Your search keyword '"Sachdev, Subir"' showing total 1,718 results

1. Quantum Annealing with chaotic driver Hamiltonians

Author

Schlömer, Henning and Sachdev, Subir

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons

Abstract

Quantum annealing is a computational approach designed to leverage quantum fluctuations for solving large-scale classical optimization problems. Although incorporating standard transverse field (TF) terms in the annealing process can help navigate sharp minima, the potential for achieving a scalable quantum advantage for general optimization problems remains uncertain. Here, we examine the effectiveness of including chaotic quantum driver Hamiltonians in the annealing dynamics. Specifically, we investigate driver Hamiltonians based on a bosonic spin version of the Sachdev-Ye-Kitaev (SYK) model, which features a high degree of non-locality and non-commutativity. Focusing on MaxCut instances on regular graphs, we find that a considerable proportion of SYK model instances demonstrate significant speedups, especially for challenging graph configurations. Additionally, our analysis of time-to-solution scalings for the low autocorrelation binary sequence (LABS) problem suggests that SYK-type fluctuations can outperform traditional transverse field annealing schedules in large-scale optimization tasks., Comment: 9+2 pages

Published

2024

2. Correlation between unconventional superconductivity and strange metallicity revealed by operando superfluid density measurements

Author

Zhang, Ruozhou, Qin, Mingyang, Li, Chenyuan, Zhao, Zhanyi, Wei, Zhongxu, Xu, Juan, Jiang, Xingyu, Cheng, Wenxin, Shi, Qiuyan, Wang, Xuewei, Yuan, Jie, Li, Yangmu, Chen, Qihong, Xiang, Tao, Sachdev, Subir, Li, Zi-Xiang, Jin, Kui, and Zhao, Zhongxian

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons

Abstract

Strange-metal behavior has been observed in superconductors ranging from cuprates to pressurized nickelates, but its relationship to unconventional superconductivity remains elusive. Here, we perform operando superfluid density measurements on ion-gated FeSe films. We observe for the first time a synchronized evolution of superconducting condensate and the strange-metal phase with electron doping. A linear scaling between zero-temperature superfluid density and the strange-metal resistivity coefficient is further established, which nails down a direct link between the formation of superfluid in the superconducting state and the scattering of carriers in the strange-metal normal state. Remarkably, the scaling also applies for different iron-based and cuprate superconductors despite their distinct electronic structures and pairing symmetries. Such a correlation can be reproduced in a theoretical calculation on the two-dimensional Yukawa-Sachdev-Ye-Kitaev model by considering a cooperative effect of quantum critical fluctuation and disorder. These findings indicate a fundamental principle governing superconducting condensation and strange-metal scattering in unconventional superconductors., Comment: 36 pages, 18 figures

Published

2024

3. Polaronic correlations from optimized ancilla wave functions for the Fermi-Hubbard model

Author

Müller, Tobias, Thomale, Ronny, Sachdev, Subir, and Iqbal, Yasir

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We employ a family of ancilla qubit variational wave-functions [Zhang and Sachdev, Phys. Rev. Res. 2, 023172 (2020)] to describe the polaronic correlations in the pseudo-gap metal phase of a hole-doped 2D Fermi-Hubbard model. Comparison to ultra-cold atom quantum simulator data [Koepsel et al., Science 374, 82 (2021)] reveals both qualitative and quantitative agreement with the numerical analysis from half-filling up to 80\% hole-doping, capturing the crossover from the polaronic regime to the Fermi liquid observed around $40\%$ doping., Comment: 7 pages, 3 figures

Published

2024

4. Lectures on the quantum phase transitions of metals

Author

Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

Quantum phase transitions of metals involve changes in the Fermi surface, and can be divided into three categories. The first two categories involve symmetry breaking, and lead to a deformation or reconstruction of the Fermi surface. The third category involves a change in the volume enclosed by the Fermi surface without any symmetry breaking: one phase is a Fermi liquid (FL) with the conventional Luttinger volume, while the other phase is a `fractionalized Fermi liquid' (FL*), which has a non-Luttinger volume Fermi surface accompanied by a spin liquid with fractionalized excitations. It is a relatively simple matter to obtain a FL*-FL transition in Kondo lattice models. However, the FL*-FL transition can also be present in single-band Hubbard-like models: this is efficiently described by the `ancilla' method, which shows that the transition is a `flipped' Kondo lattice transition. This single-band FL*-FL transition is argued to apply to the metallic states of the hole-doped cuprates. In the clean limit, the critical properties of the quantum transitions in the three categories are distinct, but all lead to perfect metal transport in the quantum-critical regime. Impurity-induced `Harris disorder', with spatial fluctuations in the local position of the quantum critical point, is a relevant perturbation to the clean critical points. In the presence of Harris disorder, all three categories exhibit strange metal behavior, which can be described by a universal two-dimensional Yukawa-Sachdev-Ye-Kitaev model., Comment: 52 pages and 168 slides; Lecture notes and slides for `Prospects in Theoretical Physics 2024', Quantum Matter Summer School, Institute for Advanced Study, Princeton, July 8-19, 2024; Lecture videos at https://www.youtube.com/playlist?list=PLcD25rnTeV9jGNXx-7XGKazw6d5yGhyWQ

Published

2024

5. Quantum coarsening and collective dynamics on a programmable quantum simulator

Author

Manovitz, Tom, Li, Sophie H., Ebadi, Sepehr, Samajdar, Rhine, Geim, Alexandra A., Evered, Simon J., Bluvstein, Dolev, Zhou, Hengyun, Koyluoglu, Nazli Ugur, Feldmeier, Johannes, Dolgirev, Pavel E., Maskara, Nishad, Kalinowski, Marcin, Sachdev, Subir, Huse, David A., Greiner, Markus, Vuletić, Vladan, and Lukin, Mikhail D.

Subjects

Quantum Physics, Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

Understanding the collective quantum dynamics of nonequilibrium many-body systems is an outstanding challenge in quantum science. In particular, dynamics driven by quantum fluctuations are important for the formation of exotic quantum phases of matter, fundamental high-energy processes, quantum metrology, and quantum algorithms. Here, we use a programmable quantum simulator based on Rydberg atom arrays to experimentally study collective dynamics across a (2+1)D Ising quantum phase transition. After crossing the quantum critical point, we observe a gradual growth of correlations through coarsening of antiferromagnetically ordered domains. By deterministically preparing and following the evolution of ordered domains, we show that the coarsening is driven by the curvature of domain boundaries, and find that the dynamics accelerate with proximity to the quantum critical point. We quantitatively explore these phenomena and further observe long-lived oscillations of the order parameter, corresponding to an amplitude (Higgs) mode. These observations offer a unique viewpoint into emergent collective dynamics in strongly correlated quantum systems and nonequilibrium quantum processes., Comment: 25 pages, 15 figures

