Search

Your search keyword '"Berg, Erez"' showing total 70 results
Start Over Author "Berg, Erez" Database OAIster
70 results on '"Berg, Erez"'

1. Universal transport in periodically driven systems without long-lived quasiparticles

Author

Esin, Iliya, Kuhlenkamp, Clemens, Refael, Gil, Berg, Erez, Rudner, Mark S., Lindner, Netanel H., Esin, Iliya, Kuhlenkamp, Clemens, Refael, Gil, Berg, Erez, Rudner, Mark S., and Lindner, Netanel H.

Abstract

An intriguing regime of universal charge transport at high entropy density has been proposed for periodically driven interacting one-dimensional systems with Bloch bands separated by a large single-particle band gap. For weak interactions, a simple picture based on well-defined Floquet quasiparticles suggests that the system should host a quasisteady state current that depends only on the populations of the system's Floquet-Bloch bands and their associated quasienergy winding numbers. Here we show that such topological transport persists into the strongly interacting regime where the single-particle lifetime becomes shorter than the drive period. Analytically, we show that the value of the current is insensitive to interaction-induced band renormalizations and lifetime broadening when certain conditions are met by the system's non-equilibrium distribution function. We show that these conditions correspond to a quasisteady state. We support these predictions through numerical simulation of a system of strongly interacting fermions in a periodically-modulated chain of Sachdev-Ye-Kitaev dots. Our work establishes universal transport at high entropy density as a robust far from equilibrium topological phenomenon, which can be readily realized with cold atoms in optical lattices., Comment: 7 pages, 4 figures + appendices

Published
2022

2. Universal transport in periodically driven systems without long-lived quasiparticles

Author

Esin, Iliya, Kuhlenkamp, Clemens, Refael, Gil, Berg, Erez, Rudner, Mark S., Lindner, Netanel H., Esin, Iliya, Kuhlenkamp, Clemens, Refael, Gil, Berg, Erez, Rudner, Mark S., and Lindner, Netanel H.

Abstract

An intriguing regime of universal charge transport at high entropy density has been proposed for periodically driven interacting one-dimensional systems with Bloch bands separated by a large single-particle band gap. For weak interactions, a simple picture based on well-defined Floquet quasiparticles suggests that the system should host a quasisteady state current that depends only on the populations of the system's Floquet-Bloch bands and their associated quasienergy winding numbers. Here we show that such topological transport persists into the strongly interacting regime where the single-particle lifetime becomes shorter than the drive period. Analytically, we show that the value of the current is insensitive to interaction-induced band renormalizations and lifetime broadening when certain conditions are met by the system's non-equilibrium distribution function. We show that these conditions correspond to a quasisteady state. We support these predictions through numerical simulation of a system of strongly interacting fermions in a periodically-modulated chain of Sachdev-Ye-Kitaev dots. Our work establishes universal transport at high entropy density as a robust far from equilibrium topological phenomenon, which can be readily realized with cold atoms in optical lattices., Comment: 7 pages, 4 figures + appendices

Published
2022

3. Universal transport in periodically driven systems without long-lived quasiparticles

Author

Esin, Iliya, Kuhlenkamp, Clemens, Refael, Gil, Berg, Erez, Rudner, Mark S., Lindner, Netanel H., Esin, Iliya, Kuhlenkamp, Clemens, Refael, Gil, Berg, Erez, Rudner, Mark S., and Lindner, Netanel H.

Abstract

An intriguing regime of universal charge transport at high entropy density has been proposed for periodically driven interacting one-dimensional systems with Bloch bands separated by a large single-particle band gap. For weak interactions, a simple picture based on well-defined Floquet quasiparticles suggests that the system should host a quasisteady state current that depends only on the populations of the system's Floquet-Bloch bands and their associated quasienergy winding numbers. Here we show that such topological transport persists into the strongly interacting regime where the single-particle lifetime becomes shorter than the drive period. Analytically, we show that the value of the current is insensitive to interaction-induced band renormalizations and lifetime broadening when certain conditions are met by the system's non-equilibrium distribution function. We show that these conditions correspond to a quasisteady state. We support these predictions through numerical simulation of a system of strongly interacting fermions in a periodically-modulated chain of Sachdev-Ye-Kitaev dots. Our work establishes universal transport at high entropy density as a robust far from equilibrium topological phenomenon, which can be readily realized with cold atoms in optical lattices.

Published
2022

4. Inter-valley coherent order and isospin fluctuation mediated superconductivity in rhombohedral trilayer graphene.

Author

Chatterjee, Shubhayu, Chatterjee, Shubhayu, Wang, Taige, Berg, Erez, Zaletel, Michael P, Chatterjee, Shubhayu, Chatterjee, Shubhayu, Wang, Taige, Berg, Erez, and Zaletel, Michael P

Abstract

Superconductivity was recently discovered in rhombohedral trilayer graphene (RTG) in the absence of a moiré potential. Superconductivity is observed proximate to a metallic state with reduced isospin symmetry, but it remains unknown whether this is a coincidence or a key ingredient for superconductivity. Using a Hartree-Fock analysis and constraints from experiments, we argue that the symmetry breaking is inter-valley coherent (IVC) in nature. We evaluate IVC fluctuations as a possible pairing glue, and find that they lead to chiral unconventional superconductivity when the fluctuations are strong. We further elucidate how the inter-valley Hund's coupling determines the spin-structure of the IVC ground state and breaks the degeneracy between spin-singlet and triplet superconductivity. Remarkably, if the normal state is spin-unpolarized, we find that a ferromagnetic Hund's coupling favors spin-singlet superconductivity, in agreement with experiments. Instead, if the normal state is spin-polarized, then IVC fluctuations lead to spin-triplet pairing.

Published
2022

5. Stability of Floquet Majorana Box Qubits

Author

Matthies, Anne, Park, Jinhong, Berg, Erez, Rosch, Achim, Matthies, Anne, Park, Jinhong, Berg, Erez, and Rosch, Achim

Abstract

In one-dimensional topological superconductors driven periodically with the frequency omega, two types of topological edge modes may appear, the well-known Majorana zero mode and a Floquet Majorana mode located at the quasienergy PLANCK CONSTANT OVER TWO PI omega/2. We investigate two Josephson-coupled topological quantum wires in the presence of Coulomb interactions, forming a so-called Majorana box qubit. An oscillating gate voltage can induce Floquet Majorana modes in both wires. This allows for the encoding of three qubits in a sector with fixed electron parity. If such a system is prepared by increasing the amplitude of oscillations adiabatically, it is inherently unstable as interactions resonantly create quasiparticles. This can be avoided by using instead a protocol where the oscillation frequency is increased slowly. In this case, one can find a parameter regime where the system remains stable.

