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101. Holographic quantum matter

Author

Hartnoll, Sean A., Lucas, Andrew, and Sachdev, Subir

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

We present a review of theories of states of quantum matter without quasiparticle excitations. Solvable examples of such states are provided through a holographic duality with gravitational theories in an emergent spatial dimension. We review the duality between gravitational backgrounds and the various states of quantum matter which live on the boundary. We then describe quantum matter at a fixed commensurate density (often described by conformal field theories), and also compressible quantum matter with variable density, providing an extensive discussion of transport in both cases. We present a unified discussion of the holographic theory of transport with memory matrix and hydrodynamic methods, allowing a direct connection to experimentally realized quantum matter. We also explore other important challenges in non-quasiparticle physics, including symmetry broken phases such as superconductors and non-equilibrium dynamics., Comment: 178 pages, 43 figures; Draft of a review article for hep-th and cond-mat readers, comments welcome; (v2) added clarifications and references; expanded version, with exercises, published as a book by MIT Press: https://mitpress.mit.edu/books/holographic-quantum-matter

Published
2016

102. Stokes paradox in electronic Fermi liquids

Author

Lucas, Andrew

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Strongly Correlated Electrons, Physics - Fluid Dynamics
Abstract

The Stokes paradox is the statement that in a viscous two dimensional fluid, the "linear response" problem of fluid flow around an obstacle is ill-posed. We present a simple consequence of this paradox in the hydrodynamic regime of a Fermi liquid of electrons in two-dimensional metals. Using hydrodynamics and kinetic theory, we estimate the contribution of a single cylindrical obstacle to the global electrical resistance of a material, within linear response. Momentum relaxation, present in any realistic electron liquid, resolves the classical paradox. Nonetheless, this paradox imprints itself in the resistance, which can be parametrically larger than predicted by Ohmic transport theory. We find a remarkably rich set of behaviors, depending on whether or not the quasiparticle dynamics in the Fermi liquid should be treated as diffusive, hydrodynamic or ballistic on the length scale of the obstacle. We argue that all three types of behavior are observable in present day experiments., Comment: 23+3 pages, 7+1 figures. v2: published version with expanded introduction

Published
2016
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110. A Generalized Slab Model

Author

Stokes, Ian A., primary, Kelly, Samuel M., additional, Lucas, Andrew J., additional, Waterhouse, Amy F., additional, Whalen, Caitlin B., additional, Klenz, Thilo, additional, Hormann, Verena, additional, and Centurioni, Luca, additional

Published
2024
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111. Life in Internal Waves

Author

Garwood, Jessica C., Musgrave, Ruth C., and Lucas, Andrew J.

Published
2020

114. Discrete tissue microenvironments instruct diversity in resident memory T cell function and plasticity

Author

Christo, Susan N., Evrard, Maximilien, Park, Simone L., Gandolfo, Luke C., Burn, Thomas N., Fonseca, Raissa, Newman, Dane M., Alexandre, Yannick O., Collins, Nicholas, Zamudio, Natasha M., Souza-Fonseca-Guimaraes, Fernando, Pellicci, Daniel G., Chisanga, David, Shi, Wei, Bartholin, Laurent, Belz, Gabrielle T., Huntington, Nicholas D., Lucas, Andrew, Lucas, Michaela, Mueller, Scott N., Heath, William R., Ginhoux, Florent, Speed, Terence P., Carbone, Francis R., Kallies, Axel, and Mackay, Laura K.

Published
2021
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115. Hoverfly communities in semi-natural grasslands, and their role in pollination