Published

2024

6. Vortex structure in a $d$-wave superconductor obtained by a confinement transition from the pseudogap metal

Author

Zhang, Jia-Xin and Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

Abstract

We compute the structure of flux $h/(2e)$ vortices in a d-wave superconductor which emerges from a higher temperature pseudogap metal. Such a transition is described by a continuum theory of the Higgs condensation of 2 flavors of charge $e$ bosons which are fundamentals of an emergent SU(2) gauge field. Period-2 charge order is present near the vortex center. Upon coupling the electrons to the superconducting and charge order parameters, we find that the electronic local density of states does not have a zero-bias peak, in contrast to BCS theory. But there are sub-gap peaks at positive and negative bias, and these exhibit anti-phase periodic spatial modulations, similar to observations in scanning tunneling microscopy experiments in the underdoped cuprates (K. Matsuba et al., J. Phys. Soc. Jpn. 76, 063704 (2007))., Comment: 31 pages, 10 figures

Published

2024

7. Strange metal and superconductor in the two-dimensional Yukawa-Sachdev-Ye-Kitaev model

Author

Li, Chenyuan, Valentinis, Davide, Patel, Aavishkar A., Guo, Haoyu, Schmalian, Jörg, Sachdev, Subir, and Esterlis, Ilya

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity, High Energy Physics - Theory

Abstract

The two-dimensional Yukawa-Sachdev-Ye-Kitaev (2d-YSYK) model provides a universal theory of quantum phase transitions in metals in the presence of quenched random spatial fluctuations in the local position of the quantum critical point. It has a Fermi surface coupled to a scalar field by spatially random Yukawa interactions. We present full numerical solutions of a self-consistent disorder averaged analysis of the 2d-YSYK model in both the normal and superconducting states, obtaining electronic spectral functions, frequency-dependent conductivity, and superfluid stiffness. Our results reproduce key aspects of observations in the cuprates as analyzed by Michon et al. (arXiv:2205.04030). We also find a regime of increasing zero temperature superfluid stiffness with decreasing superconducting critical temperature, as is observed in bulk cuprates., Comment: 7+18 pages, 5+12 figures; references added

Published

2024

8. Replica symmetry breaking in spin glasses in the replica-free Keldysh formalism

Author

Lang, Johannes, Sachdev, Subir, and Diehl, Sebastian

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons, Mathematical Physics, Quantum Physics

Abstract

We show that the algebra of Parisi ultrametric matrices is recovered by the real-time, replica-free, Dyson-Keldysh equations of infinite-range quantum spin glasses in the late time glassy limit. This connects to earlier results on classical and quantum systems showing how ultrametricity emerges from the persistent slow aging dynamics of the glass phase. The stationary spin glass state thereby spontaneously breaks thermal symmetry, or the Kubo-Martin-Schwinger relation of a state in global thermal equilibrium. We describe the Keldysh path integral of the infinite-range Ising model in transverse and longitudinal fields, and in the context of the Landau expansion of the action functional, show how the long-time limit connects to the full replica symmetry breaking obtained in the equilibrium formalism. We also illustrate our formalism by applying it to the spherical quantum $p$-spin model, which only exhibits one-step replica symmetry breaking, Comment: 19 pages, 4 figures, revised version

Published

2024

9. Learning topological states from randomized measurements using variational tensor network tomography

Author

Teng, Yanting, Samajdar, Rhine, Van Kirk, Katherine, Wilde, Frederik, Sachdev, Subir, Eisert, Jens, Sweke, Ryan, and Najafi, Khadijeh

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons, Statistics - Machine Learning

Abstract

Learning faithful representations of quantum states is crucial to fully characterizing the variety of many-body states created on quantum processors. While various tomographic methods such as classical shadow and MPS tomography have shown promise in characterizing a wide class of quantum states, they face unique limitations in detecting topologically ordered two-dimensional states. To address this problem, we implement and study a heuristic tomographic method that combines variational optimization on tensor networks with randomized measurement techniques. Using this approach, we demonstrate its ability to learn the ground state of the surface code Hamiltonian as well as an experimentally realizable quantum spin liquid state. In particular, we perform numerical experiments using MPS ans\"atze and systematically investigate the sample complexity required to achieve high fidelities for systems of sizes up to $48$ qubits. In addition, we provide theoretical insights into the scaling of our learning algorithm by analyzing the statistical properties of maximum likelihood estimation. Notably, our method is sample-efficient and experimentally friendly, only requiring snapshots of the quantum state measured randomly in the $X$ or $Z$ bases. Using this subset of measurements, our approach can effectively learn any real pure states represented by tensor networks, and we rigorously prove that random-$XZ$ measurements are tomographically complete for such states., Comment: 11+35 pages, 4+3 figures; Added additional references

Published

2024

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

Author

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

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

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 (arXiv:1103.4181) 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, arXiv:1411.2098) 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 bi-directional 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.

Published

2024

11. Ferrimagnetism of ultracold fermions in a multi-band Hubbard system

Author

Lebrat, Martin, Kale, Anant, Kendrick, Lev Haldar, Xu, Muqing, Gang, Youqi, Nikolaenko, Alexander, Sachdev, Subir, and Greiner, Markus

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

Strongly correlated materials feature multiple electronic orbitals which are crucial to accurately understand their many-body properties, from cuprate materials to twisted bilayer graphene. In such multi-band models, quantum interference can lead to dispersionless bands whose large degeneracy gives rise to itinerant magnetism even with weak interactions. Here, we report on signatures of a ferrimagnetic state realized in a Lieb lattice at half-filling, characterized by antialigned magnetic moments with antiferromagnetic correlations, concomitant with a finite spin polarization. We demonstrate its robustness when increasing repulsive interactions from the non-interacting to the Heisenberg regime, and study its emergence when continuously tuning the lattice unit cell from a square to a Lieb geometry. Our work paves the way towards exploring exotic phases in related multi-orbital models such as quantum spin liquids in kagome lattices and heavy fermion behavior in Kondo models., Comment: 7+8 pages, 4+11 figures

Published

2024

12. Strong non-linear response of strange metals

Author

Kryhin, Serhii, Sachdev, Subir, and Volkov, Pavel A.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We show that nonlinear transport responses in strange metals are strong, larger by a factor of $E_F/T$ than in Fermi liquids. Within the two-dimensional Yukawa-Sachdev-Ye-Kitaev model of a Fermi surface with a spatially random coupling to a critical scalar, the third order conductivity is found to diverge as $1/T$ at low $T$, indicating the existence of a voltage-temperature scaling regime in the conductance. Its frequency and orientation dependence contains information on relaxation times of heat and electron distribution deformations, providing a new set of tools to characterize strange metals., Comment: 5 pages, 2 figures, 5 Supplemental Information sections

Published

2024

13. Quantum spin glasses and Sachdev-Ye-Kitaev models

Author

Sachdev, Subir

Subjects

High Energy Physics - Theory, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons

Abstract

A brief survey of some random quantum models with infinite-range couplings is presented. Insights from such models have led to advances in the quantum theory of charged black holes in spatial dimensions $d \geq 3$, and to a universal theory of strange metals in correlated electron materials in $d=2$; these are also briefly reviewed., Comment: 23 pages, 8 figures; Rapporteur presentation at the 29th Solvay conference, The Structure and Dynamics of Disordered Systems, October 2023, Brussels

