Your search keyword '"Foster, Matthew S."' showing total 23 results

1. Weyl nodal ring states and Landau quantization with very large magnetoresistance in square-net magnet EuGa4

Author

Lei, Shiming, Allen, Kevin, Huang, Jianwei, Moya, Jaime M., Wu, Tsz Chun, Casas, Brian, Zhang, Yichen, Oh, Ji Seop, Hashimoto, Makoto, Lu, Donghui, Denlinger, Jonathan, Jozwiak, Chris, Bostwick, Aaron, Rotenberg, Eli, Balicas, Luis, Birgeneau, Robert, Foster, Matthew S., Yi, Ming, Sun, Yan, and Morosan, Emilia

Published

2023

2. How spectrum-wide quantum criticality protects surface states of topological superconductors from Anderson localization: Quantum Hall plateau transitions (almost) all the way down

Author

Karcher, Jonas F. and Foster, Matthew S.

Published

2021

3. Weyl nodal ring states and Landau quantization with very large magnetoresistance in square-net magnet EuGa4.

Author

Lei, Shiming, Allen, Kevin, Huang, Jianwei, Moya, Jaime M., Wu, Tsz Chun, Casas, Brian, Zhang, Yichen, Oh, Ji Seop, Hashimoto, Makoto, Lu, Donghui, Denlinger, Jonathan, Jozwiak, Chris, Bostwick, Aaron, Rotenberg, Eli, Balicas, Luis, Birgeneau, Robert, Foster, Matthew S., Yi, Ming, Sun, Yan, and Morosan, Emilia

Subjects

SUPERCONDUCTING magnets, MAGNETORESISTANCE, PHOTOEMISSION, PHOTOELECTRON spectroscopy, MAGNETICS, DENSITY functional theory, QUANTUM measurement

Abstract

Magnetic topological semimetals allow for an effective control of the topological electronic states by tuning the spin configuration. Among them, Weyl nodal line semimetals are thought to have the greatest tunability, yet they are the least studied experimentally due to the scarcity of material candidates. Here, using a combination of angle-resolved photoemission spectroscopy and quantum oscillation measurements, together with density functional theory calculations, we identify the square-net compound EuGa4 as a magnetic Weyl nodal ring semimetal, in which the line nodes form closed rings near the Fermi level. The Weyl nodal ring states show distinct Landau quantization with clear spin splitting upon application of a magnetic field. At 2 K in a field of 14 T, the transverse magnetoresistance of EuGa4 exceeds 200,000%, which is more than two orders of magnitude larger than that of other known magnetic topological semimetals. Our theoretical model suggests that the non-saturating magnetoresistance up to 40 T arises as a consequence of the nodal ring state. The tunability of electronic properties is a central goal of research into topological semimetals. Here, the authors report Weyl nodal ring states in the magnetic semimetal EuGa4 and link the nodal ring state to the observed large non-saturating magnetoresistance. [ABSTRACT FROM AUTHOR]

Published

2023

4. Dynamical phase transitions in the collisionless pre-thermal states of isolated quantum systems: theory and experiments.

Author

Marino, Jamir, Eckstein, Martin, Foster, Matthew S, and Rey, Ana Maria

Subjects

QUANTUM theory, PHASE transitions, QUANTUM states, SYSTEMS theory, QUANTUM field theory

Abstract

We overview the concept of dynamical phase transitions (DPTs) in isolated quantum systems quenched out of equilibrium. We focus on non-equilibrium transitions characterized by an order parameter, which features qualitatively distinct temporal behavior on the two sides of a certain dynamical critical point. DPTs are currently mostly understood as long-lived prethermal phenomena in a regime where inelastic collisions are incapable to thermalize the system. The latter enables the dynamics to substain phases that explicitly break detailed balance and therefore cannot be encompassed by traditional thermodynamics. Our presentation covers both cold atoms as well as condensed matter systems. We revisit a broad plethora of platforms exhibiting pre-thermal DPTs, which become theoretically tractable in a certain limit, such as for a large number of particles, large number of order parameter components, or large spatial dimension. The systems we explore include, among others, quantum magnets with collective interactions, ϕ4 quantum field theories, and Fermi–Hubbard models. A section dedicated to experimental explorations of DPTs in condensed matter and AMO systems connects this large variety of theoretical models. [ABSTRACT FROM AUTHOR]