Author

Lucas, Andrew M., Forman, Dan W., Neyland, Penny, and de Vere, Natasha

Subjects
595.77
Abstract

Pollination is an ecosystem service critical to both crop production and the functioning of many ecosystems. Hoverflies (Syrphidae) are a key group of non-hymenopteran pollinators. Using a combination of field and molecular techniques, this thesis explored hoverfly communities in grasslands, investigating how they are structured, and their possible role in pollination. In addition, it also created a library of hoverfly DNA barcodes that has applications for monitoring. Hoverfly abundance and species richness was not related to grassland plant community, but was influenced by flower abundance. Distinctive hoverfly communities were also associated with agriculturally unimproved grassland communities. Focussing on species-rich marshy grasslands, a four year study showed that hoverfly abundance and species richness was influenced by weather conditions. Hoverfly abundance was at a maximum at a daily mean temperature of 15°C and at moderate rainfall, declining with both high and low temperature and rainfall. Species-richness declined with increasing daily temperature. Sequences of the standard animal barcode COI were obtained from 82 hoverfly species caught in Britain. This was added to world-wide publicly available sequences for British species to create a library of over 70% of the British hoverfly fauna. These barcodes were effective at distinguishing hoverfly species, although discrimination was poor in a small number of genera. By DNA metabarcoding pollen derived from hoverflies, the structure of hoverfly pollen transport networks in marshy grasslands was investigated. In Eristalis species, networks were generalised at the whole network and species level, but showed some specialisation by individual hoverflies. Networks of 11 hoverfly species showed that although pollen carried by hoverflies came from a few common plant taxa, different hoverfly species carried distinctive pollen loads derived from at least 40% of the entomophilous plants present. Collectively, these results increase our understanding of hoverfly community function, and their role in grassland ecosystems.

Published
2017
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116. Charge diffusion and the butterfly effect in striped holographic matter

Author

Lucas, Andrew and Steinberg, Julia

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

Recently, it has been proposed that the butterfly velocity - a speed at which quantum information propagates - may provide a fundamental bound on diffusion constants in dirty incoherent metals. We analytically compute the charge diffusion constant and the butterfly velocity in charge-neutral holographic matter with long wavelength "hydrodynamic" disorder in a single spatial direction. In this limit, we find that the butterfly velocity does not set a sharp lower bound for the charge diffusion constant., Comment: 16+7 pages; 1 figure. v2: published version

Published
2016
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117. Dynamical response near quantum critical points

Author

Lucas, Andrew, Gazit, Snir, Podolsky, Daniel, and Witczak-Krempa, William

Subjects
Condensed Matter - Strongly Correlated Electrons, Condensed Matter - Quantum Gases, Condensed Matter - Statistical Mechanics, High Energy Physics - Theory
Abstract

We study high frequency response functions, notably the optical conductivity, in the vicinity of quantum critical points (QCPs) by allowing for both detuning from the critical coupling and finite temperature. We consider general dimensions and dynamical exponents. This leads to a unified understanding of sum rules. In systems with emergent Lorentz invariance, powerful methods from conformal field theory allow us to fix the high frequency response in terms of universal coefficients. We test our predictions analytically in the large-N O(N) model and using the gauge-gravity duality, and numerically via Quantum Monte Carlo simulations on a lattice model hosting the interacting superfluid-insulator QCP. In superfluid phases, interacting Goldstone bosons qualitatively change the high frequency optical conductivity, and the corresponding sum rule., Comment: 4+12 pages. 2+2 figures. v2: Added explanations throughout, and new results in Appendix C for the ordered phase. Published version

Published
2016
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118. Hydrodynamic theory of thermoelectric transport and negative magnetoresistance in Weyl semimetals

Author

Lucas, Andrew, Davison, Richard A., and Sachdev, Subir

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

We present a theory of thermoelectric transport in weakly disordered Weyl semimetals where the electron-electron scattering time is faster than the electron-impurity scattering time. Our hydrodynamic theory consists of relativistic fluids at each Weyl node, coupled together by perturbatively small inter-valley scattering, and long-range Coulomb interactions. The conductivity matrix of our theory is Onsager reciprocal and positive-semidefinite. In addition to the usual axial anomaly, we account for the effects of a distinct, axial-gravitational anomaly expected to be present in Weyl semimetals. Negative thermal magnetoresistance is a sharp, experimentally accessible signature of this axial-gravitational anomaly, even beyond the hydrodynamic limit., Comment: v3: 26 pages, published version

Published
2016
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119. Sound waves and resonances in electron-hole plasma