Published

2024

14. Deconfined quantum criticality of nodal $d$-wave superconductivity, N\'eel order, and charge order on the square lattice at half-filling

Author

Christos, Maine, Shackleton, Henry, Sachdev, Subir, and Luo, Zhu-Xi

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity, High Energy Physics - Theory

Abstract

We consider a SU(2) lattice gauge theory on the square lattice, with a single fundamental complex fermion and a single fundamental complex boson on each lattice site. Projective symmetries of the gauge-charged fermions are chosen so that they match with those of the spinons of the $\pi$-flux spin liquid. Global symmetries of all gauge-invariant observables are chosen to match with those of the particle-hole symmetric electronic Hubbard model at half-filling. Consequently, both the fundamental fermion and fundamental boson move in an average background $\pi$-flux, their gauge-invariant composite is the physical electron, and eliminating gauge fields in a strong gauge-coupling expansion yields an effective extended Hubbard model for the electrons. The SU(2) gauge theory displays several confining/Higgs phases: a nodal $d$-wave superconductor, and states with N\'eel, valence-bond solid, charge, or staggered current orders. There are also a number of quantum phase transitions between these phases which are very likely described by 2+1 dimensional deconfined conformal gauge theories, and we present large flavor expansions for such theories. These include the phenomenologically attractive case of a transition between a conventional insulator with a charge gap and N\'eel order, and a conventional $d$-wave superconductor with gapless Bogoliubov quasiparticles at 4 nodal points in the Brillouin zone. We also apply our approach to the honeycomb lattice, where we find a bicritical point at the junction of N\'eel, valence bond solid (Kekul\'e), and Dirac semi-metal phases., Comment: 47 pages, 20 figures

Published

2024

15. Magneto-Thermoelectric Transport in Graphene Quantum Dot with Strong Correlations

Author

Anderson, Laurel E., Laitinen, Antti, Zimmerman, Andrew, Werkmeister, Thomas, Shackleton, Henry, Kruchkov, Alexander, Taniguchi, Takashi, Watanabe, Kenji, Sachdev, Subir, and Kim, Philip

Subjects

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

Abstract

Disorder at the etched edges of graphene quantum dots (GQD) enables random all-to-all interactions between localized charges in partially-filled Landau levels, providing a potential platform to realize the Sachdev-Ye-Kitaev (SYK) model. We use quantum Hall edge states in the graphene electrodes to measure electrical conductance and thermoelectric power across the GQD. We observe a rapid diminishing of electric conductance fluctuations and slowly decreasing thermoelectric power across the GQD with increasing temperature, consistent with recent theoretical predictions for the SYK regime., Comment: 6 pages, 4 main figures; supplement has 24 pages, 10 figures

Published

2024

16. Localization of overdamped bosonic modes and transport in strange metals

Author

Patel, Aavishkar A., Lunts, Peter, and Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Disordered Systems and Neural Networks

Abstract

A recent theory described strange metal behavior in a model of a Fermi surface coupled a two-dimensional quantum critical bosonic field with a spatially random Yukawa coupling. With the assumption of self-averaging randomness, similar to that in the Sachdev-Ye-Kitaev model, numerous observed properties of a strange metal were obtained for wide range of intermediate temperatures, including the linear-in-temperature resistivity. The Harris criterion implies that spatial fluctuations in the local position of the critical point must dominate at lower temperatures. For an $M$-component boson with $M \geq 2$, we use multiple graphics processing units (GPUs) to compute the real frequency spectrum of the boson propagator in a self-consistent mean-field treatment of the boson self-interactions, but an exact treatment of multiple realizations of the spatial randomness from the random boson mass. We find that Landau damping from the fermions leads to the emergence of the physics of the random transverse-field Ising model at low temperatures, as has been proposed by Hoyos, Kotabage, and Vojta. This regime is controlled by localized overdamped eigenmodes of the bosonic scalar field, also has a resistivity which is nearly linear-in-temperature, and extends into a `quantum critical phase' away from the quantum critical point, as observed in several cuprates. For the $M = 1$ Ising scalar, the mean-field treatment is not applicable, and so we use Hybrid Monte Carlo simulations running on multiple GPUs; we find a rounded transition and localization physics, with strange metal behavior in an extended region around the transition., Comment: 7+epsilon pages, 8 figures, and a supplement

Published

2023

17. Sign-problem-free effective models of triangular lattice quantum antiferromagnets

Author

Shackleton, Henry and Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The triangular lattice antiferromagnet with $S=1/2$ spins and nearest neighbor interactions is known to have long-range antiferromagnetic order, with nearest-neighbor spins at an angle of 120 degrees. Numerical studies of quantum phases proximate to this state have been limited to small systems because the of the sign-problem in Monte Carlo simulations in imaginary time. We propose an effective lattice model for quantum fluctuations of the antiferromagnetic order, and a sign-problem free Monte Carlo algorithm, enabling studies in large systems sizes. The model is a $\mathbb{Z}_2$ gauge theory coupled to gauge-charged scalars which have a relativistic dispersion in the continuum limit. Crucially, the gauge theory is odd, i.e. there is a static, background $\mathbb{Z}_2$ gauge charge on each site, accounting for the Berry phases of the half-odd-integer spins on each site. We present results of simulations on lattices of sizes up to $36 \times 36 \times 36$. Along with the antiferromagnetically ordered phase, our phase diagram has a valence bond solid state with a $\sqrt{12} \times \sqrt{12}$ unit cell, and a gapped $\mathbb{Z}_2$ spin liquid. Deconfined critical points or phases in intermediate regions are not ruled out by our present simulations., Comment: 36 pages, 8 figures

Published

2023

18. Conductance and thermopower fluctuations in interacting quantum dots

Author

Shackleton, Henry, Anderson, Laurel E., Kim, Philip, and Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Mesoscale and Nanoscale Physics, High Energy Physics - Theory

Abstract

We model an interacting quantum dot of electrons by a Hamiltonian with random and all-to-all single particle hopping (of r.m.s. strength $t$) and two-particle interactions (of r.m.s. strength $J$). For $t \ll J$, such a model has a regime exhibiting the non-quasiparticle physics of the Sachdev-Ye-Kitaev model at temperatures $E_{\rm coh} \ll T \ll J$, and that of a renormalized Fermi liquid at $T \ll E_{\rm coh}$, where $E_{\rm coh} = t^2 / J$. Extending earlier work has computed the mean thermoelectric properties of such a dot weakly coupled to two external leads, we compute the sample-to-sample fluctuations in the conductance and thermopower of such a dot, and describe several distinct regimes. In all cases, the effect of the SYK interactions is to reduce the strength of the sample-to-sample fluctuations. We also find that in the regime where the mean transport co-efficients are determined only by the value of $J$ at leading order, the sample-to-sample fluctuations can be controlled by the influence of the smaller $t$., Comment: 39 pages, 11 figures