Published

2022

5. Quench-Induced Floquet Topological p-Wave Superfluids.

Author

Foster, Matthew S., Gurarie, Victor, Dzero, Maxim, and Yuzbashyan, Emil A.

Subjects

*SUPERFLUIDITY, *RESONANCE, *ATOMS, *MATHEMATICAL analysis, *FORCE & energy

Abstract

Ultracold atomic gases in two dimensions tuned close to a p -wave Feshbach resonance were expected to exhibit topological superfluidity, but these were found to be experimentally unstable. We show that one can induce a topological Floquet superfluid if weakly interacting atoms are brought suddenly close ("quenched") to such a resonance, in the time before the instability kicks in. The resulting superfluid possesses Majorana edge modes, yet differs from a conventional Floquet system as it is not driven externally. Instead, the periodic modulation is self-generated by the dynamics. [ABSTRACT FROM AUTHOR]

Published

2014

6. Chalker scaling, level repulsion, and conformal invariance in critically delocalized quantum matter: Disordered topological superconductors and artificial graphene.

Author

Yang-Zhi Chou and Foster, Matthew S.

Subjects

*WAVE functions, *DIRAC function, *FERMIONS, *TRANSITION metals, *MATHEMATICAL functions

Abstract

We numerically investigate critically delocalized wave functions in models of two-dimensional Dirac fermions, subject to vector potential disorder. These describe the surface states of three-dimensional topological superconductors, and can also be realized through long-range correlated bond randomness in artificial materials like molecular graphene. A "frozen" regime can occur for strong disorder in these systems, wherein a single wave function presents a few localized peaks separated by macroscopic distances. Despite this rarefied spatial structure, we find robust correlations between eigenstates at different energies, at both weak and strong disorder. The associated level statistics are always approximately Wigner-Dyson. The system shows generalized Chalker (quantum critical) scaling, even when individual states are quasilocalized in space. We confirm analytical predictions for the density of states and multifractal spectra. For a single Dirac valley, we establish that finite energy states show universal multifractal spectra consistent with the integer quantum Hall plateau transition. A single Dirac fermion at finite energy can therefore behave as a "Quantum Hall critical metal." For the case of two valleys and non-Abelian disorder, we verify predictions of conformal field theory. Our results for the non-Abelian case imply that both delocalization and conformal invariance are topologically protected for multivalley topological superconductor surface states. [ABSTRACT FROM AUTHOR]

Published

2014

7. Topological protection, disorder, and interactions: Survival at the surface of three-dimensional topological superconductors.

Author

Foster, Matthew S., Hong-Yi Xie, and Yang-Zhi Chou

Subjects

*SUPERCONDUCTORS, *MULTIFRACTALS, *WAVE functions, *SIGMA particles, *DIRAC equation

Abstract

We consider the interplay of disorder and interactions upon the gapless surface states of 3D topological superconductors. The combination of topology and superconducting order inverts the action of time-reversal symmetry, so that extrinsic time-reversal invariant surface perturbations appear only as "seudomagnetic" fields (Abelian and non-Abelian vector potentials, which couple to spin and valley currents). The main effect of disorder is to induce multifractal scaling in surface state wave functions. These critically delocalized, yet strongly inhomogeneous states renormalize interaction matrix elements relative to the clean system. We compute the enhancement or suppression of interaction scaling dimensions due to the disorder exactly, using conformal field theory. We determine the conditions under which interactions remain irrelevant in the presence of disorder for symmetry classes AIII and DIII. In the limit of large topological winding numbers (many surface valleys), we show that the effective field theory takes the form of a Finkel'stein nonlinear sigma model, augmented by the Wess-Zumino-Novikov-Witten term. The sigma model incorporates interaction effects to all orders and provides a framework for a controlled perturbative expansion; the inverse spin or thermal conductance is the small parameter. For class DIII, we show that interactions are always irrelevant, while in class AIII, there is a finite window of stability, controlled by the disorder. Outside of this window, we identify new interaction-stabilized fixed points. [ABSTRACT FROM AUTHOR]