Author

Lucas, Andrew

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

Inspired by the recent experimental signatures of relativistic hydrodynamics in graphene, we investigate theoretically the behavior of hydrodynamic sound modes in such quasi-relativistic fluids near charge neutrality, within linear response. Locally driving an electron fluid at a resonant frequency to such a sound mode can lead to large increases in the electrical response at the edges of the sample, a signature which cannot be explained using diffusive models of transport. We discuss the robustness of this signal to various effects, including electron-acoustic phonon coupling, disorder, and long-range Coulomb interactions. These long range interactions convert the sound mode into a collective plasmonic mode at low frequencies unless the fluid is charge neutral. At the smallest frequencies, the response in a disordered fluid is quantitatively what is predicted by a "momentum relaxation time" approximation. However, this approximation fails at higher frequencies (which can be parametrically small), where the classical localization of sound waves cannot be neglected. Experimental observation of such resonances is a clear signature of relativistic hydrodynamics, and provides an upper bound on the viscosity of the electron-hole plasma., Comment: 24+18 pages. 11+2 figures. v2: some small additions, published version

Published
2016
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120. Conductivity bounds in probe brane models

Author

Ikeda, Tatsuhiko N., Lucas, Andrew, and Nakai, Yuichiro

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

We discuss upper and lower bounds on the electrical conductivity of finite temperature strongly coupled quantum field theories, holographically dual to probe brane models, within linear response. In a probe limit where disorder is introduced entirely through an inhomogeneous background charge density, we find simple lower and upper bounds on the electrical conductivity in arbitrary dimensions. In field theories in two spatial dimensions, we show that both bounds persist even when disorder is included in the bulk metric. We discuss the challenges with finding sharp lower bounds on conductivity in three or more spatial dimensions when the metric is inhomogeneous., Comment: 16 pages; v2: minor changes, published version

Published
2016
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122. Shock waves, rarefaction waves and non-equilibrium steady states in quantum critical systems

Author

Lucas, Andrew, Schalm, Koenraad, Doyon, Benjamin, and Bhaseen, M. J.

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

We re-examine the emergence of a universal non-equilibrium steady state following a local quench between quantum critical heat baths in spatial dimensions greater than one. We show that energy transport proceeds by the formation of an instantaneous shock wave and a broadening rarefaction wave on either side of the interface, and not by two shock waves as previously proposed. For small temperature differences the universal steady state energy currents of the two-shock and rarefaction-shock solutions coincide. Over a broad range of parameters, the difference in the energy flow across the interface between these two solutions is at the level of two percent. The properties of the energy flow remain fully universal and independent of the microscopic theory. We briefly discuss the width of the shock wave in a viscous fluid, the effects of momentum relaxation, and the generalization to charged fluids., Comment: 23 pages, 10 figures. v2: published version

Published
2015
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123. Northern Arabian Sea Circulation-Autonomous Research (NASCar): A Research Initiative Based on Autonomous Sensors

Author

Institution of Oceanography, Scripps, Centurioni, Luca, Hormann, Verena, Talley, Lynne, Arzeno, Isabella, Beal, Lisa, Caruso, Michael, Conry, Patrick, Echols, Rosalind, Fernando, Harindra, Giddings, Sarah, Gordon, Arnold, Graber, Hans, Harcourt, Ramsey, Jayne, Steven, Jensen, Tommy, Lee, Craig, Lermusiaux, Pierre, L’Hegaret, Pierre, Lucas, Andrew, Mahadevan, Amala, McClean, Julie, Pawlak, Geno, Rainville, Luc, Riser, Stephen, Seo, Hyodae, Shcherbina, Andrey, Skyllingstad, Eric, Sprintall, Janet, Subrahmanyam, Bulusu, Terrill, Eric, Todd, Robert, Trott, Corinne, Ulloa, Hugo, and Wang, He

Subjects
Oceanography
Abstract

The Arabian Sea circulation is forced by strong monsoonal winds and is characterized by vigorous seasonally reversing currents, extreme differences in sea surface salinity, localized substantial upwelling, and widespread submesoscale thermohaline structures. Its complicated sea surface temperature patterns are important for the onset and evolution of the Asian monsoon. This article describes a program that aims to elucidate the role of upper-ocean processes and atmospheric feedbacks in setting the sea surface temperature properties of the region. The wide range of spatial and temporal scales and the difficulty of accessing much of the region with ships due to piracy motivated a novel approach based on state-of-the-art autonomous ocean sensors and platforms. The extensive data set that is being collected, combined with numerical models and remote sensing data, confirms the role of planetary waves in the reversal of the Somali Current system. These data also document the fast response of the upper equatorial ocean to monsoon winds through changes in temperature and salinity and the connectivity of the surface currents across the northern Indian Ocean. New observations of thermohaline interleaving structures and mixing in setting the surface temperature properties of the northern Arabian Sea are also discussed.