Published

2023

19. Equilibrium dynamics of infinite-range quantum spin glasses in a field

Author

Tikhanovskaya, Maria, Sachdev, Subir, and Samajdar, Rhine

Subjects

Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons, Mathematical Physics, Quantum Physics

Abstract

We determine the low-energy spectrum and Parisi replica symmetry breaking function for the spin glass phase of the quantum Ising model with infinite-range random exchange interactions and transverse and longitudinal ($h$) fields. We show that, for all $h$, the spin glass state has full replica symmetry breaking, and the local spin spectrum is gapless with a spectral density which vanishes linearly with frequency. These results are obtained using an action functional$\unicode{x2014}$argued to yield exact results at low frequencies$\unicode{x2014}$that expands in powers of a spin glass order parameter, which is is bilocal in time, and a matrix in replica space. We also present the exact solution of the infinite-range spherical quantum $p$-rotor model at nonzero $h$: here, the spin glass state has one-step replica symmetry breaking, and gaplessness only appears after imposition of an additional marginal stability condition. Possible connections to experiments on random arrays of trapped Rydberg atoms are noted., Comment: 49 pages, 13 figures

Published

2023

20. Connecting the Many-Body Chern Number to Luttinger's Theorem through St\v{r}eda's Formula

Author

Gavensky, Lucila Peralta, Sachdev, Subir, and Goldman, Nathan

Subjects

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

Abstract

Relating the quantized Hall response of correlated insulators to many-body topological invariants is a key challenge in topological quantum matter. Here, we use Streda's formula to derive an expression for the many-body Chern number in terms of the single-particle interacting Green's function and its derivative with respect to a magnetic field. In this approach, we find that this many-body topological invariant can be decomposed in terms of two contributions, $N_3[G] + \Delta N_3[G]$, where $N_3[G]$ is known as the Ishikawa-Matsuyama invariant and where the second term involves derivatives of Green's function and the self energy with respect to the magnetic perturbation. As a by-product, the invariant $N_3[G]$ is shown to stem from the derivative of Luttinger's theorem with respect to the probe magnetic field. These results reveal under which conditions the quantized Hall conductivity of correlated topological insulators is solely dictated by the invariant $N_3[G]$, providing new insight on the origin of fractionalization in strongly-correlated topological phases., Comment: 6 pages

Published

2023

21. Emergence of nodal Bogoliubov quasiparticles across the transition from the pseudogap metal to the d-wave superconductor

Author

Christos, Maine and Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity

Abstract

We model the pseudogap state of the hole- and electron-doped cuprates as a metal with hole and/or electron pocket Fermi surfaces. In the absence of long-range antiferromagnetism, such Fermi surfaces violate the Luttinger requirement of enclosing the same area as free electrons at the same density. Using the Ancilla theory of such a pseudogap state, we describe the onset of conventional $d$-wave superconductivity by the condensation of a charge e Higgs boson transforming as a fundamental under the emergent SU(2) gauge symmetry of a background $\pi$-flux spin liquid. In all cases, we find that the $d$-wave superconductor has gapless Bogoliubov quasiparticles at 4 nodal points on the Brillouin zone diagonals with significant velocity anisotropy, just as in the BCS state. This includes the case of the electron-doped pseudogap metal with only electron pockets centered at wavevectors $(\pi, 0)$, $(0, \pi)$, and an electronic gap along the zone diagonals. Remarkably, in this case too, gapless nodal Bogoliubov quasiparticles emerge within the gap at 4 points along the zone diagonals upon the onset of superconductivity., Comment: 17 pages, 14 Figures

Published

2023

22. Cyclotron resonance and quantum oscillations of critical Fermi surfaces

Author

Guo, Haoyu, Valentinis, Davide, Schmalian, Jörg, Sachdev, Subir, and Patel, Aavishkar A.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Kohn's theorem places strong constraints on the cyclotron response of Fermi liquids. Recent observations of a doping dependence in the cyclotron mass of La$_{2-x}$Sr$_x$CuO$_4$ (Legros et al., Phys. Rev. B 106, 195110 (2022)) are therefore surprising because the cyclotron mass can only be renormalized by large momentum umklapp interactions which are not expected to vary significantly with doping. We show that a version of Kohn's theorem continues to apply to disorder-free non-Fermi liquids with a critical boson near zero momentum. However, marginal Fermi liquids arising from a spatially random Yukawa coupling between the electrons and bosons do give rise to significant corrections to the cyclotron mass which we compute. This is the same theory which yields linear-in-temperature resistivity and other properties of strange metals at zero fields (Patel et al., Science 381, 790 (2023))., Comment: 55 pages, 29 figures. (v2) Added new authors and new results. (v3) added panel (b) for Fig.15

Published

2023

23. Disordered quantum critical fixed points from holography

Author

Huang, Xiaoyang, Sachdev, Subir, and Lucas, Andrew

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

Using holographic duality, we present an analytically controlled theory of quantum critical points without quasiparticles, at finite disorder and finite charge density. These fixed points are obtained by perturbing a disorder-free quantum critical point with relevant disorder whose operator dimension is perturbatively close to Harris marginal. We analyze these fixed points both using field theoretic arguments, and by solving the bulk equations of motion in holography. We calculate the critical exponents of the IR theory, together with thermoelectric transport coefficients. Our predictions for the critical exponents of the disordered fixed point are consistent with previous work, both in holographic and nonholograpic models., Comment: 5+14 pages

Published

2023

24. Hidden orders and phase transitions for the fully packed quantum loop model on the triangular lattice

Author

Ran, Xiaoxue, Yan, Zheng, Wang, Yan-Cheng, Samajdar, Rhine, Rong, Junchen, Sachdev, Subir, Qi, Yang, and Meng, Zi Yang

Published

2024

25. Emergence of nodal Bogoliubov quasiparticles across the transition from the pseudogap metal to the d-wave superconductor

Author

Christos, Maine and Sachdev, Subir

Published

2024

26. Theory of shot noise in strange metals

Author

Nikolaenko, Alexander, Sachdev, Subir, and Patel, Aavishkar A.

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We extend the theory of shot noise in coherent metals to shot noise in strange metals without quasiparticle excitations. This requires a generalization of the Boltzmann equation with a noise source to distribution functions which depend independently on the excitation momentum and energy. We apply this theory to a model of a strange metal with linear in temperature ($T$) resistivity, describing a Fermi surface with a spatially random Yukawa coupling to a critical boson. We find a suppression of the Fano factor in the strange metal, and describe the dependence of the shot noise on temperature and applied voltage. At low temperatures, we obtain a Fano factor equal to $1/6$, in contrast to the $1/3$ Fano factor in diffusive metals with quasiparticles. Our results are in general agreement with recent observations by Chen et al. (arXiv:2206.00673). We further compare the random Yukawa model to quasi-elastic electron-phonon scattering that also generates $T$-linear resistivity, and argue that shot noise observations offer a useful diagnostic to distinguish between them., Comment: 30 pages, 3 figures

