Your search keyword '"quantum oscillations"' showing total 18 results

1. Unconventional magnetic oscillations in a kagome Mott insulator.

Author

Guoxin Zheng, Yuan Zhu, Kuan-Wen Chen, Byungmin Kang, Dechen Zhang, Jenkins, Kaila, Chan, Aaron, Zhenyuan Zeng, Aini Xu, Valenzuela, Oscar A., Blawat, Joanna, Singleton, John, Shiliang Li, Lee, Patrick A., and Lu Li

Subjects

*QUANTUM spin liquid, *MAGNETIC torque, *MAGNETIC ions, *MAGNETIC fields, *OSCILLATIONS

Abstract

In metals, electrons in a magnetic field undergo cyclotron motion, leading to oscillations in physical properties called quantum oscillations. This phenomenon has never been seen in a robust insulator because there are no mobile electrons. We report an exception to this rule. We study a Mott insulator on a kagome lattice which does not order magnetically down to milli-Kelvin temperatures despite antiferromagnetic interactions. We observe a plateau at magnetization equal to 1/9 Bohr magneton per magnetic ion, accompanied by oscillations in the magnetic torque, reminiscent of quantum oscillations in metals. The temperature dependence obeys Fermi distribution. These phenomena are consistent with a quantum spin liquid state whose excitations are fermionic spinons with a Dirac-like spectrum coupled to an emergent gauge field. [ABSTRACT FROM AUTHOR]

Published

2025

2. Quantum oscillations in the hole-doped cuprates and the confinement of spinons.

Author

Bonetti, Pietro M., Christos, Maine, and Sachdev, Subir

Subjects

*CHARGE density waves, *FERMI surfaces, *HEAT resistant alloys, *QUANTUM spin liquid, *FREQUENCIES of oscillating systems

Abstract

A long-standing problem in the study of the under-hole-doped cuprates has been the description of the Fermi surfaces underlying the high magnetic field quantum oscillations, and their connection to the higher temperature pseudogap metal. Harrison and Sebastian [Phys. Rev. Lett. 106, 226402 (2011)] proposed that the pseudogap "Fermi arcs" are reconstructed into an electron pocket by field-induced charge density wave order. But computations on such a model [Zhang and Mei, Europhys. Lett. 114, 47008 (2016)] show an unobserved additional oscillation frequency from a Fermi surface arising from the backsides of the hole pockets completing the Fermi arcs. We describe a transition from a fractionalized Fermi liquid (FL*) model of the pseudogap metal, to a metal with bidirectional charge density wave order without fractionalization. We show that the confinement of the fermionic spinon excitations of the FL* across this transition can eliminate the unobserved oscillation frequency. [ABSTRACT FROM AUTHOR]

Published

2024

3. Large Fermi surface in pristine kagome metal CsV3Sb5 and enhanced quasiparticle effective masses.

Author

Wei Zhang, Tsz Fung Poon, Chun Wai Tsang, Wenyan Wang, Liu, X., Xie, J., Lam, S. T., Shanmin Wang, Kwing To Lai, Pourret, A., Seyfarth, G., Knebel, G., Wing Chi Yu, and Goh, Swee K.

Subjects

*FERMI surfaces, *CHARGE density waves, *ELECTRON configuration, *DENSITY functional theory, *QUANTUM fluctuations

Abstract

The kagome metal CsV3Sb5 is an ideal platform to study the interplay between topology and electron correlation. To understand the fermiology of CsV3Sb5, intensive quantum oscillation (QO) studies at ambient pressure have been conducted. However, due to the Fermi surface reconstruction by the complicated charge density wave (CDW) order, the QO spectrum is exceedingly complex, hindering a complete understanding of the fermiology. Here, we directly map the Fermi surface of the pristine CsV3Sb5 by measuring Shubnikov-de Haas QOs up to 29 T under pressure, where theCDWorder is completely suppressed. The QO spectrum of the pristine CsV3Sb5 is significantly simpler than the one in the CDW phase, and the detected oscillation frequencies agree well with our density functional theory calculations. In particular, a frequency as large as 8,200 T is detected. Pressure-dependent QO studies further reveal a weak but noticeable enhancement of the quasiparticle effective masses on approaching the critical pressure where the CDW order disappears, hinting at the presence of quantum fluctuations. Our high-pressure QO results reveal the large, unreconstructed Fermi surface of CsV3Sb5, paving the way to understanding the parent state of this intriguing metal in which the electrons can be organized into different ordered states. [ABSTRACT FROM AUTHOR]