Published

2014

8. Quantum quench in a p + ip superfluid: Winding numbers and topological states.

Author

Foster, Matthew S., Dzero, Maxim, Gurarie, Victor, and Yuzbashyan, A.

Subjects

*QUANTUM mechanics, *SUPERFLUIDITY, *COUPLING constants, *SUPERCONDUCTORS, *P-waves (Seismology), *HAMILTONIAN mechanics

Abstract

We study the nonadiabatic dynamics of a two-dimensional p + ip superfluid following an instantaneous quantum quench of the BCS coupling constant. The model describes a topological superconductor with a nontrivial BCS (trivial BEC) phase appearing at weak- (strong-) coupling strengths. We extract the exact long-time asymptotics of the order parameter Δ(t) by exploiting the integrability of the classical p-wave Hamiltonian, which we establish via a Lax construction. Three different types of asymptotic behavior can occur depending upon the strength and direction of the interaction quench. We refer to these as the nonequilibrium phases {I, II, III}, characterized as follows. In phase I, the order parameter asymptotes to zero due to dephasing. In phase n, Δ →Δ A∝, a nonzero constant. Phase III is characterized by persistent oscillations of Δ(t ). For quenches within phases I and II, we determine the topological character of the asymptotic states. We show that two different formulations of the bulk topological winding number, although equivalent in the BCS or BEC ground states, must be regarded as independent out of equilibrium. The first winding number Q characterizes the Anderson pseudospin texture of the initial state; we show that Q is generically conserved. For Q ≠ 0, this leads to the prediction of a "gapless topological" state when A asymptotes to zero. The presence or absence of Majorana edge modes in a sample with a boundary is encoded in the second winding number W, which is formulated in terms of the retarded Green's function. We establish that W can change following a quench across the quantum critical point. When the order parameter asymptotes to a nonzero constant, the final value of W is well defined and quantized. We discuss the implications for the (dis)appearance of Majorana edge modes. Finally, we show that the parity of zeros in the bulk out-of-equilibrium Cooper-pair distribution function constitutes a Z2-valued quantum number, which is nonzero whenever W ≠ Q. The pair distribution can in principle be measured using rf spectroscopy in an ultracold-atom realization, allowing direct experimental detection of the Z2 number. This has the following interesting implication: topological information that is experimentally inaccessible in the bulk ground state can be transferred to an observable distribution function when the system is driven far from equilibrium. [ABSTRACT FROM AUTHOR]

Published

2013

9. Interaction-Mediated Surface-State Instability in Disordered Three-Dimensional Topological Superconductors with Spin SU(2) Symmetry.

Author

Foster, Matthew S. and Yuzbashyan, Emil A.

Subjects

*SURFACES (Physics), *SUPERCONDUCTORS, *WAVE functions, *TIME reversal, *SYMMETRY (Physics), *HALL effect, *QUANTUM theory

Abstract

We show that arbitrarily weak interparticle interactions destabilize the surface states of 3D topological superconductors with spin SU(2) invariance (symmetry class CI) in the presence of nonmagnetic disorder. The conduit for the instability is disorder-induced wave function multifractality. We argue that time-reversal symmetry breaks spontaneously at the surface, so that topologically protected states do not exist for this class. The interaction-stabilized surface phase is expected to exhibit ferromagnetic order, or to reside in an insulating plateau of the spin quantum Hall effect. [ABSTRACT FROM AUTHOR]

Published

2012

10. Multifractal nature of the surface local density of states in three-dimensional topological insulators with magnetic and nonmagnetic disorder.