Published

2023

27. Strange metals and black holes: insights from the Sachdev-Ye-Kitaev model

Author

Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

Complex many-particle quantum entanglement is a central theme in two distinct major topics in physics: the strange metal state found in numerous correlated electron compounds, and the quantum theory of black holes in Einstein gravity. The Sachdev-Ye-Kitaev model provides a solvable theory of entangled many-particle quantum states without quasiparticle excitations. This article reviews how this toy model has led to realistic universal models of strange metals, and to new insights on the quantum states of black holes., Comment: 31 pages, 11 figures; Some of the introductory discussion in this article overlaps with the review in arXiv:2205.02285; companion article on black holes is arXiv:2304.13744

Published

2023

28. Quantum statistical mechanics of the Sachdev-Ye-Kitaev model and charged black holes

Author

Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons, General Relativity and Quantum Cosmology, High Energy Physics - Theory, Quantum Physics

Abstract

This review is a contribution to a book dedicated to the memory of Michael E. Fisher. The first example of a quantum many body system not expected to have any quasiparticle excitations was the Wilson-Fisher conformal field theory. The absence of quasiparticles can be established in the compressible, metallic state of the Sachdev-Ye-Kitaev model of fermions with random interactions. The solvability of the latter model has enabled numerous computations of the non-quasiparticle dynamics of chaotic many-body states, such as those expected to describe quantum black holes. We review thermodynamic properties of the SYK model, and describe how they have led to an understanding of the universal structure of the low energy density of states of charged black holes without low energy supersymmetry., Comment: 28 pages, 10 figures; Published in "50 years of the renormalization group", https://doi.org/10.1142/13571 , dedicated to the memory of Michael E. Fisher, edited by Amnon Aharony, Ora Entin-Wohlman, David Huse, and Leo Radzihovsky, World Scientific; companion article on strange metals is arXiv:2305.01001

Published

2023

29. Nodal band-off-diagonal superconductivity in twisted graphene superlattices

Author

Christos, Maine, Sachdev, Subir, and Scheurer, Mathias S.

Subjects

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

Abstract

The superconducting state and mechanism are among the least understood phenomena in twisted graphene systems. For instance, recent tunneling experiments indicate a transition between nodal and gapped pairing with electron filling, which is not naturally understood within current theory. We demonstrate that the coexistence of superconductivity and flavor polarization leads to pairing channels that are guaranteed by symmetry to be entirely band-off-diagonal, with a variety of unusual consequences: most notably, the pairing invariant under all symmetries can have protected nodal lines or be fully gapped, depending on parameters, and the band-off-diagonal chiral d-wave state exhibits transitions between gapped and nodal regions upon varying the chemical potential. We demonstrate that nodal band-off-diagonal pairing can be the leading state when only phonons are considered, and is also uniquely favored by fluctuations of a time-reversal-symmetric intervalley-coherent order motivated by recent experiments. Consequently, band-off-diagonal superconductivity allows for the reconciliation of several key experimental observations in graphene moir\'e systems., Comment: 21 pages, 7 figures

Published

2023

30. A model of $d$-wave superconductivity, antiferromagnetism, and charge order on the square lattice

Author

Christos, Maine, Luo, Zhu-Xi, Shackleton, Henry, Zhang, Ya-Hui, Scheurer, Mathias, and Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Superconductivity, High Energy Physics - Theory

Abstract

Early studies proposed a connection between cuprate superconductivity and fractionalized spin liquid states. But the low temperature phase diagram is dominated by states without fractionalization, with a competition between superconductivity and charge-ordered states which break translational symmetry. Our theory uncovers novel features associated with a particular spin-liquid presumed to underlie the pseudogap metal, and shows that it has multiple nearly-degenerate instabilities to confinement of fractionalized excitations, leading to antiferromagnetism, $d$-wave superconductivity, and/or charge order. Our theory provides routes to resolving a number of open puzzles on the cuprate phase diagram. The spin liquid is described by a SU(2) gauge theory of $N_f=2$ massless fundamental Dirac fermions, has an emergent SO(5)$_f$ global symmetry, and is presumed to confine at low energies to the N\'eel state. At non-zero doping (or smaller Hubbard repulsion at half-filling) we argue that confinement occurs via the Higgs condensation of bosonic chargons carrying fundamental SU(2) gauge charges moving in $\pi$ flux. At half-filling, the low energy Higgs sector has $N_b=2$ relativistic bosons with a possible emergent SO(5)$_b$ global symmetry describing rotations between a $d$-wave superconductor, period-2 charge stripes, and the time-reversal breaking `$d$-density wave' state. We propose a deconfined quantum critical point between a confining state which breaks SO(5)$_f$ and a confining state which breaks SO(5)$_b$. The pattern of symmetry breaking within both SO(5)s is determined by terms likely irrelevant at the critical point, which can be chosen to obtain a transition between N\'eel order and $d$-wave superconductivity. A similar theory applies at non-zero doping and large $U$, with longer-range couplings of the chargons leading to charge order with longer periods., Comment: 10+9 pages, 10+5 figures; v4 Added Ya-Hui Zhang as co-author

Published

2023

31. Emergent glassy behavior in a kagome Rydberg atom array

Author

Yan, Zheng, Wang, Yan-Cheng, Samajdar, Rhine, Sachdev, Subir, and Meng, Zi Yang

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics, Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

We present large-scale quantum Monte Carlo simulation results on a realistic Hamiltonian of kagome-lattice Rydberg atom arrays. Although the system has no intrinsic disorder, intriguingly, our analyses of static and dynamic properties on large system sizes reveal \textit{emergent} glassy behavior in a region of parameter space located between two valence bond solid phases. The extent of this glassy region is demarcated using the Edwards-Anderson order parameter, and its phase transitions to the two proximate valence bond solids -- as well as the crossover towards a trivial paramagnetic phase -- are identified. We demonstrate the intrinsically slow (imaginary) time dynamics deep inside the glassy phase and discuss experimental considerations for detecting such a quantum disordered phase with numerous nearly degenerate local minima. Our proposal paves a new route to the study of real-time glassy phenomena and highlights the potential for quantum simulation of a distinct phase of quantum matter beyond solids and liquids in current-generation Rydberg platforms., Comment: 7+4 pages, 4+5 figures

Published

2023

32. Classifying topological neural network quantum states via diffusion maps

Author

Teng, Yanting, Sachdev, Subir, and Scheurer, Mathias S.

