Your search keyword '"McGreevy, John"' showing total 573 results

1. Catholicism: A Global History from the French Revolution to Pope Francis by John T. McGreevy (review)

Author

Schloesser, Stephen, Faggioli, Massimo, Schwaller, John Frederick, Carney, James Jay, Hoang, Tuan, and McGreevy, John T.

Published

2024

2. Parish Boundaries at 25: A Personal History

Author

McGreevy, John T.

Published

2021

3. Strict area law entanglement versus chirality

Author

Li, Xiang, Lin, Ting-Chun, McGreevy, John, and Shi, Bowen

Subjects

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

Abstract

Chirality is a property of a gapped phase of matter in two spatial dimensions that can be manifested through non-zero thermal or electrical Hall conductance. In this paper, we prove two no-go theorems that forbid such chirality for a quantum state in a finite dimensional local Hilbert space with strict area law entanglement entropies. As a crucial ingredient in the proofs, we introduce a new quantum information-theoretic primitive called instantaneous modular flow, which has many other potential applications., Comment: 5+9 pages, 4 figures

Published

2024

4. Conformal geometry from entanglement

Author

Kim, Isaac H., Li, Xiang, Lin, Ting-Chun, McGreevy, John, and Shi, Bowen

Subjects

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

Abstract

In a physical system with conformal symmetry, observables depend on cross-ratios, measures of distance invariant under global conformal transformations (conformal geometry for short). We identify a quantum information-theoretic mechanism by which the conformal geometry emerges at the gapless edge of a 2+1D quantum many-body system with a bulk energy gap. We introduce a novel pair of information-theoretic quantities $(\mathfrak{c}_{\mathrm{tot}}, \eta)$ that can be defined locally on the edge from the wavefunction of the many-body system, without prior knowledge of any distance measure. We posit that, for a topological groundstate, the quantity $\mathfrak{c}_{\mathrm{tot}}$ is stationary under arbitrary variations of the quantum state, and study the logical consequences. We show that stationarity, modulo an entanglement-based assumption about the bulk, implies (i) $\mathfrak{c}_{\mathrm{tot}}$ is a non-negative constant that can be interpreted as the total central charge of the edge theory. (ii) $\eta$ is a cross-ratio, obeying the full set of mathematical consistency rules, which further indicates the existence of a distance measure of the edge with global conformal invariance. Thus, the conformal geometry emerges from a simple assumption on groundstate entanglement. We show that stationarity of $\mathfrak{c}_{\mathrm{tot}}$ is equivalent to a vector fixed-point equation involving $\eta$, making our assumption locally checkable. We also derive similar results for 1+1D systems under a suitable set of assumptions., Comment: 48+31 pages, 25 figures

Published

2024

5. Nishimori's self-tuning as evidence for the existence of God

Author

McGreevy, John and Grover, Tarun

Subjects

High Energy Physics - Theory, Quantum Physics

Abstract

Apparent violations of Naturalness may be explained by positing the existence of an omniscient but disinterested and possibly fallible Observer who regularly performs von Neumann measurements on us (and everything else). We comment briefly on the implications for the construction of scalable quantum computers., Comment: 4 (pages)/ 1 (figure)

Published

2024

6. Chiral Virasoro algebra from a single wavefunction

Author

Kim, Isaac H., Li, Xiang, Lin, Ting-Chun, McGreevy, John, and Shi, Bowen

Subjects

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

Abstract

Chiral edges of 2+1D systems can have very robust emergent conformal symmetry. When the edge is purely chiral, the Hilbert space of low-energy edge excitations can form a representation of a single Virasoro algebra. We propose a method to systematically extract the generators of the Virasoro algebra from a single ground state wavefunction, using entanglement bootstrap and an input from the edge conformal field theory. We corroborate our construction by numerically verifying the commutation relations of the generators. We also study the unitary flows generated by these operators, whose properties (such as energy and state overlap) are shown numerically to agree with our analytical predictions., Comment: 60+20 pages, 28 figures

Published

2024

7. Dimer piling problems and interacting field theory

Author

Camasca, Rolando Ramirez and McGreevy, John

Subjects

High Energy Physics - Theory, Condensed Matter - Statistical Mechanics, Mathematics - Combinatorics