Published
2017

125. Incoherent thermal transport from dirty black holes

Author

Grozdanov, Sašo, Lucas, Andrew, and Schalm, Koenraad

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

We study thermal transport in strongly disordered, strongly interacting quantum field theories without quasiparticles using gauge-gravity duality. We analyze linear perturbations of black holes with broken translational symmetry in Einstein-Maxwell-dilaton theories of gravity. Using general geometric arguments in the bulk, we derive bounds on thermal conductivity for the dual disordered field theories in one and two spatial dimensions. In the latter case, the thermal conductivity is always non-zero at finite temperature, so long as the dilaton potential is bounded from below. Hence, generic holographic models make non-trivial predictions about the thermal conductivity in a strongly disordered, strongly coupled metal in two spatial dimensions., Comment: 6 pages; v2: published version

Published
2015
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126. Transport in inhomogeneous quantum critical fluids and in the Dirac fluid in graphene

Author

Lucas, Andrew, Crossno, Jesse, Fong, Kin Chung, Kim, Philip, and Sachdev, Subir

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

We develop a general hydrodynamic framework for computing direct current thermal and electric transport in a strongly interacting finite temperature quantum system near a Lorentz-invariant quantum critical point. Our framework is non-perturbative in the strength of long wavelength fluctuations in the background charge density of the electronic fluid, and requires the rate of electron-electron scattering to be faster than the rate of electron-impurity scattering. We use this formalism to compute transport coefficients in the Dirac fluid in clean samples of graphene near the charge neutrality point, and find results insensitive to long range Coulomb interactions. Numerical results are compared to recent experimental data on thermal and electrical conductivity in the Dirac fluid in graphene and substantially improved quantitative agreement over existing hydrodynamic theories is found. We comment on the interplay between the Dirac fluid and acoustic and optical phonons, and qualitatively explain experimentally observed effects. Our work paves the way for quantitative contact between experimentally realized condensed matter systems and the wide body of high energy inspired theories on transport in interacting many-body quantum systems., Comment: 19 + 12 pages; 8 + 3 figures; v2: very minor changes, published version

Published
2015
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127. The NEOWISE-Discovered Comet Population and the CO+CO2 production rates

Author

Bauer, James M., Stevenson, Rachel, Kramer, Emily, Mainzer, A. K., Grav, Tommy, Masiero, Joseph R., Fernández, Yan R., Cutri, Roc M., Dailey, John W., Masci, Frank J., Meech, Karen J., Walker, Russel, Lisse, C. M., Weissman, Paul R., Nugent, Carrie R., Sonnett, Sarah, Blair, Nathan, Lucas, Andrew, McMillan, Robert S., Wright, Edward L., WISE, the, and Teams, NEOWISE

Subjects
Astrophysics - Earth and Planetary Astrophysics
Abstract

The 163 comets observed during the WISE/NEOWISE prime mission represent the largest infrared survey to date of comets, providing constraints on dust, nucleus sizes, and CO+CO2 production. We present detailed analyses of the WISE/NEOWISE comet discoveries, and discuss observations of the active comets showing 4.6 $\mu$m band excess. We find a possible relation between dust and CO+CO2 production, as well as possible differences in the sizes of long and short period comet nuclei., Comment: 67 pages, 10 figures, 6 Tables; Accepted by The Astrophysical Journal

Published
2015

128. Observation of the Dirac fluid and the breakdown of the Wiedemann-Franz law in graphene

Author

Crossno, Jesse, Shi, Jing K., Wang, Ke, Liu, Xiaomeng, Harzheim, Achim, Lucas, Andrew, Sachdev, Subir, Kim, Philip, Taniguchi, Takashi, Watanabe, Kenji, Ohki, Thomas A., and Fong, Kin Chung