Author

Foster, Matthew S.

Subjects

*FERMIONS, *METAL-insulator transitions, *MAGNETISM, *SCANNING tunneling microscopy, *SPECTRUM analysis, *METAL inclusions, *SURFACES (Physics)

Abstract

We compute the multifractal spectra associated to local density of states (LDOS) fluctuations due to weak quenched disorder for a single Dirac fermion in two spatial dimensions. Our results are relevant to the surfaces of Z2 topological insulators such as Bi2Se3 and Bi2Te3, where LDOS modulations can be directly probed via scanning tunneling microscopy. We find a qualitative difference in spectra obtained for magnetic versus nonmagnetic disorder. Randomly polarized magnetic impurities induce quadratic multifractalilv at first order in the impurity density: by contrast, no operator exhibits multifractal scaling at this order for a nonmagnetic impurity profile. For the time-reversal invariant case, we compute the first nontrivial multifractal correction, which appears at two loops (impurity density squared). We discuss spectral enhancement approaching the Dirac point due to renormalization. and we survey known results for the opposite limit of strong disorder. [ABSTRACT FROM AUTHOR]

Published

2012

11. Quantum quench spectroscopy of a Luttinger liquid: Ultrarelativistic density wave dynamics due to fractionalization in an XXZ chain.

Author

Foster, Matthew S., Berkelbach, Timothy C., Reichman, David R., and Yuzbashyan, Emil A.

Subjects

*QUANTUM theory, *SPECTRUM analysis, *RENORMALIZATION (Physics), *LUTTINGER liquids, *HAMILTONIAN systems, *WAVELENGTHS

Abstract

We compute the dynamics of localized excitations produced by a quantum quench in the spin-1/2 XXZ chain. Using numerics combining the density-matrix renormalization group and exact time evolution, as well as analytical arguments, we show that fractionalization due to interactions in the prequench state gives rise to "ultrarelativistic" density waves that travel at the maximum band velocity. The system is initially prepared in the ground state of the chain within the gapless XY phase, which admits a Luttinger liquid (LL) description at low energies and long wavelengths. The Hamiltonian is then suddenly quenched to a band insulator, after which the chain evolves unitarily. Through the gapped dispersion of the insulator spectrum, the postquench dynamics serve as a "velocity microscope," revealing initial-state particle correlations via space-time density propagation. We show that the ultrarelativistic wave production is tied to the particular way in which fractionalization evades Pauli blocking in the zero-temperature initial LL state. [ABSTRACT FROM AUTHOR]

Published

2011

12. Dissipative Hot-Spot-Enabled Shock and Bounce Dynamics via Terahertz Quantum Quenches in Helical Edge States.

Author

Xinghai Zhang and Foster, Matthew S.

Subjects

*SHOCK waves, *SUBMILLIMETER waves, *SECOND harmonic generation, *TOPOLOGICAL insulators, *INELASTIC scattering

Abstract

We study quantum quenches of helical liquids with spin-flip inelastic scattering. Counterpropagating charge packets in helical edges can be created by an ultrashort electric pulse applied across a 2D topological insulator. Localized "hot spots" that form due to scattering enable two types of strongly nonlinear wave dynamics. First, propagating packets develop self-focusing shock fronts. Second, colliding packets with opposite charge can exhibit near-perfect retroreflection, despite strong dissipation. This leads to frequency doubling that could be detected experimentally from emitted terahertz radiation. [ABSTRACT FROM AUTHOR]

Published

2021

13. Fractionalization Waves in Two-Dimensional Dirac Fermions: Quantum Imprint from One Dimension.

Author

Davis, Seth M. and Foster, Matthew S.