Subjects

Quantum Physics, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Strongly Correlated Electrons

Abstract

We discuss and demonstrate an unsupervised machine-learning procedure to detect topological order in quantum many-body systems. Using a restricted Boltzmann machine to define a variational ansatz for the low-energy spectrum, we sample wave functions with probability decaying exponentially with their variational energy; this defines our training dataset that we use as input to a diffusion map scheme. The diffusion map provides a low-dimensional embedding of the wave functions, revealing the presence or absence of superselection sectors and, thus, topological order. We show that for the diffusion map, the required similarity measure of quantum states can be defined in terms of the network parameters, allowing for an efficient evaluation within polynomial time. However, possible ''gauge redundancies'' have to be carefully taken into account. As an explicit example, we apply the method to the toric code., Comment: 18 pages, 10 figures

Published

2023

33. Spin density wave, Fermi liquid, and fractionalized phases in a theory of antiferromagnetic metals using paramagnons and bosonic spinons

Author

Nikolaenko, Alexander, von Milczewski, Jonas, Joshi, Darshan G., and Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

The pseudogap metal phase of the hole-doped cuprates can be described by small Fermi surfaces of electron-like quasiparticles, which enclose a volume violating the Luttinger relation. This violation requires the existence of additional fractionalized excitations which can be viewed as fractionalized remnants of the paramagnon. We fractionalize the paramagnon into bosonic spinons, and present a gauge theory of bosonic spinons, a Higgs field, and an ancilla layer of fermions coupled to the original electrons. Along with the small Fermi surface metal, this theory displays conventional phases: the Fermi liquid with a low-energy paramagnon mode, and phases with spin density wave order. We follow the evolution of the electronic photoemission spectrum across these quantum phase transitions. We consider both the two-sublattice N\'eel and incommensurate spin density wave phases., Comment: 36 pages, 16 figures; (v5) Improved figures and added clarifications; (v6) Added Appendix B on connection to theories of holon metals; this appendix is not in the PRB version

Published

2022

34. Superconductivity of non-Fermi liquids described by Sachdev-Ye-Kitaev models

Author

Li, Chenyuan, Sachdev, Subir, and Joshi, Darshan G.

Subjects

Condensed Matter - Superconductivity, Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

We investigate models of electrons in the Sachdev-Ye-Kitaev class with random and all-to-all electron hopping, electron spin exchange, and Cooper-pair hopping. An attractive on-site interaction between electrons leads to superconductivity at low temperatures. Depending on the relative strengths of the hopping and spin exchange, the normal state at the critical temperature is either a Fermi-liquid or a non-Fermi liquid. We present a large-$M$ (where spin symmetry is enlarged to SU$(M)$) study of the normal state to superconductor phase transition. We describe the transition temperature, the superconducting order parameter, and the electron spectral functions. We contrast between Fermi liquid and non-Fermi liquid normal states: we find that for weaker attractive on-site interaction there is a relative enhancement of $T_c$ when the normal state is a non-Fermi liquid, and correspondingly a strong deviation from BCS limit. Also, the phase transition in this case becomes a first-order transition for strong non-Fermi liquids. On the other hand, for stronger on-site interaction, there is no appreciable difference in $T_c$ between whether the superconductivity emerges from a Fermi liquid or a non-Fermi liquid. Notable features of superconductivity emerging from a non-Fermi liquid are that the superconducting electron spectral function is different from the Fermi-liquid case, with additional peaks at higher energies, and there is no Hebel-Slichter peak in the NMR relaxation rate in the non-Fermi liquid case., Comment: 26 pages, 13 figures; (v2) Added new results, figures, and references, modified abstract, and expanded discussion

Published

2022

35. Engineering SYK interactions in disordered graphene flakes under realistic experimental conditions

Author

Brzezinska, Marta, Guan, Yifei, Yazyev, Oleg V., Sachdev, Subir, and Kruchkov, Alexander

Subjects

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

Abstract

We model SYK (Sachdev-Ye-Kitaev) interactions in disordered graphene flakes up to 300 000 atoms ($\sim$100 nm in diameter) subjected to an out-of-plane magnetic field $B$ of 5-20 Tesla within the tight-binding formalism. We investigate two sources of disorder: (i) irregularities at the system boundaries, and (ii) bulk vacancies, -- for a combination of which we find conditions which could be favorable for the formation of the phase with SYK features under realistic experimental conditions above the liquid helium temperature., Comment: 6 pages, 4 figures

Published

2022

36. Large $N$ theory of critical Fermi surfaces II: conductivity

Author

Guo, Haoyu, Patel, Aavishkar A., Esterlis, Ilya, and Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

A Fermi surface coupled to a scalar field can be described in a $1/N$ expansion by choosing the fermion-scalar Yukawa coupling to be random in the $N$-dimensional flavor space, but invariant under translations. We compute the conductivity of such a theory in two spatial dimensions for a critical scalar. We find a Drude contribution, and verify that the proposed $1/\omega^{2/3}$ contribution to the optical conductivity at frequency $\omega$ has vanishing co-efficient for a convex Fermi surface. We also describe the influence of impurity scattering of the fermions, and find that while the self energy resembles a marginal Fermi liquid, the resistivity and optical conductivity behave like a Fermi liquid., Comment: 50 pages, 1 figure. This analysis appeared originally in the supplement of arXiv:2203.04990, and has now been extracted into this paper. Part I is arXiv:2103.08615. (v4) Added references. (v5) Added appendix showing cancellation of diagrams. Added reference to arXiv:2208.04328. (v8) Fixed typo

Published

2022

37. Hidden orders and phase transitions for the fully packed quantum loop model on the triangular lattice

Author

Ran, Xiaoxue, Yan, Zheng, Wang, Yan-Cheng, Samajdar, Rhine, Rong, Junchen, Sachdev, Subir, Qi, Yang, and Meng, Zi Yang

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Statistical Mechanics, High Energy Physics - Theory, Physics - Atomic Physics, Quantum Physics

Abstract

Quantum loop and dimer models are prototypical correlated systems with local constraints, which are not only intimately connected to lattice gauge theories and topological orders but are also widely applicable to the broad research areas of quantum materials and quantum simulation. Employing our sweeping cluster quantum Monte Carlo algorithm, we reveal the complete phase diagram of the triangular-lattice fully packed quantum loop model. Apart from the known lattice nematic (LN) solid and the even $\mathbb{Z}_2$ quantum spin liquid (QSL) phases, we discover a hidden vison plaquette (VP) phase, which had been overlooked and misinterpreted as a QSL for more than a decade. Moreover, the VP-to-QSL continuous transition belongs to the $(2+1)$D cubic* universality class, which offers a lattice realization of the (fractionalized) cubic fixed point that had long been considered as irrelevant towards the O($3$) symmetry until corrected recently by conformal bootstrap calculations. Our results are therefore of relevance to recent developments in both experiments and theory, and facilitate further investigations of hidden phases and transitions., Comment: 11+7 pages, 6+5 figures

Published

2022

38. Statistical mechanics of strange metals and black holes

Author

Sachdev, Subir

Subjects

High Energy Physics - Theory, Condensed Matter - Strongly Correlated Electrons

Abstract

A colloquium style review of the connections between the Sachdev-Ye-Kitaev model and strange metals without quasiparticles, and between the SYK model and the quantum properties of black holes. Along with other insights, this connection has led to an understanding of the universal form of the low energy density of states of charged black holes in asymptotically 3+1 dimensional Minkowski space., Comment: 18 pages, 6 figures. published in ICTS News, newsletter of the International Centre for Theoretical Sciences, Tata Institute of Fundamental Research; (v6) additional comments which include the results of arXiv:2209.13608; (v7) small improvements