Published

2024

4. Quantum interference in superposed lattices.

Author

Yejun Feng, Yishu Wang, Rosenbaum, T. F., Littlewood, P. B., and Hua Chen

Abstract

Charge transport in solids at low temperature reveals a material's mesoscopic properties and structure. Under a magnetic field, Shubnikov-de Haas (SdH) oscillations inform complex quantum transport phenomena that are not limited by the ground state characteristics and have facilitated extensive explorations of quantum and topological interest in two- and three-dimensional materials. Here, in elemental metal Cr with two incommensurately superposed lattices of ions and a spin-density-wave ground state, we reveal that the phases of several low-frequency SdH oscillations in σxx (ρxx) and σyy (ρyy) are no longer identical but opposite. These relationships contrast with the SdH oscillations from normal cyclotron orbits that maintain identical phases between σxx (ρxx) and σyy (ρyy). We trace the origin of the low-frequency SdH oscillations to quantum interference effects arising from the incommensurate orbits of Cr's superposed reciprocal lattices and explain the observed π-phase shift by the reconnection of anisotropic joint open and closed orbits. [ABSTRACT FROM AUTHOR]

Published

2024

5. Truncated mass divergence in a Mott metal.

Author

Semeniuk, Konstantin, Hui Chang, Baglo, Jordan, Friedemann, Sven, Tozer, Stanley W., Coniglio, William A., Gamża, Monika B., Reiss, Pascal, Alireza, Patricia, Leermakers, Inge, McCollam, Alix, Grockowiak, Audrey D., and Grosche, F. Malte

Subjects

*CONDENSED matter physics, *METAL-insulator transitions, *FERMI surfaces, *QUANTUM measurement, *PHASE diagrams

Abstract

The Mott metal-insulator transition represents one of the most fundamental phenomena in condensed matter physics. Yet, basic tenets of the canonical Brinkman-Rice picture of Mott localization remain to be tested experimentally by quantum oscillation measurements that directly probe the quasiparticle Fermi surface and effective mass. By extending this technique to high pressure, we have examined the metallic state on the threshold of Mott localization in clean, undoped crystals of NiS3. We find that i) on approaching Mott localization, the quasiparticle mass is strongly enhanced, whereas the Fermi surface remains essentially unchanged; ii) the quasiparticle mass closely follows the divergent form predicted theoretically, establishing charge carrier slowdown as the driver for the metal-insulator transition; iii) this mass divergence is truncated by the metal-insulator transition, placing the Mott critical point inside the insulating section of the phase diagram. The inaccessibility of the Mott critical point in NiS2 parallels findings at the threshold of ferromagnetism in clean metallic systems, in which criticality at low temperature is almost universally interrupted by first-order transitions or novel emergent phases such as incommensurate magnetic order or unconventional superconductivity. [ABSTRACT FROM AUTHOR]

Published

2023

6. Unconventional localization of electrons inside of a nematic electronic phase.

Author

Farrar, Liam S., Zajicek, Zachary, Morfoot, Archie B., Bristow, Matthew, Humphries, Oliver S., Haghighirad, Amir A., McCollam, Alix, Bending, Simon J., and Coldea, Amalia I.