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

Interactions between particles in quantum many-body systems can lead to collective behavior described by hydrodynamics. One such system is the electron-hole plasma in graphene near the charge neutrality point which can form a strongly coupled Dirac fluid. This charge neutral plasma of quasi-relativistic fermions is expected to exhibit a substantial enhancement of the thermal conductivity, due to decoupling of charge and heat currents within hydrodynamics. Employing high sensitivity Johnson noise thermometry, we report the breakdown of the Wiedemann-Franz law in graphene, with a thermal conductivity an order of magnitude larger than the value predicted by Fermi liquid theory. This result is a signature of the Dirac fluid, and constitutes direct evidence of collective motion in a quantum electronic fluid., Comment: 5+5 pages, 3+7 figures

Published
2015
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129. Absence of disorder-driven metal-insulator transitions in simple holographic models

Author

Grozdanov, Sašo, Lucas, Andrew, Sachdev, Subir, and Schalm, Koenraad

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

We study electrical transport in a strongly coupled strange metal in two spatial dimensions at finite temperature and charge density, holographically dual to Einstein-Maxwell theory in an asymptotically $\mathrm{AdS}_4$ spacetime, with arbitrary spatial inhomogeneity, up to mild assumptions including emergent isotropy. In condensed matter, these are candidate models for exotic strange metals without long-lived quasiparticles. We prove that the electrical conductivity is bounded from below by a universal minimal conductance: the quantum critical conductivity of a clean, charge-neutral plasma. Beyond non-perturbatively justifying mean-field approximations to disorder, our work demonstrates the practicality of new hydrodynamic insight into holographic transport., Comment: 6 pages. v2: more references, minor changes. v3: published version

Published
2015
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130. Hydrodynamic transport in strongly coupled disordered quantum field theories

Author

Lucas, Andrew

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

We compute direct current (dc) thermoelectric transport coefficients in strongly coupled quantum field theories without long lived quasiparticles, at finite temperature and charge density, and disordered on long wavelengths compared to the length scale of local thermalization. Many previous transport computations in strongly coupled systems are interpretable hydrodynamically, despite formally going beyond the hydrodynamic regime. This includes momentum relaxation times previously derived by the memory matrix formalism, and non-perturbative holographic results; in the latter case, this is subject to some important subtleties. Our formalism may extend some memory matrix computations to higher orders in the perturbative disorder strength, as well as give valuable insight into non-perturbative regimes. Strongly coupled metals with quantum critical contributions to transport generically transition between coherent and incoherent metals as disorder strength is increased at fixed temperature, analogous to mean field holographic treatments of disorder. From a condensed matter perspective, our theory generalizes the resistor network approximation, and associated variational techniques, to strongly interacting systems where momentum is long lived., Comment: 27 pages, 3 figures (main text), + 14 pages (appendices, references). v2: new references, minor errors fixed. v3: published version

Published
2015
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131. Memory matrix theory of magnetotransport in strange metals

Author

Lucas, Andrew and Sachdev, Subir

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

We model strange metals as quantum liquids without quasiparticle excitations, but with slow momentum relaxation, and with slow diffusive dynamics of a conserved charge and energy. General expressions are obtained for electrical, thermal and thermoelectric transport in the presence of an applied magnetic field using the memory matrix formalism. In the appropriate limits, our expressions agree with previous hydrodynamic and holographic results. We discuss the relationship of such results to thermoelectric and Hall transport measurements in the strange metal phase of the hole-doped cuprates., Comment: 20 pages, 1 figure. v2: extended discussions

Published
2015
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132. Conductivity of a strange metal: from holography to memory functions

Author

Lucas, Andrew

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

We study the electrical response of a wide class of strange metal phases without quasiparticles at finite temperature and charge density, with explicitly broken translational symmetry, using holography. The low frequency electrical conductivity exhibits a Drude peak, so long as momentum relaxation is slow. The relaxation time and the direct current conductivity are exactly equal to what is computed, independently of holography, via the memory function framework., Comment: 14 pages. v2: very minor changes. v3: references updated. published version