Subjects

*FERMIONS, *LUTTINGER liquids, *DISPERSION (Chemistry)

Abstract

Particle fractionalization is believed to orchestrate the physics of many strongly correlated systems, yet its direct experimental detection remains a challenge. We propose a simple measurement for an ultracold matter system, in which correlations in initially decoupled 1D chains are imprinted via quantum quench upon two-dimensional Dirac fermions. Luttinger liquid correlations launch relativistic "fractionalization waves" along the chains, while coupling noninteracting chains induces perpendicular dispersion. These could be easily distinguished in an ultracold gas experiment. [ABSTRACT FROM AUTHOR]

Published

2019

14. Dephasing Catastrophe in 4-ε Dimensions: A Possible Instability of the Ergodic (Many-Body-Delocalized) Phase.

Author

Yunxiang Liao and Foster, Matthew S.

Subjects

*ANDERSON localization, *ENERGY density, *FERMIONS

Abstract

In two dimensions, dephasing by a bath cuts off Anderson localization that would otherwise occur at any energy density for fermions with disorder. For an isolated system with short-range interactions, the system can be its own bath, exhibiting diffusive (non-Markovian) thermal density fluctuations. We recast the dephasing of weak localization due to a diffusive bath as a self-interacting polymer loop. We investigate the critical behavior of the loop in d=4-ε dimensions, and find a nontrivial fixed point corresponding to a temperature T*∼ε>0 where the dephasing time diverges. Assuming that this fixed point survives to ε=2, we associate it with a possible instability of the ergodic phase. Our approach may open a new line of attack against the problem of the ergodic to many-body-localized phase transition in d>1 spatial dimensions. [ABSTRACT FROM AUTHOR]

Published

2018

15. Transport coefficients of graphene: Interplay of impurity scattering, Coulomb interaction, and optical phonons.

Author

Hong-Yi Xie and Foster, Matthew S.

Subjects

*PHONONS, *ELECTRIC conductivity, *GRAPHENE

Abstract

We study the electric and thermal transport of the Dirac carriers in monolayer graphene using the Boltzmann-equation approach. Motivated by recent thermopower measurements [F. Ghahari, H.-Y. Xie, T. Taniguchi, K. Watanabe, M. S. Foster, and P. Kim, Phys. Rev. Lett. 116, 136802 (2016)], we consider the effects of quenched disorder, Coulomb interactions, and electron-optical-phonon scattering. Via an unbiased numerical solution to the Boltzmann equation we calculate the electrical conductivity, thermopower, and electronic component of the thermal conductivity, and discuss the validity of Mott's formula and of the Wiedemann-Franz law. An analytical solution for the disorder-only case shows that screened Coulomb impurity scattering, although elastic, violates the Wiedemann-Franz law even at low temperature. For the combination of carrier-carrier Coulomb and short-ranged impurity scattering, we observe the crossover from the interaction-limited (hydrodynamic) regime to the disorder-limited (Fermi-liquid) regime. In the former, the thermopower and the thermal conductivity follow the results anticipated by the relativistic hydrodynamic theory. On the other hand, we find that optical phonons become non-negligible at relatively low temperatures and that the induced electron thermopower violates Mott's formula. Combining all of these scattering mechanisms, we obtain the thermopower that quantitatively coincides with the experimental data. [ABSTRACT FROM AUTHOR]

Published

2016

16. Helical Quantum Edge Gears in 2D Topological Insulators.

Author

Yang-Zhi Chou, Levchenko, Alex, and Foster, Matthew S.

Subjects

*QUANTUM theory, *HELICAL waveguides, *TOPOLOGICAL insulators, *SPIN-orbit interactions, *SCATTERING (Physics)

Abstract

We show that two-terminal transport can measure the Luttinger liquid (LL) parameter K, in helical LLs at the edges of two-dimensional topological insulators (TIs) with Rashba spin-orbit coupling. We consider a Coulomb drag geometry with two coplanar TIs and short-ranged spin-flip interedge scattering. Current injected into one edge loop induces circulation in the second, which floats without leads. In the low-temperature (T → 0) perfect drag regime, the conductance is (e2/h)(2K + 1)/(K + 1). At higher T, we predict a conductivity ∼T-4K+3. The conductivity for a single edge is also computed. [ABSTRACT FROM AUTHOR]

Published

2015

17. Surface transport coefficients for three-dimensional topological superconductors.

Author

Hong-Yi Xie, Yang-Zhi Chou, and Foster, Matthew S.