Subjects

*ELECTRON mobility, *QUANTUM scattering, *ELECTRONS, *CHARGE carriers, *ELECTRONIC structure

Abstract

The magnetotransport behavior inside the nematic phase of bulk FeSe reveals unusual multiband effects that cannot be reconciled with a simple two-band approximation proposed by surface-sensitive spectroscopic probes. In order to understand the role played by the multiband electronic structure and the degree of two-dimensionality, we have investigated the electronic properties of exfoliated flakes of FeSe by reducing their thickness. Based on magnetotransport and Hall resistivity measurements, we assess the mobility spectrum that suggests an unusual asymmetry between the mobilities of the electrons and holes, with the electron carriers becoming localized inside the nematic phase. Quantum oscillations in magnetic fields up to 38 T indicate the presence of a hole-like quasiparticle with a lighter effective mass and a quantum scattering time three times shorter, as compared with bulk FeSe. The observed localization of negative charge carriers by reducing dimensionality can be driven by orbitally dependent correlation effects, enhanced interband spin fluctuations, or a Lifshitz-like transition, which affect mainly the electron bands. The electronic localization leads to a fragile two-dimensional superconductivity in thin flakes of FeSe, in contrast to the two-dimensional high-Tc induced with electron doping via dosing or using a suitable interface. [ABSTRACT FROM AUTHOR]

Published

2022

7. Quantum oscillations in the magnetization and density of states of insulators.

Author

Panda, Animesh, Banerjee, Sumilan, and Randeria, Mohit

Subjects

*DENSITY of states, *OSCILLATIONS, *MAGNETIZATION, *FREQUENCIES of oscillating systems, *FERMI surfaces

Abstract

The observation of 1/B-periodic behavior in Kondo insulators and semiconductor quantum wells challenges the conventional wisdom that quantum oscillations (QOs) necessarily arise from Fermi surfaces in metals. We revisit recently proposed theories for this phenomenon, focusing on a minimal model of an insulator with a hybridization gap between two opposite-parity light and heavy mass bands with an inverted band structure. We show that there are characteristic differences between the QO frequencies in the magnetization and the low-energy density of states (LE-DOS) of these insulators, in marked contrast to metals where all observables exhibit oscillations at the same frequency. The magnetization oscillations arising from occupied Landau levels occur at the same frequency that would exist in the unhybridized case. The LE-DOS oscillations in a disorder-free system are dominated by gap-edge states and exhibit a beat pattern between two distinct frequencies at low temperature. Disorder-induced in-gap states lead to an additional contribution to the DOS at the unhybridized frequency. The temperature dependence of the amplitude and phase of the magnetization and DOS oscillations are also qualitatively different and show marked deviations from the Lifshitz–Kosevich form well known in metals. We also compute transport to ensure that we are probing a regime with insulating upturns in the direct current (DC) resistivity. [ABSTRACT FROM AUTHOR]

Published

2022

8. Unconventional quantum vortex matter state hosts quantum oscillations in the underdoped high-temperature cuprate superconductors.

Author

Yu-Te Hsua, Hartstein, Máté, Davies, Alexander J., Hickey, Alexander J., Chan, Mun K., Porras, Juan, Toshinao Loew, Taylor, Sofia V., Hsu Liu, Eaton, Alexander G., Le Tacon, Matthieu, Huakun Zuo, Jinhua Wang, Zengwei Zhu, Lonzarich, Gilbert G., Keimer, Bernhard, Harrison, Neil, and Sebastian, Suchitra E.

Subjects

*HIGH temperature superconductors, *PHASES of matter, *QUANTUM states, *OSCILLATIONS, *ELECTRICAL resistivity, *FLEXIBLE AC transmission systems