Published
2022

6. Prethermalization and entanglement dynamics in interacting topological pumps

Author

Gawatz, Raffael, Balram, Ajit C., Berg, Erez, Lindner, Netanel H., Rudner, Mark S., Gawatz, Raffael, Balram, Ajit C., Berg, Erez, Lindner, Netanel H., and Rudner, Mark S.

Abstract

We investigate the formation of quasisteady states in one-dimensional pumps of interacting fermions at noninteger filling fraction, in the regime where the driving frequency and the interaction strength are small compared to the instantaneous single-particle band gap throughout the driving cycle. The system rapidly absorbs energy from the driving field and approaches a quasisteady state that locally resembles a maximal entropy state subject to the constraint of a fixed particle number in each of the system's single-particle Floquet bands. We explore the nature of this quasisteady state through one-body observables including the pumped current and natural orbital occupations, as well as the (many-body) entanglement spectrum and entropy. Potential disorder significantly reduces the amplitude of fluctuations of the quasisteady-state current around its universal value, while the lifetime of the quasisteady state remains nearly unaffected for disorder strengths up to the scale of the single-particle band gap. Interestingly, the natural orbital occupations and the entanglement entropy display patterns signifying the periodic entangling and disentangling of the system's degrees of freedom over each driving cycle. Moreover, prominent features in the system's time-dependent entanglement spectrum reveal the emergence of long timescales associated with the equilibration of many-particle correlations., We investigate the formation of quasisteady states in one-dimensional pumps of interacting fermions at noninteger filling fraction, in the regime where the driving frequency and the interaction strength are small compared to the instantaneous single-particle band gap throughout the driving cycle. The system rapidly absorbs energy from the driving field and approaches a quasisteady state that locally resembles a maximal entropy state subject to the constraint of a fixed particle number in each of the system's single-particle Floquet bands. We explore the nature of this quasisteady state through one-body observables including the pumped current and natural orbital occupations, as well as the (many-body) entanglement spectrum and entropy. Potential disorder significantly reduces the amplitude of fluctuations of the quasisteady-state current around its universal value, while the lifetime of the quasisteady state remains nearly unaffected for disorder strengths up to the scale of the single-particle band gap. Interestingly, the natural orbital occupations and the entanglement entropy display patterns signifying the periodic entangling and disentangling of the system's degrees of freedom over each driving cycle. Moreover, prominent features in the system's time-dependent entanglement spectrum reveal the emergence of long timescales associated with the equilibration of many-particle correlations.

Published
2022

7. Proposal for realizing anomalous Floquet insulators via Chern band annihilation

Author

Zhang, Carolyn, Holder, Tobias, Lindner, Netanel H., Rudner, Mark S., Berg, Erez, Zhang, Carolyn, Holder, Tobias, Lindner, Netanel H., Rudner, Mark S., and Berg, Erez

Abstract

Two-dimensional periodically driven systems can host an unconventional topological phase unattainable for equilibrium systems, termed the Anomalous Floquet-Anderson insulator (AFAI). The AFAI features a quasi-energy spectrum with chiral edge modes and a fully localized bulk, leading to non-adiabatic but quantized charge pumping. Here, we show how such a Floquet phase can be realized in a driven, disordered Quantum Anomalous Hall insulator, which is assumed to have two critical energies where the localization length diverges, carrying states with opposite Chern numbers. Driving the system at a frequency close to resonance between these two energies localizes the critical states and annihilates the Chern bands, giving rise to an AFAI phase. We exemplify this principle by studying a model for a driven, magnetically doped topological insulator film, where the annihilation of the Chern bands and the formation of the AFAI phase is demonstrated using the rotating wave approximation. This is complemented by a scaling analysis of the localization length for two copies of a quantum Hall network model with a tunable coupling between them. We find that by tuning the frequency of the driving close to resonance, the driving strength required to stabilize the AFAI phase can be made arbitrarily small.

Published
2022

8. Correlated insulating states in carbon nanotubes controlled by magnetic field

Author

Voliovich, Assaf, Rudner, Mark S., Oreg, Yuval, Berg, Erez, Voliovich, Assaf, Rudner, Mark S., Oreg, Yuval, and Berg, Erez

Abstract

We investigate competing insulating phases in nearly metallic zigzag carbon nanotubes, under conditions where an applied magnetic flux approximately closes the single-particle gap in one valley. Recent experiments have shown that an energy gap persists throughout magnetic field sweeps where the single-particle picture predicts that the gap should close and reopen. Using a bosonic low-energy effective theory to describe the interplay between electron-electron interactions, spin-orbit coupling, and magnetic field, we obtain a phase diagram consisting of several competing insulating phases that can form in the vicinity of the single-particle gap closing point. We characterize these phases in terms of spin-resolved charge polarization densities, each of which can independently take one of two possible values consistent with the mirror symmetry of the system, or can take an intermediate value through a spontaneous mirror symmetry breaking transition. In the mirror symmetry breaking phase, adiabatic changes of the orbital magnetic flux drive charge and spin currents along the nanotube. We discuss the relevance of these results to recent and future experiments.

Published
2022

9. Prethermalization and entanglement dynamics in interacting topological pumps

Author

Gawatz, Raffael, Balram, Ajit C., Berg, Erez, Lindner, Netanel H., Rudner, Mark S., Gawatz, Raffael, Balram, Ajit C., Berg, Erez, Lindner, Netanel H., and Rudner, Mark S.