Subjects

*SUPERCONDUCTORS, *TRANSPORT theory, *NUCLEAR spin, *THERMAL conductivity, *SUPERCONDUCTIVITY

Abstract

We argue that surface spin and thermal conductivities of three-dimensional topological superconductors are universal and topologically quantized at low temperature. For a bulk winding number ν, there are [ABSTRACT FROM AUTHOR]

Published

2015

18. Critical Percolation without Fine-Tuning on the Surface of a Topological Superconductor.

Author

Ghorashi, Sayed Ali Akbar, Yunxiang Liao, and Foster, Matthew S.

Subjects

*TOPOLOGY, *SUPERCONDUCTORS, *QUANTUM transitions

Abstract

We present numerical evidence that most two-dimensional surface states of a bulk topological superconductor (TSC) sit at an integer quantum Hall plateau transition. We study TSC surface states in class CI with quenched disorder. Low-energy (finite-energy) surface states were expected to be critically delocalized (Anderson localized). We confirm the low-energy picture, but find instead that finite-energy states are also delocalized, with universal statistics that are independent of the TSC winding number, and consistent with the spin quantum Hall plateau transition (percolation). [ABSTRACT FROM AUTHOR]

Published

2018

19. Disorder-enhanced topological protection and universal quantum criticality in a spin-3/2 topological superconductor.

Author

Ghorashi, Sayed Ali Akbar, Davis, Seth, and Foster, Matthew S.

Subjects

*SUPERCONDUCTORS, *TOPOLOGY, *QUANTUM mechanics

Abstract

We study the Majorana surface states of higher-spin topological superconductors (TSCs) that could be realized in ultracold atomic systems or doped semimetals with spin-orbit coupling. As a paradigmatic example, we consider a model with p-wave pairing of spin-3/2 fermions that generalizes ³He-B. This model has coexisting linear and cubic dispersing Majorana surface bands. We show that these are unstable to interactions, which can generate a spontaneous surface thermal quantum Hall effect (TQHE). By contrast, nonmagnetic quenched disorder induces a surface conformal field theory (CFT) that is stable against weak interactions: topological protection is enhanced by disorder. Gapless surface states of higher-spin TSCs could therefore be robustly realized in solid-state systems, where disorder is inevitable. The surface CFT is characterized by universal signatures that depend only on the bulk topological winding number, and they include power-law scaling of the density of states, a universal multifractal spectrum of local density of states fluctuations, and a quantized ratio of the longitudinal thermal conductivity kxx divided by temperature T. By contrast, kxx/T for the clean surface without TQHE order would diverge as T→0. Since disorder stabilizes the conducting Majorana surface fluid and quantizes thermal transport, our results suggest a close analogy between bulk TSCs and the integer quantum Hall effect. [ABSTRACT FROM AUTHOR]

Published

2017

20. Twisting Anderson pseudospins with light: Quench dynamics in terahertz-pumped BCS superconductors.

Author

Yang-Zhi Chou, Yunxiang Liao, and Foster, Matthew S.