Abstract

A central question in the underdoped cuprates pertains to the nature of the pseudogap ground state. A conventional metallic ground state of the pseudogap region has been argued to host quantum oscillations upon destruction of the superconducting order parameter by modest magnetic fields. Here, we use low applied measurement currents and millikelvin temperatures on ultrapure single crystals of underdoped YBa2Cu3O6+x to unearth an unconventional quantum vortex matter ground state characterized by vanishing electrical resistivity, magnetic hysteresis, and nonohmic electrical transport characteristics beyond the highest laboratory-accessible static fields. A model of the pseudogap ground state is now required to explain quantum oscillations that are hosted by the bulk quantum vortex matter state without experiencing sizable additional damping in the presence of a large maximum superconducting gap; possibilities include a pair density wave. [ABSTRACT FROM AUTHOR]

Published

2021

9. Vanishing quantum oscillations in Dirac semimetal ZrTe5.

Author

Jingyue Wang, Jingjing Niu, Baoming Yan, Xinqi Li, Ran Bi, Dapeng Yu, Xiaosong Wu, and Yuan Yao

Subjects

*OSCILLATIONS, *ZEEMAN effect, *DIRAC equation, *GEOMETRIC quantum phases, *TOPOLOGICAL fields

Abstract

One of the characteristics of topological materials is their nontrivial Berry phase. Experimental determination of this phase largely relies on a phase analysis of quantum oscillations. We study the angular dependence of the oscillations in a Dirac material ZrTe5 and observe a striking spin-zero effect (i.e., vanishing oscillations accompanied with a phase inversion). This indicates that the Berry phase in ZrTe5 remains nontrivial for arbitrary field direction, in contrast with previous reports. The Zeeman splitting is found to be proportional to the magnetic field based on the condition for the spin-zero effect in a Dirac band. Moreover, it is suggested that the Dirac band in ZrTe5 is likely transformed into a line node other than Weyl points for the field directions at which the spin zero occurs. The results underline a largely overlooked spin factor when determining the Berry phase from quantum oscillations. [ABSTRACT FROM AUTHOR]

Published

2018

10. Vanishing quantum oscillations in Dirac semimetal ZrTe5.

Author

Jingyue Wang, Jingjing Niu, Baoming Yan, Xinqi Li, Ran Bi, Dapeng Yu, Xiaosong Wu, and Yuan Yao

Subjects

OSCILLATIONS, ZEEMAN effect, DIRAC equation, GEOMETRIC quantum phases, TOPOLOGICAL fields

Abstract

One of the characteristics of topological materials is their nontrivial Berry phase. Experimental determination of this phase largely relies on a phase analysis of quantum oscillations. We study the angular dependence of the oscillations in a Dirac material ZrTe5 and observe a striking spin-zero effect (i.e., vanishing oscillations accompanied with a phase inversion). This indicates that the Berry phase in ZrTe5 remains nontrivial for arbitrary field direction, in contrast with previous reports. The Zeeman splitting is found to be proportional to the magnetic field based on the condition for the spin-zero effect in a Dirac band. Moreover, it is suggested that the Dirac band in ZrTe5 is likely transformed into a line node other than Weyl points for the field directions at which the spin zero occurs. The results underline a largely overlooked spin factor when determining the Berry phase from quantum oscillations. [ABSTRACT FROM AUTHOR]

Published

2018

11. Quantum oscillations in a biaxial pair density wave state.

Author

Norman, M. R. and Davis, J. C. Séamus

Subjects

*DENSITY wave theory, *CUPRATES, *X-ray scattering, *FERMI energy, *QUANTUM harmonic oscillators, *MAGNETIC fields, *VORTEX methods

Abstract

There has been growing speculation that a pair density wave state is a key component of the phenomenology of the pseudogap phase in the cuprates. Recently, direct evidence for such a state has emerged from an analysis of scanning tunneling microscopy data in halos around the vortex cores. By extrapolation, these vortex halos would then overlap at a magnetic-field scale where quantum oscillations have been observed. Here, we show that a biaxial pair density wave state gives a unique description of the quantum oscillation data, bolstering the case that the pseudogap phase in the cuprates may be a pair density wave state. [ABSTRACT FROM AUTHOR]

Published

2018

12. Metal-insulator quantum critical point beneath the high Tc superconducting dome.

Author

Sebastian, Suchitra E., Harrison, N., Altarawneh, M. M., Mielke, C. H., Ruixing Liang, Bonn, D. A., Hardy, W. N., and Lonzarich, G. G.