Published

2022

39. Emergent $\mathbb{Z}_2$ gauge theories and topological excitations in Rydberg atom arrays

Author

Samajdar, Rhine, Joshi, Darshan G., Teng, Yanting, and Sachdev, Subir

Subjects

Condensed Matter - Quantum Gases, Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory, Quantum Physics

Abstract

Strongly interacting arrays of Rydberg atoms provide versatile platforms for exploring exotic many-body phases and dynamics of correlated quantum systems. Motivated by recent experimental advances, we show that the combination of Rydberg interactions and appropriate lattice geometries naturally leads to emergent $\mathbb{Z}_2$ gauge theories endowed with matter fields. Based on this mapping, we describe how Rydberg platforms could realize two distinct classes of topological $\mathbb{Z}_2$ quantum spin liquids, which differ in their patterns of translational symmetry fractionalization. We also discuss the natures of the fractionalized excitations of these $\mathbb{Z}_2$ spin liquid states using both fermionic and bosonic parton theories, and illustrate their rich interplay with proximate solid phases., Comment: 6+14 pages, 4+6 figures

Published

2022

40. Critical metallic phase in the overdoped random $t$-$J$ model

Author

Christos, Maine, Joshi, Darshan G., Sachdev, Subir, and Tikhanovskaya, Maria

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

We investigate a model of electrons with random and all-to-all hopping and spin exchange interactions, with a constraint of no double occupancy. The model is studied in a Sachdev-Ye-Kitaev-like large-$M$ limit with SU($M$) spin symmetry. The saddle point equations of this model are similar to appoximate dynamic mean field equations of realistic, non-random, $t$-$J$ models. We use numerical studies on both real and imaginary frequency axes, along with asymptotic analyses, to establish the existence of a critical non-Fermi-liquid metallic ground state at large doping, with the spin correlation exponent varying with doping. This critical solution possesses a time-reparametrization symmetry, akin to SYK models, which contributes a linear-in-temperature resistivity over the full range of doping where the solution is present. It is therefore an attractive mean-field description of the overdoped region of cuprates, where experiments have observed a linear-$T$ resistivity in a broad region. The critical metal also displays a strong particle-hole asymmetry, which is relevant to Seebeck coefficient measurements. We show that the critical metal has an instability to a low-doping spin-glass phase, and compute a critical doping value. We also describe the properties of this metallic spin-glass phase., Comment: Main: 8 pages, 8 figures; SI: 17 pages, 13 figures. v2: several corrections and modifications. PNAS format

Published

2022

41. Universal theory of strange metals from spatially random interactions

Author

Patel, Aavishkar A., Guo, Haoyu, Esterlis, Ilya, and Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

We consider two-dimensional metals of fermions coupled to quantum critical scalars, the latter representing order parameters or emergent gauge fields. We show that at low temperatures ($T$), such metals generically exhibit strange metal behavior with a $T$-linear resistivity arising from spatially random fluctuations in the fermion-scalar Yukawa couplings about a non-zero spatial average. We also find a $T\ln (1/T)$ specific heat, and a rationale for the Planckian bound on the transport scattering time. These results are obtained in the large $N$ expansion of an ensemble of critical metals., Comment: 7 pages (including references), 1 figure, and a 11 page supplement; (v3) Analysis of cases without spatially random interactions in the supplement has been removed to improve readability, and now appears in arXiv:2207.08841; Summary poster at http://qpt.physics.harvard.edu/talks/aptos22.pdf; To be published in Science

Published

2022

42. Anisotropic deconfined criticality in Dirac spin liquids

Author

Shackleton, Henry and Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

We analyze a Higgs transition from a U(1) Dirac spin liquid to a gapless $\mathbb{Z}_2$ spin liquid. This $\mathbb{Z}_2$ spin liquid is of relevance to the spin $S=1/2$ square lattice antiferromagnet, where recent numerical studies have given evidence for such a phase existing in the regime of high frustration between nearest neighbor and next-nearest neighbor antiferromagnetic interactions (the $J_1$-$J_2$ model), appearing in a parameter regime between the vanishing of N\'eel order and the onset of valence bond solid ordering. The proximate Dirac spin liquid is unstable to monopole proliferation on the square lattice, ultimately leading to N\'eel or valence bond solid ordering. As such, we conjecture that this Higgs transition describes the critical theory separating the gapless $\mathbb{Z}_2$ spin liquid of the $J_1$-$J_2$ model from one of the two proximate ordered phases. The transition into the other ordered phase can be described in a unified manner via a transition into an unstable SU(2) spin liquid, which we have analyzed in prior work. By studying the deconfined critical theory separating the U(1) Dirac spin liquid from the gapless $\mathbb{Z}_2$ spin liquid in a $1/N_f$ expansion, with $N_f$ proportional to the number of fermions, we find a stable fixed point with an anisotropic spinon dispersion and a dynamical critical exponent $z \neq 1$. We analyze the consequences of this anisotropic dispersion by calculating the angular profiles of the equal-time N\'eel and valence bond solid correlation functions, and we find them to be distinct. We also note the influence of the anisotropy on the scaling dimension of monopoles., Comment: 42 pages, 6 figures

Published

2022

43. Triangular lattice quantum dimer model with variable dimer density

Author

Yan, Zheng, Samajdar, Rhine, Wang, Yan-Cheng, Sachdev, Subir, and Meng, Zi Yang

Subjects

Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Statistical Mechanics, Physics - Atomic Physics, Quantum Physics

Abstract

Quantum dimer models are known to host topological quantum spin liquid phases, and it has recently become possible to simulate such models with Rydberg atoms trapped in arrays of optical tweezers. Here, we present large-scale quantum Monte Carlo simulation results on an extension of the triangular lattice quantum dimer model with terms in the Hamiltonian annihilating and creating single dimers. We find distinct odd and even $\mathbb{Z}_2$ spin liquids, along with several phases with no topological order: a staggered crystal, a nematic phase, and a trivial symmetric phase with no obvious broken symmetry. We also present dynamic spectra of the phases, and note implications for experiments on Rydberg atoms.

Published

2022

44. Quantum Optimization of Maximum Independent Set using Rydberg Atom Arrays

Author

Ebadi, Sepehr, Keesling, Alexander, Cain, Madelyn, Wang, Tout T., Levine, Harry, Bluvstein, Dolev, Semeghini, Giulia, Omran, Ahmed, Liu, Jinguo, Samajdar, Rhine, Luo, Xiu-Zhe, Nash, Beatrice, Gao, Xun, Barak, Boaz, Farhi, Edward, Sachdev, Subir, Gemelke, Nathan, Zhou, Leo, Choi, Soonwon, Pichler, Hannes, Wang, Shengtao, Greiner, Markus, Vuletic, Vladan, and Lukin, Mikhail D.