Abstract

We investigate the formation of quasisteady states in one-dimensional pumps of interacting fermions at noninteger filling fraction, in the regime where the driving frequency and the interaction strength are small compared to the instantaneous single-particle band gap throughout the driving cycle. The system rapidly absorbs energy from the driving field and approaches a quasisteady state that locally resembles a maximal entropy state subject to the constraint of a fixed particle number in each of the system's single-particle Floquet bands. We explore the nature of this quasisteady state through one-body observables including the pumped current and natural orbital occupations, as well as the (many-body) entanglement spectrum and entropy. Potential disorder significantly reduces the amplitude of fluctuations of the quasisteady-state current around its universal value, while the lifetime of the quasisteady state remains nearly unaffected for disorder strengths up to the scale of the single-particle band gap. Interestingly, the natural orbital occupations and the entanglement entropy display patterns signifying the periodic entangling and disentangling of the system's degrees of freedom over each driving cycle. Moreover, prominent features in the system's time-dependent entanglement spectrum reveal the emergence of long timescales associated with the equilibration of many-particle correlations., We investigate the formation of quasisteady states in one-dimensional pumps of interacting fermions at noninteger filling fraction, in the regime where the driving frequency and the interaction strength are small compared to the instantaneous single-particle band gap throughout the driving cycle. The system rapidly absorbs energy from the driving field and approaches a quasisteady state that locally resembles a maximal entropy state subject to the constraint of a fixed particle number in each of the system's single-particle Floquet bands. We explore the nature of this quasisteady state through one-body observables including the pumped current and natural orbital occupations, as well as the (many-body) entanglement spectrum and entropy. Potential disorder significantly reduces the amplitude of fluctuations of the quasisteady-state current around its universal value, while the lifetime of the quasisteady state remains nearly unaffected for disorder strengths up to the scale of the single-particle band gap. Interestingly, the natural orbital occupations and the entanglement entropy display patterns signifying the periodic entangling and disentangling of the system's degrees of freedom over each driving cycle. Moreover, prominent features in the system's time-dependent entanglement spectrum reveal the emergence of long timescales associated with the equilibration of many-particle correlations.

Published
2022

10. Proposal for realizing anomalous Floquet insulators via Chern band annihilation

Author

Zhang, Carolyn, Holder, Tobias, Lindner, Netanel H., Rudner, Mark S., Berg, Erez, Zhang, Carolyn, Holder, Tobias, Lindner, Netanel H., Rudner, Mark S., and Berg, Erez

Abstract

Two-dimensional periodically driven systems can host an unconventional topological phase unattainable for equilibrium systems, termed the Anomalous Floquet-Anderson insulator (AFAI). The AFAI features a quasi-energy spectrum with chiral edge modes and a fully localized bulk, leading to non-adiabatic but quantized charge pumping. Here, we show how such a Floquet phase can be realized in a driven, disordered Quantum Anomalous Hall insulator, which is assumed to have two critical energies where the localization length diverges, carrying states with opposite Chern numbers. Driving the system at a frequency close to resonance between these two energies localizes the critical states and annihilates the Chern bands, giving rise to an AFAI phase. We exemplify this principle by studying a model for a driven, magnetically doped topological insulator film, where the annihilation of the Chern bands and the formation of the AFAI phase is demonstrated using the rotating wave approximation. This is complemented by a scaling analysis of the localization length for two copies of a quantum Hall network model with a tunable coupling between them. We find that by tuning the frequency of the driving close to resonance, the driving strength required to stabilize the AFAI phase can be made arbitrarily small.

Published
2022

11. Entropic evidence for a Pomeranchuk effect in magic-angle graphene

Author

Massachusetts Institute of Technology. Department of Physics, Rozen, Asaf, Park, Jeong Min, Zondiner, Uri, Cao, Yuan, Rodan-Legrain, Daniel, Taniguchi, Takashi, Watanabe, Kenji, Oreg, Yuval, Stern, Ady, Berg, Erez, Jarillo-Herrero, Pablo, Ilani, Shahal, Massachusetts Institute of Technology. Department of Physics, Rozen, Asaf, Park, Jeong Min, Zondiner, Uri, Cao, Yuan, Rodan-Legrain, Daniel, Taniguchi, Takashi, Watanabe, Kenji, Oreg, Yuval, Stern, Ady, Berg, Erez, Jarillo-Herrero, Pablo, and Ilani, Shahal

Abstract

In the 1950s, Pomeranchuk1 predicted that, counterintuitively, liquid 3He may solidify on heating. This effect arises owing to high excess nuclear spin entropy in the solid phase, where the atoms are spatially localized. Here we find that an analogous effect occurs in magic-angle twisted bilayer graphene2-6. Using both local and global electronic entropy measurements, we show that near a filling of one electron per moiré unit cell, there is a marked increase in the electronic entropy to about 1kB per unit cell (kB is the Boltzmann constant). This large excess entropy is quenched by an in-plane magnetic field, pointing to its magnetic origin. A sharp drop in the compressibility as a function of the electron density, associated with a reset of the Fermi level back to the vicinity of the Dirac point, marks a clear boundary between two phases. We map this jump as a function of electron density, temperature and magnetic field. This reveals a phase diagram that is consistent with a Pomeranchuk-like temperature- and field-driven transition from a low-entropy electronic liquid to a high-entropy correlated state with nearly free magnetic moments. The correlated state features an unusual combination of seemingly contradictory properties, some associated with itinerant electrons-such as the absence of a thermodynamic gap, metallicity and a Dirac-like compressibility-and others associated with localized moments, such as a large entropy and its disappearance under a magnetic field. Moreover, the energy scales characterizing these two sets of properties are very different: whereas the compressibility jump has an onset at a temperature of about 30 kelvin, the bandwidth of magnetic excitations is about 3 kelvin or smaller. The hybrid nature of the present correlated state and the large separation of energy scales have implications for the thermodynamic and transport properties of the correlated states in twisted bilayer graphene.

Published
2022

12. Correlated insulating states in carbon nanotubes controlled by magnetic field

Author

Voliovich, Assaf, Rudner, Mark S., Oreg, Yuval, Berg, Erez, Voliovich, Assaf, Rudner, Mark S., Oreg, Yuval, and Berg, Erez

Abstract

We investigate competing insulating phases in nearly metallic zigzag carbon nanotubes, under conditions where an applied magnetic flux approximately closes the single-particle gap in one valley. Recent experiments have shown that an energy gap persists throughout magnetic field sweeps where the single-particle picture predicts that the gap should close and reopen. Using a bosonic low-energy effective theory to describe the interplay between electron-electron interactions, spin-orbit coupling, and magnetic field, we obtain a phase diagram consisting of several competing insulating phases that can form in the vicinity of the single-particle gap closing point. We characterize these phases in terms of spin-resolved charge polarization densities, each of which can independently take one of two possible values consistent with the mirror symmetry of the system, or can take an intermediate value through a spontaneous mirror symmetry breaking transition. In the mirror symmetry breaking phase, adiabatic changes of the orbital magnetic flux drive charge and spin currents along the nanotube. We discuss the relevance of these results to recent and future experiments.