Subjects

*FERMI surfaces, *HIGH temperature superconductivity, *METAL-insulator transitions, *OSCILLATIONS, *SUPERCONDUCTIVITY, *EFFECTIVE mass (Physics)

Abstract

An enduring question in correlated systems concerns whether superconductivity is favored at a quantum critical point (QCP) characterized by a divergent quasiparticle effective mass. Despite such a scenario being widely postulated in high Tc cuprates and invoked to explain non-Fermi liquid transport signatures, experimental evidence is lacking for a critical divergence under the superconducting dome. We use ultrastrong magnetic fields to measure quantum oscillations in underdoped YBa2Cu3O6+x. revealing a dramatic doping-dependent upturn in quasiparticle effective mass at a critical metal-insulator transition beneath the superconducting dome. Given the location of this QCP under a plateau in Tc in addition to a postulated QCP at optimal doping, we discuss the intriguing possibility of two intersecting superconducting subdomes, each centered at a critical Fermi surface instability. [ABSTRACT FROM AUTHOR]

Published

2010

13. Pressure-induced phase transitions and superconductivity in a black phosphorus single crystal

Author

Tao Xiang, Jianping Sun, P. Shahi, Jianshi Zhou, Allan H. MacDonald, Yoshiya Uwatoko, Jinguang Cheng, Miao Gao, Xiang Li, and John B. Goodenough

Subjects

Superconductivity, Phase transition, Phase boundary, Multidisciplinary, Materials science, Condensed matter physics, Hydrostatic pressure, Quantum oscillations, Fermi surface, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Corrections, Hall effect, Phase (matter), 0103 physical sciences, 010306 general physics, 0210 nano-technology

Abstract

We report a thorough study of the transport properties of the normal and superconducting states of black phosphorus (BP) under magnetic field and high pressure with a large-volume apparatus that provides hydrostatic pressure to induce transitions from the layered A17 phase to the layered A7 phase and to the cubic phase of BP. Quantum oscillations can be observed at P ≥ 1 GPa in both resistivity and Hall voltage, and their evolutions with pressure in the A17 phase imply a continuous enlargement of Fermi surface. A significantly large magnetoresistance (MR) at low temperatures is observed in the A7 phase that becomes superconducting below a superconducting transition temperature T c ∼ 6–13 K. T c increases continuously with pressure on crossing the A7 to the cubic phase boundary. The strong MR effect can be fit by a modified Kohler’s rule. A correlation between T c and fitting parameters suggests that phonon-mediated interactions play dominant roles in driving the Cooper pairing, which is further supported by our density functional theory (DFT) calculations. The change of effective carrier mobility in the A17 phase under pressure derived from the MR effect is consistent with that obtained from the temperature dependence of the quantum oscillations. In situ single-crystal diffraction under high pressure indicates a total structural reconstruction instead of simple stretching of the A17 phase layers in the A17-to-A7-phase transition. This finding helps us to interpret transport properties on crossing the phase transition under high pressure.

Published

2018

14. Large nonsaturating magnetoresistance and signature of nondegenerate Dirac nodes in ZrSiS

Author

Ratnadwip Singha, Biswarup Satpati, Prabhat Mandal, and Arnab Pariari

Subjects

Physics, Chiral anomaly, Condensed Matter - Materials Science, Multidisciplinary, Condensed matter physics, Magnetoresistance, Dirac (software), Quantum oscillations, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences, 02 engineering and technology, Electron, 021001 nanoscience & nanotechnology, 01 natural sciences, symbols.namesake, Dirac fermion, Hall effect, 0103 physical sciences, Physical Sciences, symbols, Condensed Matter::Strongly Correlated Electrons, 010306 general physics, 0210 nano-technology, Dirac sea