Subjects

*DYNAMICS, *BCS theory (Superconductivity), *OPTICAL conductivity

Abstract

We study the preparation (pump) and the detection (probe) of far-from-equilibrium BCS superconductor dynamics in THz pump-probe experiments. In a recent experiment [R. Matsunaga, Y. I. Hamada, K. Makise, Y. Uzawa, H. Terai, Z. Wang, and R. Shimano, Phys. Rev. Lett. 111, 057002 (2013)], an intense monocycle THz pulse with center frequency ω≃Δ was injected into a superconductor with BCS gap Δ; the subsequent postpump evolution was detected via the optical conductivity. It was argued that nonlinear coupling of the pump to the Anderson pseudospins of the superconductor induces coherent dynamics of the Higgs (amplitude) mode Δ(t). We validate this picture in a two-dimensional BCS model with a combination of exact numerics and the Lax reduction method, and we compute the nonequilibrium phase diagram as a function of the pump intensity. The main effect of the pump is to scramble the orientations of Anderson pseudospins along the Fermi surface by twisting them in the xy plane. We show that more intense pump pulses can induce a far-from-equilibrium phase of gapless superconductivity ("phase I"), originally predicted in the context of interaction quenches in ultracold atoms. We show that the THz pump method can reach phase I at much lower energy densities than an interaction quench, and we demonstrate that Lax reduction (tied to the integrability of the BCS Hamiltonian) provides a general quantitative tool for computing coherent BCS dynamics. We also calculate the Mattis-Bardeen optical conductivity for the nonequilibrium states discussed here. [ABSTRACT FROM AUTHOR]

Published

2017

21. Power-Law Temperature Dependence of the Penetration Depth in a Topological Superconductor Due to Surface States.

Author

Tsz Chun Wu, Pal, Hridis K., Hosur, Pavan, and Foster, Matthew S.

Subjects

*PENETRATION depth (Superconductors), *SURFACE states, *SUPERCONDUCTIVITY, *TEMPERATURE, *SUPERCONDUCTORS

Abstract

We study the temperature dependence of the magnetic penetration depth in a 3D topological superconductor (TSC), incorporating the paramagnetic current due to the surface states. A TSC is predicted to host a gapless 2D surface Majorana fluid. In addition to the bulk-dominated London response, we identify a T³ power-law-in-temperature contribution from the surface, valid in the low-temperature limit. Our system is fully gapped in the bulk, and should be compared to bulk nodal superconductivity, which also exhibits power-law behavior. Power-law temperature dependence of the penetration depth can be one indicator of topological superconductivity. [ABSTRACT FROM AUTHOR]

Published

2020

22. Enhanced Thermoelectric Power in Graphene: Violation of the Mott Relation by Inelastic Scattering.

Author

Ghahari, Fereshte, Hong-Yi Xie, Takashi Taniguchi, Kenji Watanabe, Foster, Matthew S., and Kim, Philip

Subjects

*THERMOELECTRIC power, *INELASTIC scattering, *BOLTZMANN'S H-theorem (Statistical physics)

Abstract

We report the enhancement of the thermoelectric power (TEP) in graphene with extremely low disorder. At high temperature we observe that the TEP is substantially larger than the prediction of the Mott relation, approaching to the hydrodynamic limit due to strong inelastic scattering among the charge carriers. However, closer to room temperature the inelastic carrier-optical-phonon scattering becomes more significant and limits the TEP below the hydrodynamic prediction. We support our observation by employing a Boltzmann theory incorporating disorder, electron interactions, and optical phonons. [ABSTRACT FROM AUTHOR]

Published

2016

23. Topological Protection from Random Rashba Spin-Orbit Backscattering: Ballistic Transport in a Helical Luttinger Liquid.

Author

Hong-Yi Xie, Heqiu Li, Yang-Zhi Chou, and Foster, Matthew S.

Subjects

*RASHBA effect, *SPIN-orbit interactions, *LUTTINGER liquids

Abstract

The combination of Rashba spin-orbit coupling and potential disorder induces a random current operator for the edge states of a 2D topological insulator. We prove that charge transport through such an edge is ballistic at any temperature, with or without Luttinger liquid interactions. The solution exploits a mapping to a spin 1/2 in a time-dependent field that preserves the projection along one randomly undulating component (integrable dynamics). Our result is exact and rules out random Rashba backscattering as a source of temperature-dependent transport, absent integrability-breaking terms. [ABSTRACT FROM AUTHOR]

Published

2016