Person: Punk, Matthias
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Punk
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Matthias
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Punk, Matthias
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Publication Topological excitations and the dynamic structure factor of spin liquids on the kagome lattice(Nature Publishing Group, 2014) Punk, Matthias; Chowdhury, Debanjan; Sachdev, SubirRecent neutron scattering experiments on the spin-1/2 kagome lattice antiferromagnet ZnCu\(_3\)(OH)\(_6\)C\(_{12}\) (Herbertsmithite) provide the first evidence of fractionalized excitations in a quantum spin liquid state in two spatial dimensions. In contrast to existing theoretical models of spin liquids, the measured dynamic structure factor reveals an excitation continuum which is remarkably at as a function of frequency and has almost no momentum dependence along several high-symmetry directions. Here we show that many experimentally observed features can be explained by the presence of topological vison excitations in a Z\(_2\) spin liquid. These visons form at bands on the kagome lattice, and thus act as a momentum sink for spin-carrying excitations which are probed by neutron scattering. We compute the dynamic structure factor for two di fferent Z\(_2\) spin liquids and find that one of them describes Herbertsmithite well above a very low energy cutoff.Publication Mobile impurity near the superfluid–Mott-insulator quantum critical point in two dimensions(American Physical Society, 2013) Punk, Matthias; Sachdev, SubirWe consider bosonic atoms in an optical lattice at integer filling, tuned to the superfluid-Mott insulator critical point, and coupled to a single, mobile impurity atom of a di↵erent species. This setup is inspired by current experiments with quantum gas microscopes, which enable tracking of the impurity motion. We describe the evolution of the impurity motion from quantum wave packet spread at short times, to Brownian diffusion at long times. This dynamics is controlled by the interplay between dangerously irrelevant perturbations at the strongly-interacting field theory describing the superfluid-insulator transition in two spatial dimensions.Publication Optical Conductivity of Visons in Z_{2} Spin Liquids Close to a Valence Bond Solid Transition on the Kagome Lattice(American Physical Society (APS), 2013) Huh, Yejin; Punk, Matthias; Sachdev, SubirWe consider Z2 spin liquids on the kagome lattice on the verge of a valence bond solid (VBS) transition, where vortex excitations carrying Z2 magnetic flux—so-called visons—condense. We show that these vison excitations can couple directly to the external electromagnetic field, even though they carry neither spin nor charge. This is possible via a magnetoelastic coupling mechanism recently identified. [Potter, Senthil, and Lee, arXiv:1301.3495; Hao, Phys. Rev. B 85, 174432 (2012)] For the case of transitions to a 36-site unit cell VBS state, the corresponding finite ac conductivity has a specific power-law frequency dependence, which is related to the crossover exponent of the quantum critical point. The visons’ contribution to the optical conductivity at transitions to VBS states with a 12-site unit cell vanishes, however.Publication Antiferromagnetism in Metals: From the Cuprate Superconductors to the Heavy Fermion Materials(IOP Publishing, 2012) Sachdev, Subir; Metlitski, Max A.; Punk, MatthiasThe critical theory of the onset of antiferromagnetism in metals, with concomitant Fermi surface reconstruction, has recently been shown to be strongly coupled in two spatial dimensions. The onset of unconventional superconductivity near this critical point is reviewed: it involves a subtle interplay between the breakdown of fermionic quasiparticle excitations on the Fermi surface and the strong pairing glue provided by the antiferromagnetic fluctuations. The net result is a logarithm-squared enhancement of the pairing vertex for generic Fermi surfaces, with a universal dimensionless coefficient independent of the strength of interactions, which is expected to lead to superconductivity at the scale of the Fermi energy. We also discuss the possibility that the antiferromagnetic critical point can be replaced by an intermediate 'fractionalized Fermi liquid' phase, in which there is Fermi surface reconstruction but no long-range antiferromagnetic order. We discuss the relevance of this phase to the underdoped cuprates and the heavy fermion materials.Publication Breakdown of Fermi Liquid Behavior at the (π,π)=2k\(_F\) Spin-Density Wave Quantum-Critical Point: the Case of Electron-Doped Cuprates(American Physical Society, 2012) Bergeron, Dominic; Chowdhury, Debanjan; Punk, Matthias; Sachdev, Subir; Tremblay, A.-M. S.Many correlated materials display a quantum-critical point between a paramagnetic and a spin-density wave (SDW) state. The SDW wave vector connects points, so-called hot spots, on opposite sides of the Fermi surface. The Fermi velocities at these pairs of points are in general not parallel. Here, we consider the case where pairs of hot spots coalesce, and the wave vector (π,π) of the SDW connects hot spots with parallel Fermi velocities. Using the specific example of electron-doped cuprates, we first show that Kanamori screening and generic features of the Lindhard function make this case experimentally relevant. The temperature dependence of the correlation length, the spin susceptibility, and the self-energy at the hot spots are found using the two-particle self-consistent theory and specific numerical examples worked out for band and interaction