Published
2022

13. Strongly coupled phonon fluid and Goldstone modes in an anharmonic quantum solid: transport and chaos

Author

Tulipman, Evyatar, Berg, Erez, Tulipman, Evyatar, and Berg, Erez

Abstract

We study properties of thermal transport and quantum many-body chaos in a lattice model with $N\to\infty$ oscillators per site, coupled by strong anharmonic terms. We first consider a model with only optical phonons. We find that the thermal diffusivity $D_{\rm th}$ and chaos diffusivity $D_L$ (defined as $D_L = v_B^2/ \lambda_L$, where $v_B$ and $\lambda_L$ are the butterfly velocity and the scrambling rate, respectively) satisfy $D_{\rm th} \approx \gamma D_L$ with $\gamma\gtrsim 1$. At intermediate temperatures, the model exhibits a "quantum phonon fluid" regime, where both diffusivities satisfy $D^{-1} \propto T$, and the thermal relaxation time and inverse scrambling rate are of the order the of Planckian timescale $\hbar/k_B T$. We then introduce acoustic phonons to the model and study their effect on transport and chaos. The long-wavelength acoustic modes remain long-lived even when the system is strongly coupled, due to Goldstone's theorem. As a result, for $d=1,2$, we find that $D_{\rm th}/D_L\to \infty$, while for $d=3$, $D_{\rm th}$ and $D_{L}$ remain comparable., Comment: 16 + 9 pages, 8 + 1 figures, updated version to match published version

Published
2021
Full Text
View/download PDF

14. Strongly coupled phonon fluid and Goldstone modes in an anharmonic quantum solid: transport and chaos

Author

Tulipman, Evyatar, Berg, Erez, Tulipman, Evyatar, and Berg, Erez

Abstract

We study properties of thermal transport and quantum many-body chaos in a lattice model with $N\to\infty$ oscillators per site, coupled by strong anharmonic terms. We first consider a model with only optical phonons. We find that the thermal diffusivity $D_{\rm th}$ and chaos diffusivity $D_L$ (defined as $D_L = v_B^2/ \lambda_L$, where $v_B$ and $\lambda_L$ are the butterfly velocity and the scrambling rate, respectively) satisfy $D_{\rm th} \approx \gamma D_L$ with $\gamma\gtrsim 1$. At intermediate temperatures, the model exhibits a "quantum phonon fluid" regime, where both diffusivities satisfy $D^{-1} \propto T$, and the thermal relaxation time and inverse scrambling rate are of the order the of Planckian timescale $\hbar/k_B T$. We then introduce acoustic phonons to the model and study their effect on transport and chaos. The long-wavelength acoustic modes remain long-lived even when the system is strongly coupled, due to Goldstone's theorem. As a result, for $d=1,2$, we find that $D_{\rm th}/D_L\to \infty$, while for $d=3$, $D_{\rm th}$ and $D_{L}$ remain comparable., Comment: 16 + 9 pages, 8 + 1 figures, updated version to match published version

Published
2021
Full Text
View/download PDF

15. Strong-coupling expansion of multi-band interacting models:Mapping onto the transverse-field J1-J2 Ising model

Author

Wang, Xiaoyu, Christensen, Morten H., Berg, Erez, Fernandes, Rafael M., Wang, Xiaoyu, Christensen, Morten H., Berg, Erez, and Fernandes, Rafael M.

Abstract

We investigate a class of two-dimensional two-band microscopic models in which the inter-band repulsive interactions play the dominant role. We first demonstrate three different schemes of constraining the ratios between the three types of inter-band interactions - density-density, spin exchange, and pair-hopping that render the model free of the fermionic sign-problem for any filling and, consequently, amenable to efficient Quantum Monte Carlo simulations. We then study the behavior of these signproblem-free models in the strong-coupling regime. In the cases where spin-rotational invariance is preserved or lowered to a planar symmetry, the strong-coupling ground state is a quantum paramagnet. However, in the case where there is only a residual Ising symmetry, the strong-coupling expansion maps onto the transverse-field J(1)-J(2) Ising model, whose pseudospins are associated with local inter-band magnetic order. We show that by varying the band structure parameters within a reasonable range of values, a variety of ground states and quantum critical points can be accessed in the strong-coupling regime, some of which are not realized in the weak-coupling regime. We compare these results with the case of the single-band Hubbard model, where only intra-band repulsion is present, and whose strong-coupling behavior is captured by a simple Heisenberg model. (C) 2021 Elsevier Inc. All rights reserved.

Published
2021

16. Electronic Floquet gyro-liquid crystal

Author

Esin, Iliya, Gupta, Gaurav Kumar, Berg, Erez, Rudner, Mark S., Lindner, Netanel H., Esin, Iliya, Gupta, Gaurav Kumar, Berg, Erez, Rudner, Mark S., and Lindner, Netanel H.

Abstract

The nonequilibrium regime provides an exciting frontier in the search for novel quantum phases of matter. Here, the authors show that optically driving a lightly-doped semiconductor can lead to the spontaneous formation of a dynamical quantum liquid crystalline phase with a rotating magnetization.Floquet engineering uses coherent time-periodic drives to realize designer band structures on-demand, thus yielding a versatile approach for inducing a wide range of exotic quantum many-body phenomena. Here we show how this approach can be used to induce non-equilibrium correlated states with spontaneously broken symmetry in lightly doped semiconductors. In the presence of a resonant driving field, the system spontaneously develops quantum liquid crystalline order featuring strong anisotropy whose directionality rotates as a function of time. The phase transition occurs in the steady state of the system achieved due to the interplay between the coherent external drive, electron-electron interactions, and dissipative processes arising from the coupling to phonons and the electromagnetic environment. We obtain the phase diagram of the system using numerical calculations that match predictions obtained from a phenomenological treatment and discuss the conditions on the system and the external drive under which spontaneous symmetry breaking occurs. Our results demonstrate that coherent driving can be used to induce non-equilibrium quantum phases of matter with dynamical broken symmetry.

Published
2021

17. Hierarchy of many-body invariants and quantized magnetization in anomalous Floquet insulators

Author

Nathan, Frederik, Abanin, Dmitry A., Lindner, Netanel H., Berg, Erez, Rudner, Mark S., Nathan, Frederik, Abanin, Dmitry A., Lindner, Netanel H., Berg, Erez, and Rudner, Mark S.

Abstract

We uncover a new family of few-body topological phases in periodically driven fermionic systems in two dimensions. These phases, which we term correlation-induced anomalous Floquet insulators (CIAFIs), are characterized by quantized contributions to the bulk magnetization from multi-particle correlations, and are classified by a family of integer-valued topological invariants. The CIAFI phases do not require many-body localization, but arise in the generic situation of k-particle localization, where the system is localized (due to disorder) for any finite number of particles up to a maximum number, k. We moreover show that, when fully many-body localized, periodically driven systems of interacting fermions in two dimensions are characterized by a quantized magnetization in the bulk, thus confirming the quantization of magnetization of the anomalous Floquet insulator. We demonstrate our results with numerical simulations.