Abstract

While the discovery of Dirac and Weyl type excitations in electronic systems is a major breakthrough in recent condensed matter physics, finding appropriate materials for fundamental physics and technological applications, is an experimental challenge. In all the reported materials, linear dispersion survives only up to a few hundred meV from the Dirac or Weyl nodes. On the other hand, real materials are subject to uncontrolled doping during preparation and thermal effect near room temperature can hinder the rich physics. In ZrSiS, ARPES measurements have shown an unusually robust linear dispersion (up to $\sim$2 eV) with multiple non-degenerate Dirac nodes. In this context, we present the magnetotransport study on ZrSiS crystal, which represents a large family of materials (\textit{WHM} with \textit{W} = Zr, Hf; \textit{H} = Si, Ge, Sn; \textit{M} = O, S, Se, Te) with identical band topology. Along with extremely large and non-saturating magnetoresistance (MR), $\sim$ 1.4 $\times$ 10$^{5}$ \% at 2 K and 9 T, it shows strong anisotropy depending on the direction of the magnetic field. Quantum oscillation and Hall effect measurements have revealed large hole and small electron Fermi pockets. Non-trivial $\pi$ Berry phase confirms the Dirac fermionic nature for both types of charge carriers. The long-sought relativistic phenomenon of massless Dirac fermions, known as Adler-Bell-Jackiw chiral anomaly, has also been observed., Comment: 10 pages, 13 figures

Published

2017

15. Spectroscopic evidence for Fermi liquid-like energy and temperature dependence of the relaxation rate in the pseudogap phase of the cuprates

Author

Erik van Heumen, Yuan Li, Neven Barišić, Seyed Iman Mirzaei, Antoine Georges, Dirk van der Marel, D. Stricker, Martin Greven, Mun Chan, Christophe Berthod, Jason Hancock, X. Zhao, and Hard Condensed Matter (WZI, IoP, FNWI)

Subjects

Superconductivity, Optical spectroscopy, 02 engineering and technology, ddc:500.2, 01 natural sciences, Electrical resistivity and conductivity, Fermi liquid, Condensed Matter::Superconductivity, 0103 physical sciences, Self energy, Cuprate, 010306 general physics, Cuprate high-Tc superconductors, Landau-Fermi liquid, pseudogap, Physics, Condensed Matter::Quantum Gases, Multidisciplinary, Condensed matter physics, Quantum oscillations, Fermi surface, 021001 nanoscience & nanotechnology, Mass renormalization, Physical Sciences, Condensed Matter::Strongly Correlated Electrons, Fermi liquid theory, 0210 nano-technology, Pseudogap, Fermi gas

Abstract

Cuprate high- T c superconductors exhibit enigmatic behavior in the nonsuperconducting state. For carrier concentrations near “optimal doping” (with respect to the highest T c s) the transport and spectroscopic properties are unlike those of a Landau–Fermi liquid. On the Mott-insulating side of the optimal carrier concentration, which corresponds to underdoping, a pseudogap removes quasi-particle spectral weight from parts of the Fermi surface and causes a breakup of the Fermi surface into disconnected nodal and antinodal sectors. Here, we show that the near-nodal excitations of underdoped cuprates obey Fermi liquid behavior. The lifetime τ ( ω , T ) of a quasi-particle depends on its energy ω as well as on the temperature T . For a Fermi liquid, 1/ τ ( ω , T ) is expected to collapse on a universal function proportional to ( ℏω ) 2 + ( pπk B T ) 2 . Magneto-transport experiments, which probe the properties in the limit ω = 0, have provided indications for the presence of a T 2 dependence of the dc ( ω = 0) resistivity of different cuprate materials. However, Fermi liquid behavior is very much about the energy dependence of the lifetime, and this can only be addressed by spectroscopic techniques. Our optical experiments confirm the aforementioned universal ω - and T dependence of 1/ τ ( ω , T ), with p ∼ 1.5. Our data thus provide a piece of evidence in favor of a Fermi liquid-like scenario of the pseudogap phase of the cuprates.