Abstract

The dimer tiling problem asks in how many ways can the edges of a graph be covered by dimers so that each site is covered once. In the special case of a planar graph, this problem has a solution in terms of a free fermionic field theory. We rediscover and explore an expression for the number of coverings of an arbitrary graph by arbitrary objects in terms of an interacting fermionic field theory first proposed by Samuel. Generalizations of the dimer tiling problem, which we call `dimer piling problems,' demand that each site be covered N times by indistinguishable dimers. Our field theory provides a solution of these problems in the large-N limit. We give a similar path integral representation for certain lattice coloring problems., Comment: v1: 36 pages plus appendices, 29 figures. v2: improved understanding of large-N artifacts in model B, corrected error and added new results on 3-coloring problems

Published

2023

8. Conformal Field Theory Ground States as Critical Points of an Entropy Function

Author

Lin, Ting-Chun and McGreevy, John

Subjects

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

Abstract

We derive an entropy formula satisfied by the ground states of 1+1D conformal field theories. The formula implies that the ground state is the critical point of an entropy function. We conjecture that this formula may serve as an information-theoretic criterion for conformal field theories, which differs from the conventional algebraic definition. In addition to these findings, we use the same proof method to extract the six global conformal generators of the conformal field theory from its ground state. We validate our results by testing them on different critical lattice models with excellent agreement.

Published

2023

9. Catholics, Democrats, and the GOP in Contemporary America

Author

McGreevy, John T

Published

2007

10. Remote detectability from entanglement bootstrap I: Kirby's torus trick

Author

Shi, Bowen, Huang, Jin-Long, and McGreevy, John

Subjects

Quantum Physics, Condensed Matter - Strongly Correlated Electrons, High Energy Physics - Theory, Mathematical Physics, Mathematics - Quantum Algebra

Abstract

Remote detectability is often taken as a physical assumption in the study of topologically ordered systems, and it is a central axiom of mathematical frameworks of topological quantum field theories. We show under the entanglement bootstrap approach that remote detectability is a necessary property; that is, we derive it as a theorem. Starting from a single wave function on a topologically-trivial region satisfying the entanglement bootstrap axioms, we can construct states on closed manifolds. The crucial technique is to immerse the punctured manifold into the topologically trivial region and then heal the puncture. This is analogous to Kirby's torus trick. We then analyze a special class of such manifolds, which we call pairing manifolds. For each pairing manifold, which pairs two classes of excitations, we identify an analog of the topological $S$-matrix. This pairing matrix is unitary, which implies remote detectability between two classes of excitations. These matrices are in general not associated with the mapping class group of the manifold. As a by-product, we can count excitation types (e.g., graph excitations in 3+1d). The pairing phenomenon occurs in many physical contexts, including systems in different dimensions, with or without gapped boundaries. We provide a variety of examples to illustrate its scope., Comment: 110+20 pages. Many figures

Published

2023

11. Response to Ribuffo, McCarraher, and Shannon

Author

McGreevy, John T.

Published

2012

12. Religious Roots

Author

McGreevy, John T

Published

2000

13. Bronx Miracle

Author

McGreevy, John T.

Published

2000

14. Faith and Morals in the Modern United States, 1865-Present

Author

McGreevy, John T

Published

1998

15. Knots and entanglement

Author

Huang, Jin-Long, McGreevy, John, and Shi, Bowen

Abstract

We extend the entanglement bootstrap program to (3+1)-dimensions. We study knotted excitations of (3+1)-dimensional liquid topological orders and exotic fusion processes of loops. As in previous work in (2+1)-dimensions [Ann. Phys. 418, 168164(2020), Phys. Rev. B 103, 115150 (2021)], we define a variety of superselection sectors and fusion spaces from two axioms on the ground state entanglement entropy. In particular, we identify fusion spaces associated with knots. We generalize the information convex set to a new class of regions called immersed regions, promoting various theorems to this new context. Examples from solvable models are provided; for instance, a concrete calculation of knot multiplicity shows that the knot complement of a trefoil knot can store quantum information. We define spiral maps that allow us to understand consistency relations for torus knots as well as spiral fusions of fluxes.