Published
2021

18. Electronic Floquet gyro-liquid crystal

Author

Esin, Iliya, Gupta, Gaurav Kumar, Berg, Erez, Rudner, Mark S., Lindner, Netanel H., Esin, Iliya, Gupta, Gaurav Kumar, Berg, Erez, Rudner, Mark S., and Lindner, Netanel H.

Abstract

The nonequilibrium regime provides an exciting frontier in the search for novel quantum phases of matter. Here, the authors show that optically driving a lightly-doped semiconductor can lead to the spontaneous formation of a dynamical quantum liquid crystalline phase with a rotating magnetization.Floquet engineering uses coherent time-periodic drives to realize designer band structures on-demand, thus yielding a versatile approach for inducing a wide range of exotic quantum many-body phenomena. Here we show how this approach can be used to induce non-equilibrium correlated states with spontaneously broken symmetry in lightly doped semiconductors. In the presence of a resonant driving field, the system spontaneously develops quantum liquid crystalline order featuring strong anisotropy whose directionality rotates as a function of time. The phase transition occurs in the steady state of the system achieved due to the interplay between the coherent external drive, electron-electron interactions, and dissipative processes arising from the coupling to phonons and the electromagnetic environment. We obtain the phase diagram of the system using numerical calculations that match predictions obtained from a phenomenological treatment and discuss the conditions on the system and the external drive under which spontaneous symmetry breaking occurs. Our results demonstrate that coherent driving can be used to induce non-equilibrium quantum phases of matter with dynamical broken symmetry.

Published
2021

19. Hierarchy of many-body invariants and quantized magnetization in anomalous Floquet insulators

Author

Nathan, Frederik, Abanin, Dmitry A., Lindner, Netanel H., Berg, Erez, Rudner, Mark S., Nathan, Frederik, Abanin, Dmitry A., Lindner, Netanel H., Berg, Erez, and Rudner, Mark S.

Abstract

We uncover a new family of few-body topological phases in periodically driven fermionic systems in two dimensions. These phases, which we term correlation-induced anomalous Floquet insulators (CIAFIs), are characterized by quantized contributions to the bulk magnetization from multi-particle correlations, and are classified by a family of integer-valued topological invariants. The CIAFI phases do not require many-body localization, but arise in the generic situation of k-particle localization, where the system is localized (due to disorder) for any finite number of particles up to a maximum number, k. We moreover show that, when fully many-body localized, periodically driven systems of interacting fermions in two dimensions are characterized by a quantized magnetization in the bulk, thus confirming the quantization of magnetization of the anomalous Floquet insulator. We demonstrate our results with numerical simulations.

Published
2021

20. Scrambling and Lyapunov Exponent in Unitary Networks with Tunable Interactions

Author

Keselman, Anna, Nie, Laimei, Berg, Erez, Keselman, Anna, Nie, Laimei, and Berg, Erez

Abstract

Scrambling of information in a quantum many-body system, quantified by the out-of-time-ordered correlator (OTOC), is a key manifestation of quantum chaos. A regime of exponential growth in the OTOC, characterized by a Lyapunov exponent, has so far mostly been observed in systems with a high-dimensional local Hilbert space and in weakly-coupled systems. Here, we propose a general criterion for the existence of a well-defined regime of exponential growth of the OTOC in spatially extended systems with local interactions. In such systems, we show that a parametrically long period of exponential growth requires the butterfly velocity to be much larger than the Lyapunov exponent times a microscopic length scale, such as the lattice spacing. As an explicit example, we study a random unitary circuit with tunable interactions. In this model, we show that in the weakly interacting limit the above criterion is satisfied, and there is a prolonged window of exponential growth. Our results are based on numerical simulations of both Clifford and universal random circuits supported by an analytical treatment.

Published
2020
Full Text
View/download PDF

21. Strongly coupled quantum phonon fluid in a solvable model

Author

Tulipman, Evyatar, Berg, Erez, Tulipman, Evyatar, and Berg, Erez

Abstract

We study a model of a large number of strongly coupled phonons that can be viewed as a bosonic variant of the Sachdev-Ye-Kitaev model. We determine the phase diagram of the model which consists of a glass phase and a disordered phase, with a first-order phase transition separating them. We compute the specific heat of the disordered phase, with which we diagnose the high-temperature crossover to the classical limit. We further study the real-time dynamics of the disordered phase, where we identify three dynamical regimes as a function of temperature. Low temperatures are associated with a semiclassical regime, where the phonons can be described as long-lived normal modes. High temperatures are associated with the classical limit of the model. For a large region in parameter space, we identify an intermediate-temperatures regime, where the phonon lifetime is of the order of the Planckian time scale $\hbar/k_B T$., Comment: Typos corrected, references added, discussion improved

Published
2020
Full Text
View/download PDF

22. Bulk Anyons as Edge Symmetries: Boundary Phase Diagrams of Topologically Ordered States

Author

Lichtman, Tsuf, Thorngren, Ryan, Lindner, Netanel H., Stern, Ady, Berg, Erez, Lichtman, Tsuf, Thorngren, Ryan, Lindner, Netanel H., Stern, Ady, and Berg, Erez

Abstract

We study effectively one-dimensional systems that emerge at the edge of a two-dimensional topologically ordered state, or at the boundary between two topologically ordered states. We argue that anyons of the bulk are associated with emergent symmetries of the edge, which play a crucial role in the structure of its phase diagram. Using this symmetry principle, transitions between distinct gapped phases at the boundaries of Abelian states can be understood in terms of symmetry breaking transitions or transitions between symmetry protected topological phases. Yet more exotic phenomena occur when the bulk hosts non-Abelian anyons. To demonstrate these principles, we explore the phase diagrams of the edges of a single and a double layer of the toric code, as well as those of domain walls in a single and double-layer Kitaev spin liquid (KSL). In the case of the KSL, we find that the presence of a non-Abelian anyon in the bulk enforces Kramers-Wannier self-duality as a symmetry of the effective boundary theory. These examples illustrate a number of surprising phenomena, such as spontaneous duality-breaking, two-sector phase transitions, and unfreezing of marginal operators at a transition between different gapless phases., Comment: 33 page, 13 figures; published version