Published

2013

16. Are the surface Fermi arcs in Dirac semimetals topologically protected?

Author

Mehdi Kargarian, Yuan-Ming Lu, and Mohit Randeria

Subjects

Surface (mathematics), Physics, Multidisciplinary, Condensed matter physics, Dirac (video compression format), Quantum oscillations, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Brillouin zone, Gapless playback, Quantum mechanics, Topological insulator, 0103 physical sciences, Physical Sciences, Condensed Matter::Strongly Correlated Electrons, 010306 general physics, 0210 nano-technology, Fermi Gamma-ray Space Telescope, Surface states

Abstract

Motivated by recent experiments probing anomalous surface states of Dirac semimetals (DSMs) Na3Bi and Cd3As2, we raise the question posed in the title. We find that, in marked contrast to Weyl semimetals, the gapless surface states of DSMs are not topologically protected in general, except on time-reversal-invariant planes of surface Brillouin zone. We first demonstrate this finding in a minimal four-band model with a pair of Dirac nodes at [Formula: see text] where gapless states on the side surfaces are protected only near [Formula: see text] We then validate our conclusions about the absence of a topological invariant protecting double Fermi arcs in DSMs, using a K-theory analysis for space groups of Na3Bi and Cd3As2 Generically, the arcs deform into a Fermi pocket, similar to the surface states of a topological insulator, and this pocket can merge into the projection of bulk Dirac Fermi surfaces as the chemical potential is varied. We make sharp predictions for the doping dependence of the surface states of a DSM that can be tested by angle-resolved photoemission spectroscopy and quantum oscillation experiments.

Published

2016

17. On the two-fluid model of the Kondo lattice

Author

Gilbert G. Lonzarich

Subjects

Superconductivity, Physics, Multidisciplinary, Condensed matter physics, PNAS Plus, Quantum critical point, Hydrostatic pressure, Quantum oscillations, Fermi energy, Fermi liquid theory, Fermi gas, Phase diagram

Abstract

The normal state of conduction electrons in metals at low temperatures has been described in terms of the standard theory of a Fermi liquid introduced soon after the advent of quantum mechanics and completed by Landau and others by the middle of the 20th century (1). Fermi liquid theory describes the nature of a quantum liquid of interacting itinerant fermions below a characteristic temperature T FL, which can be far below the bare Fermi temperature T F. The state above T FL, but below T F, is itself a correlated quantum liquid that can extend down to very low temperatures close to a quantum critical point (Fig. 1 A ) (2). Fig. 1. Two-fluid model of the Kondo lattice. ( A ) Schematic temperature-vs.-hybridization effectiveness phase diagram about a quantum critical point (midpoint of lower horizontal axis). f can be tuned in practice via hydrostatic pressure or chemical substitution. T N is the Neel temperature and T * is the hybridization crossover temperature. ( B and C ) the heavy carrier fraction f h( T ) and local moment fraction f l( T ), respectively, as functions of temperature and hybridization effectiveness in the two-fluid model. The quantum critical point corresponds to a T of 0 and an f of 1. The heavy carrier fraction saturates and the local moment fraction vanishes below T L for f > 1. The Kondo liquid tends to be unstable to superconductivity or other subtle forms of quantum order. The transitions or crossovers into such states as well as the relocalization temperature just above T N (and T N itself in B and C ) are not indicated. Yang and Pines (3) and Shirer et al. (4) present a phenomenological description of such a correlated quantum liquid known as the Kondo liquid (5). In the simplest case … 1E-mail: gl238{at}cam.ac.uk.

Published

2012

18. Vanishing quantum oscillations in Dirac semimetal ZrTe₅

Author

Wang, Jingyue, Niu, Jingjing, Yan, Baoming, Li, Xinqi, Bi, Ran, Yao, Yuan, Yu, Dapeng, and Wu, Xiaosong

Published

2018