Published
2015
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136. Conductivity of weakly disordered strange metals: from conformal to hyperscaling-violating regimes

Author

Lucas, Andrew and Sachdev, Subir

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

We present a semi-analytic method for constructing holographic black holes that interpolate from anti-de Sitter space to hyperscaling-violating geometries. These are holographic duals of conformal field theories in the presence of an applied chemical potential, $\mu$, at a non-zero temperature, $T$, and allow us to describe the crossover from `strange metal' physics at $T \ll \mu$, to conformal physics at $T \gg \mu$. Our holographic technique adds an extra gauge field and exploits structure of the Einstein-Maxwell system to manifestly find 1-parameter families of solutions of the Einstein-matter system in terms of a small family of functions, obeying a nested set of differential equations. Using these interpolating geometries, we re-consider holographically some recent questions of interest about hyperscaling-violating field theories. Our focus is a more detailed holographic computation of the conductivity of strange metals, weakly perturbed by disorder coupled to scalar operators, including both the average conductivity as well as sample-to-sample fluctuations. Our findings are consistent with previous scaling arguments, though we point out logarithmic corrections in some special (holographic) cases. We also discuss the nature of superconducting instabilities in hyperscaling-violating geometries with appropriate choices of scalar couplings., Comment: 31 pages, 6 figures. v2: published version

Published
2014
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137. Vortex annihilation and inverse cascades in two dimensional superfluid turbulence

Author

Chesler, Paul M. and Lucas, Andrew

Subjects
Condensed Matter - Quantum Gases, High Energy Physics - Theory, Nonlinear Sciences - Chaotic Dynamics, Physics - Fluid Dynamics
Abstract

We study two dimensional superfluid turbulence by employing an effective description valid in the limit where the density of superfluid vortices is parametrically small. At sufficiently low temperatures the effective description yields an inverse cascade with Kolmogorov energy spectrum $E(k) \sim k^{-5/3}$. Denoting the number of vortices as a function of time by $N(t)$, we find that the vortex annihilation rate scales like $\dot N \sim N^{5/3}$ in states with an inverse cascade and $\dot N \sim N^2$ for laminar flow., Comment: 5 pages, 3 figures

Published
2014

139. Non-equilibrium steady states in the Klein-Gordon theory

Author

Doyon, Benjamin, Lucas, Andrew, Schalm, Koenraad, and Bhaseen, M. J.

Subjects
Condensed Matter - Statistical Mechanics, High Energy Physics - Theory, Mathematical Physics
Abstract

We construct non-equilibrium steady states in the Klein-Gordon theory in arbitrary space dimension $d$ following a local quench. We consider the approach where two independently thermalized semi-infinite systems, with temperatures $T_{\rm L}$ and $T_{\rm R}$, are connected along a $d-1$-dimensional hypersurface. A current-carrying steady state, described by thermally distributed modes with temperatures $T_{\rm L}$ and $T_{\rm R}$ for left and right-moving modes, respectively, emerges at late times. The non-equilibrium density matrix is the exponential of a non-local conserved charge. We obtain exact results for the average energy current and the complete distribution of energy current fluctuations. The latter shows that the long-time energy transfer can be described by a continuum of independent Poisson processes, for which we provide the exact weights. We further describe the full time evolution of local observables following the quench. Averages of generic local observables, including the stress-energy tensor, approach the steady state with a power-law in time, where the exponent depends on the initial conditions at the connection hypersurface. We describe boundary conditions and special operators for which the steady state is reached instantaneously on the connection hypersurface. A semiclassical analysis of freely propagating modes yields the average energy current at large distances and late times. We conclude by comparing and contrasting our findings with results for interacting theories and provide an estimate for the timescale governing the crossover to hydrodynamics. As a modification of our Klein-Gordon analysis we also include exact results for free Dirac fermions., Comment: 42 pages, 7 figures

Published
2014
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140. Sound-induced vortex interactions in a zero-temperature two-dimensional superfluid