Published
2020
Full Text
View/download PDF

23. Strongly coupled quantum phonon fluid in a solvable model

Author

Tulipman, Evyatar, Berg, Erez, Tulipman, Evyatar, and Berg, Erez

Abstract

We study a model of a large number of strongly coupled phonons that can be viewed as a bosonic variant of the Sachdev-Ye-Kitaev model. We determine the phase diagram of the model which consists of a glass phase and a disordered phase, with a first-order phase transition separating them. We compute the specific heat of the disordered phase, with which we diagnose the high-temperature crossover to the classical limit. We further study the real-time dynamics of the disordered phase, where we identify three dynamical regimes as a function of temperature. Low temperatures are associated with a semiclassical regime, where the phonons can be described as long-lived normal modes. High temperatures are associated with the classical limit of the model. For a large region in parameter space, we identify an intermediate-temperatures regime, where the phonon lifetime is of the order of the Planckian time scale $\hbar/k_B T$., Comment: Typos corrected, references added, discussion improved

Published
2020
Full Text
View/download PDF

24. Bulk Anyons as Edge Symmetries: Boundary Phase Diagrams of Topologically Ordered States

Author

Lichtman, Tsuf, Thorngren, Ryan, Lindner, Netanel H., Stern, Ady, Berg, Erez, Lichtman, Tsuf, Thorngren, Ryan, Lindner, Netanel H., Stern, Ady, and Berg, Erez

Abstract

We study effectively one-dimensional systems that emerge at the edge of a two-dimensional topologically ordered state, or at the boundary between two topologically ordered states. We argue that anyons of the bulk are associated with emergent symmetries of the edge, which play a crucial role in the structure of its phase diagram. Using this symmetry principle, transitions between distinct gapped phases at the boundaries of Abelian states can be understood in terms of symmetry breaking transitions or transitions between symmetry protected topological phases. Yet more exotic phenomena occur when the bulk hosts non-Abelian anyons. To demonstrate these principles, we explore the phase diagrams of the edges of a single and a double layer of the toric code, as well as those of domain walls in a single and double-layer Kitaev spin liquid (KSL). In the case of the KSL, we find that the presence of a non-Abelian anyon in the bulk enforces Kramers-Wannier self-duality as a symmetry of the effective boundary theory. These examples illustrate a number of surprising phenomena, such as spontaneous duality-breaking, two-sector phase transitions, and unfreezing of marginal operators at a transition between different gapless phases., Comment: 33 page, 13 figures; published version

Published
2020
Full Text
View/download PDF

25. Quantized large-bias current in the anomalous Floquet-Anderson insulator

Author

Kundu, Arijit, Rudner, Mark, Berg, Erez, Lindner, Netanel H., Kundu, Arijit, Rudner, Mark, Berg, Erez, and Lindner, Netanel H.

Abstract

We study two-terminal transport through two-dimensional periodically driven systems in which all bulk Floquet eigenstates are localized by disorder. We focus on the anomalous Floquet-Anderson insulator (AFAI) phase, a topologically nontrivial phase within this class, which hosts topologically protected chiral edge modes coexisting with its fully localized bulk. We show that the unique properties of the AFAI yield remarkable far-from-equilibrium transport signatures: for a large bias between leads, a quantized amount of charge is transported through the system each driving period. Upon increasing the bias, the chiral Floquet edge mode connecting source to drain becomes fully occupied and the current rapidly approaches its quantized value.

Published
2020

28. Quantized large-bias current in the anomalous Floquet-Anderson insulator

Author

Kundu, Arijit, Rudner, Mark, Berg, Erez, Lindner, Netanel H., Kundu, Arijit, Rudner, Mark, Berg, Erez, and Lindner, Netanel H.

Abstract

We study two-terminal transport through two-dimensional periodically driven systems in which all bulk Floquet eigenstates are localized by disorder. We focus on the anomalous Floquet-Anderson insulator (AFAI) phase, a topologically nontrivial phase within this class, which hosts topologically protected chiral edge modes coexisting with its fully localized bulk. We show that the unique properties of the AFAI yield remarkable far-from-equilibrium transport signatures: for a large bias between leads, a quantized amount of charge is transported through the system each driving period. Upon increasing the bias, the chiral Floquet edge mode connecting source to drain becomes fully occupied and the current rapidly approaches its quantized value.

Published
2020

29. Exponentially long lifetime of universal quasi-steady states in topological Floquet pumps

Author

Gulden, Tobias, Rudner, Mark S., Berg, Erez, Lindner, Netanel H., Gulden, Tobias, Rudner, Mark S., Berg, Erez, and Lindner, Netanel H.

Abstract

We investigate a mechanism to transiently stabilize topological phenomena in long-lived quasi-steady states of isolated quantum many-body systems driven at low frequencies. We obtain an analytical bound for the lifetime of the quasi-steady states which is exponentially large in the inverse driving frequency. Within this lifetime, the quasi-steady state is characterized by maximum entropy subject to the constraint of fixed number of particles in the system's Floquet-Bloch bands. In such a state, all the non-universal properties of these bands are washed out, hence only the topological properties persist.

Published
2020

30. Quantized large-bias current in the anomalous Floquet-Anderson insulator

Author

Kundu, Arijit, Rudner, Mark, Berg, Erez, Lindner, Netanel H., Kundu, Arijit, Rudner, Mark, Berg, Erez, and Lindner, Netanel H.

Abstract

We study two-terminal transport through two-dimensional periodically driven systems in which all bulk Floquet eigenstates are localized by disorder. We focus on the anomalous Floquet-Anderson insulator (AFAI) phase, a topologically nontrivial phase within this class, which hosts topologically protected chiral edge modes coexisting with its fully localized bulk. We show that the unique properties of the AFAI yield remarkable far-from-equilibrium transport signatures: for a large bias between leads, a quantized amount of charge is transported through the system each driving period. Upon increasing the bias, the chiral Floquet edge mode connecting source to drain becomes fully occupied and the current rapidly approaches its quantized value.

Published
2020

31. Intrinsic superconducting instabilities of a solvable model for an incoherent metal

Author

Massachusetts Institute of Technology. Department of Physics, Chowdhury, Debanjan, Berg, Erez, Massachusetts Institute of Technology. Department of Physics, Chowdhury, Debanjan, and Berg, Erez

Abstract

We construct a family of translationally invariant lattice models with a large number (N) of orbitals at every site coupled together via single-electron tunneling. By tuning the relative strength of the electronic bandwidth and on-site interactions, which have a modified Sachdev-Ye-Kitaev form, we demonstrate a number of unusual features at strong coupling and in the large-N limit. We find examples of (i) an intrinsic non-BCS superconducting instability arising out of an incoherent non-Fermi-liquid metal, and (ii) an instability of an incipient heavy Fermi-liquid metal to superconductivity with transition temperatures comparable to its renormalized bandwidth. At strong coupling, these solvable models display pairing instabilities that are not driven by any special “nesting” properties associated with an underlying Fermi surface., The Gordon and Betty Moore Foundation, under the EPiQS initiative, Grant No. GBMF-4303

Published
2020

32. Exponentially long lifetime of universal quasi-steady states in topological Floquet pumps

Author

Gulden, Tobias, Rudner, Mark S., Berg, Erez, Lindner, Netanel H., Gulden, Tobias, Rudner, Mark S., Berg, Erez, and Lindner, Netanel H.