Published

2023

16. Generalized Symmetries in Condensed Matter

Author

McGreevy, John

Subjects

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

Abstract

Recent advances in our understanding of symmetry in quantum many-body systems offer the possibility of a generalized Landau paradigm that encompasses all equilibrium phases of matter. This is a brief and elementary review of some of these developments., Comment: 27 pages + refs; v2: added refs, minor improvements

Published

2022

17. Knots and entanglement

Author

Huang, Jin-Long, McGreevy, John, and Shi, Bowen

Subjects

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

Abstract

We extend the entanglement bootstrap approach to (3+1)-dimensions. We study knotted excitations of (3+1)-dimensional liquid topological orders and exotic fusion processes of loops. As in previous work in (2+1)-dimensions, we define a variety of superselection sectors and fusion spaces from two axioms on the ground state entanglement entropy. In particular, we identify fusion spaces associated with knots. We generalize the information convex set to a new class of regions called immersed regions, promoting various theorems to this new context. Examples from solvable models are provided; for instance, a concrete calculation of knot multiplicity shows that the knot complement of a trefoil knot can store quantum information. We define spiral maps that allow us to understand consistency relations for torus knots as well as spiral fusions of fluxes., Comment: 84+43 pages, 46 figures, published version

Published

2021

18. Catholicism and American Freedom

Author

McGreevy, John T.

Published

2012

19. Local Adaptations

Author

McGreevy, John T.

Subjects

Judgment at Tokyo: World War II on Trial and the Making of Modern Asia (Nonfiction work) -- Bass, Gary J., Books -- Book reviews, Humanities, Literature/writing, Political science

Abstract

Gary Bass's Judgment at Tokyo assesses the trials of Japanese leaders conducted by the Allied powers after World War II--a lesser known and, in Bass's view, less successful counterpart to [...]

Published

2024

20. Mean string field theory: Landau-Ginzburg theory for 1-form symmetries

Author

Iqbal, Nabil and McGreevy, John

Subjects

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

Abstract

By analogy with the Landau-Ginzburg theory of ordinary zero-form symmetries, we introduce and develop a Landau-Ginzburg theory of one-form global symmetries, which we call mean string field theory. The basic dynamical variable is a string field -- defined on the space of closed loops -- that can be used to describe the creation, annihilation, and condensation of effective strings. Like its zero-form cousin, the mean string field theory provides a useful picture of the phase diagram of broken and unbroken phases. We provide a transparent derivation of the area law for charged line operators in the unbroken phase and describe the dynamics of gapless Goldstone modes in the broken phase. The framework also provides a theory of topological defects of the broken phase and a description of the phase transition that should be valid above an upper critical dimension, which we discuss. We also discuss general consequences of emergent one-form symmetries at zero and finite temperature., Comment: 47 pages + appendices, 5 figures; v2: references added, some small clarifications, Appendix B improved

Published

2021

21. Fractonic order in infinite-component Chern-Simons gauge theories

Author

Ma, Xiuqi, Shirley, Wilbur, Cheng, Meng, Levin, Michael, McGreevy, John, and Chen, Xie

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

2+1D multi-component $U(1)$ gauge theories with a Chern-Simons (CS) term provide a simple and complete characterization of 2+1D Abelian topological orders. In this paper, we extend the theory by taking the number of component gauge fields to infinity and find that they can describe interesting types of 3+1D "fractonic" order. "Fractonic" describes the peculiar phenomena that point excitations in certain strongly interacting systems either cannot move at all or are only allowed to move in a lower dimensional sub-manifold. In the simplest cases of infinite-component CS gauge theory, different components do not couple to each other and the theory describes a decoupled stack of 2+1D fractional Quantum Hall systems with quasi-particles moving only in 2D planes -- hence a fractonic system. We find that when the component gauge fields do couple through the CS term, more varieties of fractonic orders are possible. For example, they may describe foliated fractonic systems for which increasing the system size requires insertion of nontrivial 2+1D topological states. Moreover, we find examples which lie beyond the foliation framework, characterized by 2D excitations of infinite order and braiding statistics that are not strictly local.

Published

2020

22. Topological terms on topological defects: a quantum Monte Carlo study

Author

Sato, Toshihiro, Hohenadler, Martin, Grover, Tarun, McGreevy, John, and Assaad, Fakher F.