parameters characteristic of the electron-doped cuprates. While the curvature of the Fermi surface at the hot spots leads to deviations from perfect nesting, the pseudonesting conditions lead to drastic modifications of the temperature dependence of these physical observables: Neglecting logarithmic corrections, the correlation length ξ scales like 1/T, namely, z=1 instead of the naive z=2, the (π,π) static spin susceptibility χ like 1/\(\sqrt{T}\), and the imaginary part of the self-energy at the hot spots like T\(^{3/2}\). The correction T\(_1\)\(^{−1}\)∼T\(^{3/2}\) to the Korringa NMR relaxation rate is subdominant. We also consider this problem at zero temperature, or for frequencies larger than temperature, using a field-theoretical model of gapless collective bosonic modes (SDW fluctuations) interacting with fermions. The imaginary part of the retarded fermionic self-energy close to the hot spots scales as −ω\(^{3/2}\)lnω. This is less singular than earlier predictions of the form −ωlnω. The difference arises from the effects of umklapp terms that were not included in previous studies.Publication Fermi Surface Reconstruction in Hole-Doped t-J Models without Long-Range Antiferromagnetic Order(American Physical Society, 2012) Punk, Matthias; Sachdev, SubirWe calculate the Fermi surface of electrons in hole-doped, extended t-J models on a square lattice in a regime where no long-range antiferromagnetic order is present, and no symmetries are broken. Using the “spinon-dopon” formalism of Ribeiro and Wen, we show that short-range antiferromagnetic correlations lead to a reconstruction of the Fermi surface into hole pockets which are not necessarily centered at the antiferromagnetic Brillouin zone boundary. The Brillouin zone area enclosed by the Fermi surface is proportional to the density of dopants away from half-filling, in contrast to the conventional Luttinger theorem, which counts the total electron density. This state realizes a “fractionalized Fermi liquid” (FL*), which has been proposed as a possible ground state of the underdoped cuprates; we note connections to recent experiments. We also discuss the quantum phase transition from the FL* state to the Fermi liquid state with long-range antiferromagnetic order.Publication Vison States and Confinement Transitions of \(Z_2\) Spin Liquids on the Kagome Lattice(American Physical Society, 2011) Huh, Yejin; Punk, Matthias; Sachdev, SubirWe present a projective symmetry group (PSG) analysis of the spinless excitations of \(Z_2\) spin liquids on the kagome lattice. In the simplest case, vortices carrying \(Z_2\) magnetic flux (“visons”) are shown to transform under the 48 element group \(GL(2,Z_3)\). Alternative exchange couplings can also lead to a second case with visons transforming under 288-element group \(GL(2,Z_3)×D_3\). We study the quantum phase transition in which visons condense into confining states with valence bond solid order. The critical field theories and confining states are classified using the vison PSGs.Publication Relaxation of Antiferromagnetic Order in Spin-1/2 Chains Following a Quantum Quench(American Physical Society, 2009) Barmettler, Peter; Punk, Matthias; Gritsev, Vladimir; Demler, Eugene; Altman, EhudWe study the unitary time evolution of antiferromagnetic order in anisotropic Heisenberg chains that are initially prepared in a pure quantum state far from equilibrium. Our analysis indicates that the antiferromagnetic order imprinted in the initial state vanishes exponentially. Depending on the anisotropy parameter, oscillatory or non-oscillatory relaxation dynamics is observed. Furthermore, the corresponding relaxation time exhibits a at the critical point, in contrast to the usual notion of critical slowing down, from which a maximum is expected.Publication Quantum quenches in the anisotropic spin-\frac{1}{2} Heisenberg chain: different approaches to many-body dynamics far from equilibrium(IOP Publishing, 2010) Barmettler, Peter; Punk, Matthias; Gritsev, Vladimir; Demler, Eugene; Altman, EhudRecent experimental achievements in controlling ultracold gases in optical lattices open a new perspective on quantum many-body physics. In these experimental setups it is possible to study coherent time evolution of isolated quantum systems. These dynamics reveal new physics beyond the low-energy properties usually relevant in solid-state many-body systems. In this paper we study the time evolution of antiferromagnetic order in the Heisenberg chain after a sudden change of the anisotropy parameter, using various numerical and analytical methods. As a generic result we find that the order parameter, which can show oscillatory or non-oscillatory dynamics, decays exponentially except for the effectively non-interacting case of the XX limit. For weakly ordered initial states we also find evidence for an algebraic correction to the exponential law. The study is based on numerical simulations using a numerical matrix product method for infinite system sizes (iMPS), for which we provide a detailed description and an error analysis. Additionally, we investigate in detail the exactly solvable XX limit. These results are compared to approximative analytical approaches including an effective description by the XZ-model as well as by mean-field, Luttinger-liquid and sine-Gordon theories. This reveals which aspects of non-equilibrium dynamics can as in equilibrium be described by low-energy theories and which are the novel phenomena specific to quantum quench dynamics. The relevance of the energetically high part of the spectrum is illustrated by means of a full numerical diagonalization of the Hamiltonian.