic heavy fermion metals. Among these are the extensive recent theoretical and experimental studies on the physics of Kondo destruction in a class of beyond-Landau quantum critical points. Also discussed are the theoretical basis for a global phase diagram of antiferromagnetic heavy fermion metals, and the recent surge of materials suitable for studying this phase diagram. Furthermore, we address the generalization of this global phase diagram to the case of Kondo insulators, and consider the future prospect to study the interplay among Kondo coherence, magnetism and topological states. Finally, we touch upon related issues beyond the antiferromagnetic settings, arising in mixed valent, ferromagnetic, quadrupolar, or spin glass f-electron systems, as well as some general issues on emergent phases near quantum critical points., Comment: 14 pages, 7 figures. Review article as part of the contributions to QCNP12. Covering quantum criticality and novel phases in the most-extensively studied case of antiferromagnetic heavy fermion metals, while extending the discussion to the less explored settings such as Kondo insulating, mixed valent, and ferromagnetic systems

Published

2013

50. Phononic filter effect of rattling phonons in the thermoelectric clathrate Ba$_8$Ge$_{40+x}$Ni$_{6-x}$

Author

Euchner, Holger, Pailhès, Stephane, Nguyen, Lien, Assmus, Wolf, Ritter, Franz, Haghighirad, Amir, Grin, Yuri, Paschen, Silke, and de Boissieu, Marc.

Subjects

Condensed Matter - Materials Science

Abstract

One of the key requirements for good thermoelectric materials is a low lattice thermal conductivity. Here we present a combined neutron scattering and theoretical investigation of the lattice dynamics in the type I clathrate system Ba-Ge-Ni, which fulfills this requirement. We observe a strong hybridization between phonons of the Ba guest atoms and acoustic phonons of the Ge-Ni host structure over a wide region of the Brillouin zone which is in contrast with the frequently adopted picture of isolated Ba atoms in Ge-Ni host cages. It occurs without a strong decrease of the acoustic phonon lifetime which contradicts the usual assumption of strong anharmonic phonon--phonon scattering processes. Within the framework of ab-intio density functional theory calculations we interpret these hybridizations as a series of an ti-crossings which act as a low pass filter, preventing the propagation of acoustic phonons. To highlight the effect of such a phononic low pass filter on the thermal transport, we compute the contribution of acoustic phonons to the thermal conductivity of Ba$_8$Ge$_{40}$Ni$_{6}$ and compare it to those of pure Ge and a Ge$_{46}$ empty-cage model system., Comment: 10 pages, 10 figures

Published

2012