Author

Lucas, Andrew and Surówka, Piotr

Subjects
Condensed Matter - Quantum Gases, High Energy Physics - Theory
Abstract

We present a systematic derivation of the effective action for interacting vortices in a non-relativistic two-dimensional superfluid described by the Gross-Pitaevskii equation by integrating out longitudinal fluctuations of the order parameter. There are no logarithmically divergent coefficients in the equations of motion. Our analysis is valid in a dilute limit of vortices where the intervortex spacing is large compared to the core size, and where number fluctuations of atoms in vortex cores are suppressed. We analyze sound-induced corrections to the dynamics of a vortex-antivortex pair and show that there is no instability to annihilation, suggesting that sound-mediated interactions are not strong enough to ruin an inverse energy cascade in two-dimensional zero-temperature superfluid turbulence., Comment: 20 pages

Published
2014
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141. A simple model for multiple-choice collective decision making

Author

Lee, Ching Hua and Lucas, Andrew

Subjects
Physics - Physics and Society, Condensed Matter - Statistical Mechanics
Abstract

We describe a simple model of heterogeneous, interacting agents making decisions between $n\ge 2$ discrete choices. For a special class of interactions, our model is the mean field description of random-field Potts-like models, and is effectively solved by finding the extrema of the average energy $E$ per agent. In these cases, by studying the propagation of decision changes via avalanches, we argue that macroscopic dynamics is well-captured by a gradient flow along $E$. We focus on the permutation-symmetric case, where all $n$ choices are (on average) the same, and spontaneous symmetry breaking (SSB) arises purely from cooperative social interactions. As examples, we show that bimodal heterogeneity naturally provides a mechanism for the spontaneous formation of hierarchies between decisions, and that SSB is a preferred instability to discontinuous phase transitions between two symmetric points. Beyond the mean field limit, exponentially many stable equilibria emerge when we place this model on a graph of finite mean degree. We conclude with speculation on decision making with persistent collective oscillations. Throughout the paper, we emphasize analogies between methods of solution to our model and common intuition from diverse areas of physics, including statistical physics and electromagnetism., Comment: 1+18 pages (main text) + 12 pages (appendices/references). 8 + 3 figures. v2: more references, a couple more comments/explanations and a short new section on finite size effects added

Published
2014
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142. Phenomenology of non-relativistic parity-violating hydrodynamics in 2+1 dimensions

Author

Lucas, Andrew and Surówka, Piotr

Subjects
Condensed Matter - Mesoscale and Nanoscale Physics, High Energy Physics - Theory, Physics - Fluid Dynamics
Abstract

Parity-violating fluids in two spatial dimensions can appear in a variety of contexts such as liquid crystal films, anyon fluids, and quantum Hall fluids. Nonetheless, the consequences of parity-violation on the solutions to the equations of motion are largely unexplored. In this paper, we explore phenomenological consequences of parity-violation through simple, illustrative examples. Although incompressible velocity fields are essentially unchanged by parity violation, we discuss examples where parity violation plays a role at boundaries, or in the dynamics of temperature. We then discuss new types of compressible flows which only exist in a parity-violating fluid, including new sound waves, and solitons in the dissipationless limit. We conclude with a discussion of some curious features in Rayleigh-B\'enard convection of a parity-violating fluid., Comment: v2: expanded and published version. 33 pages, 9 figures

Published
2014
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143. Connecting microscopic physics with the macroscopic properties of materials in introductory physics courses

Author

Lucas, Andrew

Subjects
Physics - Physics Education, Condensed Matter - Materials Science
Abstract

An elementary understanding of the relevant length, mass and energy scales at the molecular level can be used to explain the order of magnitude of material properties such as mass density, latent heat, surface tension, elastic moduli and beyond in an introductory physics course. These order of magnitude estimates are remarkably easy to derive, and in many instances are the same for many different liquids and solids. This helps students to understand the origin of the zoo of material properties, and to connect molecular physics to the physics of familiar materials like water, metals and plastics. We also note some simple mechanisms by which material properties can easily vary over many orders of magnitude., Comment: 13 pages, 2 figures. v2: fixed incorrect explanation. v3: added reference, fixed typos

Published
2014

144. Scale-invariant hyperscaling-violating holographic theories and the resistivity of strange metals with random-field disorder