Subjects

Quantum Physics, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Quantum Gases, Physics - Atomic Physics

Abstract

Realizing quantum speedup for practically relevant, computationally hard problems is a central challenge in quantum information science. Using Rydberg atom arrays with up to 289 qubits in two spatial dimensions, we experimentally investigate quantum algorithms for solving the Maximum Independent Set problem. We use a hardware-efficient encoding associated with Rydberg blockade, realize closed-loop optimization to test several variational algorithms, and subsequently apply them to systematically explore a class of graphs with programmable connectivity. We find the problem hardness is controlled by the solution degeneracy and number of local minima, and experimentally benchmark the quantum algorithm's performance against classical simulated annealing. On the hardest graphs, we observe a superlinear quantum speedup in finding exact solutions in the deep circuit regime and analyze its origins., Comment: 10 pages, 5 figures, Supplementary materials at the end

Published

2022

45. Maximal quantum chaos of the critical Fermi surface

Author

Tikhanovskaya, Maria, Sachdev, Subir, and Patel, Aavishkar A.

Subjects

Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory

Abstract

We investigate the many-body quantum chaos of non-Fermi liquid states with Fermi surfaces in two spatial dimensions by computing their out-of-time-order correlation functions. Using a recently proposed large $N$ theory for the critical Fermi surface, and the ladder identity of Gu and Kitaev, we show that the chaos Lyapunov exponent takes the maximal value of $2 \pi k_B T/\hbar$, where $T$ is the absolute temperature. We also examine a phenomenological model in which the chaos exponent becomes smaller than the maximal value precisely when quasiparticles are restored., Comment: Updated with more information on the phenomenological model and other minor corrections and clarifications. Main manuscript 6 pages, SI 9 pages

Published

2022

46. Resonant thermal Hall effect of phonons coupled to dynamical defects

Author

Guo, Haoyu, Joshi, Darshan G., and Sachdev, Subir

Subjects

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

Abstract

We present computations of the thermal Hall coefficient of phonons scattering off a defect with multiple energy levels. Using a microscopic formulation based on the Kubo formula, we find that the leading contribution perturbative in the phonon-defect coupling is proportional to the phonon lifetime, and has a `side-jump' interpretation. Consequently, the thermal Hall angle is independent of the phonon lifetime. The contribution to the thermal Hall coefficient is at resonance when the phonon energy equals a defect level spacing. Our results are obtained for three different defect models, which apply to different correlated electron materials. For the pseudogap regime of the cuprates, we propose a model of phonons coupled to an impurity quantum spin in the presence of quasi-static magnetic order with an isotropic Zeeman coupling to the applied field, and without spin-orbit interaction., Comment: 7 pages, 3 figures

Published

2022

47. Machine learning discovery of new phases in programmable quantum simulator snapshots

Author

Miles, Cole, Samajdar, Rhine, Ebadi, Sepehr, Wang, Tout T., Pichler, Hannes, Sachdev, Subir, Lukin, Mikhail D., Greiner, Markus, Weinberger, Kilian Q., and Kim, Eun-Ah

Subjects

Quantum Physics, Condensed Matter - Quantum Gases, Condensed Matter - Strongly Correlated Electrons, Computer Science - Machine Learning

Abstract

Machine learning has recently emerged as a promising approach for studying complex phenomena characterized by rich datasets. In particular, data-centric approaches lend to the possibility of automatically discovering structures in experimental datasets that manual inspection may miss. Here, we introduce an interpretable unsupervised-supervised hybrid machine learning approach, the hybrid-correlation convolutional neural network (Hybrid-CCNN), and apply it to experimental data generated using a programmable quantum simulator based on Rydberg atom arrays. Specifically, we apply Hybrid-CCNN to analyze new quantum phases on square lattices with programmable interactions. The initial unsupervised dimensionality reduction and clustering stage first reveals five distinct quantum phase regions. In a second supervised stage, we refine these phase boundaries and characterize each phase by training fully interpretable CCNNs and extracting the relevant correlations for each phase. The characteristic spatial weightings and snippets of correlations specifically recognized in each phase capture quantum fluctuations in the striated phase and identify two previously undetected phases, the rhombic and boundary-ordered phases. These observations demonstrate that a combination of programmable quantum simulators with machine learning can be used as a powerful tool for detailed exploration of correlated quantum states of matter., Comment: 9 pages, 5 figures + 12 pages, 10 figures appendix

Published

2021

48. Bulk and Boundary Quantum Phase Transitions in a Square Rydberg Atom Array

Author

Kalinowski, Marcin, Samajdar, Rhine, Melko, Roger G., Lukin, Mikhail D., Sachdev, Subir, and Choi, Soonwon

Subjects

Quantum Physics, Condensed Matter - Quantum Gases

Abstract

Motivated by recent experimental realizations of exotic phases of matter on programmable quantum simulators, we carry out a comprehensive theoretical study of quantum phase transitions in a Rydberg atom array on a square lattice, with both open and periodic boundary conditions. In the bulk, we identify several first-order and continuous phase transitions by performing large-scale quantum Monte Carlo simulations and develop an analytical understanding of the nature of these transitions using the framework of Landau-Ginzburg-Wilson theory. Remarkably, we find that under open boundary conditions, the boundary itself undergoes a second-order quantum phase transition, independent of the bulk. These results explain recent experimental observations and provide important new insights into both the adiabatic state preparation of novel quantum phases and quantum optimization using Rydberg atom array platforms., Comment: 6+10 pages

Published

2021

49. Quasiparticle metamorphosis in the random t-J model

Author

Kumar, Aman, Sachdev, Subir, and Tripathi, Vikram

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

Motivated by the pseudogap-Fermi liquid transition in doped Mott insulators, we examine the excitations of a $t$-$J$ model with random and all-to-all hopping and exchange. The stability of quasiparticles such as spin-1/2 fermions, spin-1 magnons, and emergent Jordan-Wigner (JW) spinless fermions is cast as a problem of localization in the many-body Hilbert space, which is studied by the FEAST eigensolver algorithm. At low dopings, magnons and JW fermions are better defined than spin-1/2 fermions, which are unstable. Upon crossing a critical value of doping around $p_c$ = 1/3, their stabilities are interchanged. Near the critical doping, these quasiparticles are all found to be ill-defined. The critical point is thus associated with a localization transition in the many-body Hilbert space, Comment: 7 pages, 6 figures

Published

2021

50. Electronic spectra with paramagnon fractionalization in the single band Hubbard model

Author

Mascot, Eric, Nikolaenko, Alexander, Tikhanovskaya, Maria, Zhang, Ya-Hui, Morr, Dirk K., and Sachdev, Subir

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We examine the spectral properties of a recently proposed theory of the intermediate temperature pseudogap metal phase of the cuprates. We show that this theory can be obtained from the familiar paramagnon theory of nearly antiferromagnetic metals by fractionalizing the paramagnon into two `hidden' layers of S=1/2 spins. The first hidden layer of spins hybridizes with the electrons as in a Kondo lattice heavy Fermi liquid, while the second hidden layer of spins forms a spin liquid with fractionalized spinon excitations. We compute the imaginary part of the electronic self energy induced by the spinon excitations. The energy and momentum dependence of the photoemission spectrum across the Brillouin zone provides a good match to observations by He et al. in Bi2201 (Science 331, 1579 (2011)) and by Chen et al. in Bi2212 (Science 366, 1099 (2019))., Comment: 33 pages, 15 figures

Published

2021