Abstract

We investigate a mechanism to transiently stabilize topological phenomena in long-lived quasi-steady states of isolated quantum many-body systems driven at low frequencies. We obtain an analytical bound for the lifetime of the quasi-steady states which is exponentially large in the inverse driving frequency. Within this lifetime, the quasi-steady state is characterized by maximum entropy subject to the constraint of fixed number of particles in the system's Floquet-Bloch bands. In such a state, all the non-universal properties of these bands are washed out, hence only the topological properties persist.

Published
2020

35. Evidence of topological superconductivity in planar Josephson junctions

Author

Fornieri, Antonio, Whiticar, Alexander M., Setiawan, F., Marín, Elías Portolés, Drachmann, Asbjørn C. C., Keselman, Anna, Gronin, Sergei, Thomas, Candice, Wang, Tian, Kallaher, Ray, Gardner, Geoffrey C., Berg, Erez, Manfra, Michael J., Stern, Ady, Marcus, Charles M., Nichele, Fabrizio, Fornieri, Antonio, Whiticar, Alexander M., Setiawan, F., Marín, Elías Portolés, Drachmann, Asbjørn C. C., Keselman, Anna, Gronin, Sergei, Thomas, Candice, Wang, Tian, Kallaher, Ray, Gardner, Geoffrey C., Berg, Erez, Manfra, Michael J., Stern, Ady, Marcus, Charles M., and Nichele, Fabrizio

Abstract

Majorana zero modes are quasiparticle states localized at the boundaries of topological superconductors that are expected to be ideal building blocks for fault-tolerant quantum computing. Several observations of zero-bias conductance peaks measured in tunneling spectroscopy above a critical magnetic field have been reported as experimental indications of Majorana zero modes in superconductor/semiconductor nanowires. On the other hand, two dimensional systems offer the alternative approach to confine Ma jorana channels within planar Josephson junctions, in which the phase difference {\phi} between the superconducting leads represents an additional tuning knob predicted to drive the system into the topological phase at lower magnetic fields. Here, we report the observation of phase-dependent zero-bias conductance peaks measured by tunneling spectroscopy at the end of Josephson junctions realized on a InAs/Al heterostructure. Biasing the junction to {\phi} ~ {\pi} significantly reduces the critical field at which the zero-bias peak appears, with respect to {\phi} = 0. The phase and magnetic field dependence of the zero-energy states is consistent with a model of Majorana zero modes in finite-size Josephson junctions. Besides providing experimental evidence of phase-tuned topological superconductivity, our devices are compatible with superconducting quantum electrodynamics architectures and scalable to complex geometries needed for topological quantum computing.

Published
2019

36. Anomalous Floquet insulators

Author

Nathan, Frederik, Abanin, Dmitry, Berg, Erez, Lindner, Netanel H., Rudner, Mark S., Nathan, Frederik, Abanin, Dmitry, Berg, Erez, Lindner, Netanel H., and Rudner, Mark S.

Published
2019

37. Anomalous Floquet insulators

Author

Nathan, Frederik, Abanin, Dmitry, Berg, Erez, Lindner, Netanel H., Rudner, Mark S., Nathan, Frederik, Abanin, Dmitry, Berg, Erez, Lindner, Netanel H., and Rudner, Mark S.

Published
2019

38. Translationally invariant non-Fermi liquid metals with critical Fermi-surfaces: Solvable models

Author

Chowdhury, Debanjan, Werman, Yochai, Berg, Erez, Senthil, T., Chowdhury, Debanjan, Werman, Yochai, Berg, Erez, and Senthil, T.

Abstract

We construct examples of translationally invariant solvable models of strongly-correlated metals, composed of lattices of Sachdev-Ye-Kitaev dots with identical local interactions. These models display crossovers as a function of temperature into regimes with local quantum criticality and marginal-Fermi liquid behavior. In the marginal Fermi liquid regime, the dc resistivity increases linearly with temperature over a broad range of temperatures. By generalizing the form of interactions, we also construct examples of non-Fermi liquids with critical Fermi-surfaces. The self energy has a singular frequency dependence, but lacks momentum dependence, reminiscent of a dynamical mean field theory-like behavior but in dimensions $d<\infty$. In the low temperature and strong-coupling limit, a heavy Fermi liquid is formed. The critical Fermi-surface in the non-Fermi liquid regime gives rise to quantum oscillations in the magnetization as a function of an external magnetic field in the absence of quasiparticle excitations. We discuss the implications of these results for local quantum criticality and for fundamental bounds on relaxation rates. Drawing on the lessons from these models, we formulate conjectures on coarse grained descriptions of a class of intermediate scale non-fermi liquid behavior in generic correlated metals., Comment: (48+27) pages, 10 figures; (v2) made some textual changes for increased clarity. This version also includes updated references. To appear in Physical Review X

Published
2018
Full Text
View/download PDF

39. Translationally invariant non-Fermi liquid metals with critical Fermi-surfaces: Solvable models

Author

Chowdhury, Debanjan, Werman, Yochai, Berg, Erez, Senthil, T., Chowdhury, Debanjan, Werman, Yochai, Berg, Erez, and Senthil, T.

Abstract

We construct examples of translationally invariant solvable models of strongly-correlated metals, composed of lattices of Sachdev-Ye-Kitaev dots with identical local interactions. These models display crossovers as a function of temperature into regimes with local quantum criticality and marginal-Fermi liquid behavior. In the marginal Fermi liquid regime, the dc resistivity increases linearly with temperature over a broad range of temperatures. By generalizing the form of interactions, we also construct examples of non-Fermi liquids with critical Fermi-surfaces. The self energy has a singular frequency dependence, but lacks momentum dependence, reminiscent of a dynamical mean field theory-like behavior but in dimensions $d<\infty$. In the low temperature and strong-coupling limit, a heavy Fermi liquid is formed. The critical Fermi-surface in the non-Fermi liquid regime gives rise to quantum oscillations in the magnetization as a function of an external magnetic field in the absence of quasiparticle excitations. We discuss the implications of these results for local quantum criticality and for fundamental bounds on relaxation rates. Drawing on the lessons from these models, we formulate conjectures on coarse grained descriptions of a class of intermediate scale non-fermi liquid behavior in generic correlated metals., Comment: (48+27) pages, 10 figures; (v2) made some textual changes for increased clarity. This version also includes updated references. To appear in Physical Review X

Published
2018
Full Text
View/download PDF

40. Superconductivity and non-Fermi liquid behavior near a nematic quantum critical point

Author

Massachusetts Institute of Technology. Department of Physics, Lederer, Samuel, Schattner, Yoni, Berg, Erez, Kivelson, Steven A., Massachusetts Institute of Technology. Department of Physics, Lederer, Samuel, Schattner, Yoni, Berg, Erez, and Kivelson, Steven A.