Author

Lucas, Andrew, Sachdev, Subir, and Schalm, Koenraad

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

We compute the direct current resistivity of a scale-invariant, $d$-dimensional strange metal with dynamic critical exponent $z$ and hyperscaling-violating exponent $\theta$, weakly perturbed by a scalar operator coupled to random-field disorder that locally breaks a $\mathbb{Z}_2$ symmetry. Independent calculations via Einstein-Maxwell-Dilaton holography and memory matrix methods lead to the same results. We show that random field disorder has a strong effect on resistivity: charge carriers in the infrared are easily depleted, as the relaxation time for momentum is surprisingly small. In the course of our holographic calculation we use a non-trivial dilaton coupling to the disordered scalar, allowing us to study a strongly-coupled scale invariant theory with $\theta \ne 0$. Using holography, we are also able to determine the disorder strength at which perturbation theory breaks down. Curiously, for locally critical theories this breakdown occurs when the resistivity is proportional to the entropy density, up to a possible logarithmic correction., Comment: 20 pages. v2: minor changes, more references. v3: published version

Published
2014
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148. Far from equilibrium energy flow in quantum critical systems

Author

Bhaseen, M. J., Doyon, Benjamin, Lucas, Andrew, and Schalm, Koenraad

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

We investigate far from equilibrium energy transport in strongly coupled quantum critical systems. Combining results from gauge-gravity duality, relativistic hydrodynamics, and quantum field theory, we argue that long-time energy transport occurs via a universal steady-state for any spatial dimensionality. This is described by a boosted thermal state. We determine the transport properties of this emergent steady state, including the average energy flow and its long-time fluctuations., Comment: 5 pages, 3 figures

Published
2013
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149. Conformal field theories in a periodic potential: results from holography and field theory

Author

Chesler, Paul, Lucas, Andrew, and Sachdev, Subir

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

We study 2+1 dimensional conformal field theories (CFTs) with a globally conserved U(1) charge, placed in a chemical potential which is periodically modulated along the spatial direction $x$ with zero average: $\mu(x) = V \cos(kx)$. The dynamics of such theories depends only on the dimensionless ratio $V/k$, and we expect that they flow in the infrared to new CFTs whose universality class changes as a function of $V/k$. We compute the frequency-dependent conductivity of strongly-coupled CFTs using holography of the Einstein-Maxwell theory in 4-dimensional anti-de Sitter space. We compare the results with the corresponding computation of weakly-coupled CFTs, perturbed away from the CFT of free, massless Dirac fermions (which describes graphene at low energies). We find that the results of the two computations have significant qualitative similarities. However, differences do appear in the vicinities of an infinite discrete set of values of $V/k$: the universality class of the infrared CFT changes at these values in the weakly-coupled theory, by the emergence of new zero modes of Dirac fermions which are remnants of local Fermi surfaces. The infrared theory changes continuously in holography, and the classical gravitational theory does not capture the physics of the discrete transition points between the infrared CFTs. We briefly note implications for a non-zero average chemical potential., Comment: 42 pages, 22 figures; v2: more references; v3: published version

Published
2013
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150. Binary decision making with very heterogeneous influence

Author

Lucas, Andrew

Subjects
Physics - Physics and Society, Condensed Matter - Statistical Mechanics, Computer Science - Social and Information Networks
Abstract

We consider an extension of a binary decision model in which nodes make decisions based on influence-biased averages of their neighbors' states, similar to Ising spin glasses with on-site random fields. In the limit where these influences become very heavy-tailed, the behavior of the model dramatically changes. On complete graphs, or graphs where nodes with large influence have large degree, this model is characterized by a new "phase" with an unpredictable number of macroscopic shocks, with no associated critical phenomena. On random graphs where the degree of the most influential nodes is small compared to population size, a predictable glassy phase without phase transitions emerges. Analytic results about both of these new phases are obtainable in limiting cases. We use numerical simulations to explore the model for more general scenarios. The phases associated with very influential decision makers are easily distinguishable experimentally from a homogeneous influence phase in many circumstances, in the context of our simple model., Comment: 19 pages, 7 figures; v2: published version

Published
2013
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