Abstract

Using determinantal quantum Monte Carlo, we compute the properties of a lattice model with spin 1/2 itinerant electrons tuned through a quantum phase transition to an Ising nematic phase. The nematic fluctuations induce superconductivity with a broad dome in the superconducting T[subscript c] enclosing the nematic quantum critical point. For temperatures above T[subscript c], we see strikingly non- Fermi liquid behavior, including a "nodal-antinodal dichotomy" reminiscent of that seen in several transition metal oxides. In addition, the critical fluctuations have a strong effect on the lowfrequency optical conductivity, resulting in behavior consistent with "bad metal" phenomenology. Keywords: superconductivity; non-Fermi liquid; quantum criticality

Published
2018

42. Fate of the one-dimensional Ising quantum critical point coupled to a gapless boson

Author

Alberton, Ori, Ruhman, Jonathan, Berg, Erez, Altman, Ehud, Alberton, Ori, Ruhman, Jonathan, Berg, Erez, and Altman, Ehud

Abstract

The problem of a quantum Ising degree of freedom coupled to a gapless bosonic mode appears naturally in many one-dimensional systems, yet surprisingly little is known how such a coupling affects the Ising quantum critical point. We investigate the fate of the critical point in a regime, where the weak coupling renormalization group (RG) indicates a flow toward strong coupling. Using a renormalization group analysis and numerical density matrix renormalization group (DMRG) calculations we show that, depending on the ratio of velocities of the gapless bosonic mode and the Ising critical fluctuations, the transition may remain continuous or become fluctuation-driven first order. The two regimes are separated by a tricritical point of a novel type.

Published
2017

43. Fate of the one-dimensional Ising quantum critical point coupled to a gapless boson

Author

Alberton, Ori, Ruhman, Jonathan, Berg, Erez, Altman, Ehud, Alberton, Ori, Ruhman, Jonathan, Berg, Erez, and Altman, Ehud

Abstract

The problem of a quantum Ising degree of freedom coupled to a gapless bosonic mode appears naturally in many one-dimensional systems, yet surprisingly little is known how such a coupling affects the Ising quantum critical point. We investigate the fate of the critical point in a regime, where the weak coupling renormalization group (RG) indicates a flow toward strong coupling. Using a renormalization group analysis and numerical density matrix renormalization group (DMRG) calculations we show that, depending on the ratio of velocities of the gapless bosonic mode and the Ising critical fluctuations, the transition may remain continuous or become fluctuation-driven first order. The two regimes are separated by a tricritical point of a novel type.

Published
2017

47. Ising Nematic Quantum Critical Point in a Metal: A Monte Carlo Study

Author

Massachusetts Institute of Technology. Department of Physics, Lederer, Samuel, Schattner, Yoni, Kivelson, Steven A., Berg, Erez, Massachusetts Institute of Technology. Department of Physics, Lederer, Samuel, Schattner, Yoni, Kivelson, Steven A., and Berg, Erez

Abstract

The Ising nematic quantum critical point associated with the zero-temperature transition from a symmetric to a nematic metal is an exemplar of metallic quantum criticality. We carry out a minus-sign-free quantum Monte Carlo study of this quantum critical point for a two-dimensional lattice model with sizes up to 24 × 24 sites. For the parameters in this study, some (but not all) correlation functions exhibit scaling behavior over the accessible ranges of temperature, (imaginary) time, and distance, and the system remains nonsuperconducting down to the lowest accessible temperatures. The observed scaling behavior has remarkable similarities to recently measured properties of the Fe-based superconductors proximate to their putative nematic quantum critical point., United States. Department of Energy (Grant No. DE-AC02-76SF00515), Stanford University (ABB Fellowship), Gordon and Betty Moore Foundation (Post Doctoral Fellowship)

Published
2017

48. Fate of the one-dimensional Ising quantum critical point coupled to a gapless boson

Author

Massachusetts Institute of Technology. Department of Physics, Ruhman, Yehonatan, Alberton, Ori, Berg, Erez, Altman, Ehud, Massachusetts Institute of Technology. Department of Physics, Ruhman, Yehonatan, Alberton, Ori, Berg, Erez, and Altman, Ehud

Abstract

The problem of a quantum Ising degree of freedom coupled to a gapless bosonic mode appears naturally in many one-dimensional systems, yet surprisingly little is known how such a coupling affects the Ising quantum critical point. We investigate the fate of the critical point in a regime, where the weak coupling renormalization group (RG) indicates a flow toward strong coupling. Using a renormalization group analysis and numerical density matrix renormalization group (DMRG) calculations we show that, depending on the ratio of velocities of the gapless bosonic mode and the Ising critical fluctuations, the transition may remain continuous or become fluctuation-driven first order. The two regimes are separated by a tricritical point of a novel type., European Research Council (UQUAM Synergy Grant), Gordon and Betty Moore Foundation (Grant GBMF4303)

Published
2017

50. Spin density wave order, topological order, and Fermi surface reconstruction

Author

Sachdev, Subir, Berg, Erez, Chatterjee, Shubhayu, Schattner, Yoni, Sachdev, Subir, Berg, Erez, Chatterjee, Shubhayu, and Schattner, Yoni

Abstract

In the conventional theory of density wave ordering in metals, the onset of spin density wave (SDW) order co-incides with the reconstruction of the Fermi surfaces into small 'pockets'. We present models which display this transition, while also displaying an alternative route between these phases via an intermediate phase with topological order, no broken symmetry, and pocket Fermi surfaces. The models involve coupling emergent gauge fields to a fractionalized SDW order, but retain the canonical electron operator in the underlying Hamiltonian. We establish an intimate connection between the suppression of certain defects in the SDW order, and the presence of Fermi surface sizes distinct from the Luttinger value in Fermi liquids. We discuss the relevance of such models to the physics of the hole-doped cuprates near optimal doping., Comment: 32 pages, 3 figures; (v2) 33 pages, 4 figures, added figure, clarifications and references

Published
2016
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results