Subjects

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

Abstract

Dirac fermions in $2+1$ dimensions with dynamically generated anticommuting SO(3) antiferromagnetic (AFM) and Z$_2$ Kekul\'e valence-bond solid (KVBS) masses map onto a field theory with a topological $\theta$-term. This term provides a mechanism for continuous phase transitions between different symmetry-broken states: topological defects of one phase carry the charge of the other and proliferate at the transition. The $\theta$-term implies that a domain wall of the Z$_2$ KVBS order parameter harbors a spin-$1/2$ Heisenberg chain, as described by a $1+1$ dimensional SO(3) non-linear sigma model with $\theta$-term at $\theta = \pi$. Using pinning fields to stabilize the domain wall, we show that our auxiliary-field quantum Monte Carlo simulations indeed support the emergence of a spin-$1/2$ chain at the Z$_2$ topological defect. This concept can be generalized to higher dimensions where $2+1$ dimensional SO(4) or SO(5) theories with topological terms are realized at a domain wall., Comment: 5 pages, 3 figures, supplemental material

Published

2020

23. Toward a 3d Ising model with a weakly-coupled string theory dual

Author

Iqbal, Nabil and McGreevy, John

Subjects

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

Abstract

It has long been expected that the 3d Ising model can be thought of as a string theory, where one interprets the domain walls that separate up spins from down spins as two-dimensional string worldsheets. The usual Ising Hamiltonian measures the area of these domain walls. This theory has string coupling of unit magnitude. We add new local terms to the Ising Hamiltonian that further weight each spin configuration by a factor depending on the genus of the corresponding domain wall, resulting in a new 3d Ising model that has a tunable bare string coupling $g_s$. We use a combination of analytical and numerical methods to analyze the phase structure of this model as $g_s$ is varied. We study statistical properties of the topology of worldsheets and discuss the prospects of using this new deformation at weak string coupling to find a worldsheet description of the 3d Ising transition., Comment: 34 pages + appendices. Many plots and pictures of cubes. Appendix E can be cut out and assembled. Code available at https://github.com/nabiliqbal/3d-ising-string-theory. v2: references added, minor changes

Published

2020

24. Adiabatic ground state preparation in an expanding lattice

Author

Olund, Christopher T., Block, Maxwell, Gazit, Snir, McGreevy, John, and Yao, Norman Y.

Subjects

Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

We implement and characterize a numerical algorithm inspired by the $s$-source framework [Phys. Rev.~B 93, 045127 (2016)] for building a quantum many-body ground state wavefunction on a lattice of size $2L$ by applying adiabatic evolution to the corresponding ground state at size $L$, along with $L$ interleaved ancillae. The procedure can in principle be iterated to repeatedly double the size of the system. We implement the algorithm for several one dimensional spin model Hamiltonians, and find that the construction works particularly well when the gap is large and, interestingly, at scale invariant critical points. We explain this feature as a natural consequence of the lattice expansion procedure. This behavior holds for both the integrable transverse-field Ising model and non-integrable variations. We also develop an analytic perturbative understanding of the errors deep in either phase of the transverse field Ising model, and suggest how the circuit could be modified to parametrically reduce errors. In addition to sharpening our perspective on entanglement renormalization in 1D, the algorithm could also potentially be used to build states experimentally, enabling the realization of certain long-range correlated states with low depth quantum circuits., Comment: 14 pages, 6 figures

Published

2020

25. Disentangling quantum matter with measurements

Author

Ben-Zion, Daniel, McGreevy, John, and Grover, Tarun

Subjects

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

Abstract

Measurements destroy entanglement. Building on ideas used to study `quantum disentangled liquids', we explore the use of this effect to characterize states of matter. We focus on systems with multiple components, such as charge and spin in a Hubbard model, or local moments and conduction electrons in a Kondo lattice model. In such systems, measurements of (a subset of) one of the components can leave behind a quantum state of the other that is easy to understand, for example in terms of scaling of entanglement entropy of subregions. We bound the outcome of this protocol, for any choice of measurement, in terms of more standard information-theoretic quantities. We apply this quantum disentangling protocol to several problems of physical interest, including gapless topological phases, heavy fermions, and scar states in Hubbard model., Comment: 36 pages, 12 figures. v2: many improvements in presentation

Published

2019

26. Jewish Studies at a Catholic University

Author

McGreevy, John T., primary

Published

2023

27. Effects of Dissipation on Solitons in the Hydrodynamic Regime of Graphene

Author

Zdyrski, Thomas and McGreevy, John

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We use hydrodynamic techniques to analyze the one-dimensional propagation of solitons in gated graphene on an arbitrary uniform background current. Results are derived for both the Fermi liquid and Dirac fluid regimes. We find that these solutions satisfy the Korteweg-de Vries-Burgers equation. Viscous dissipation and ohmic heating are included, causing the solitons to decay. Experiments are proposed to measure this decay and thereby quantify the shear viscosity in graphene., Comment: Improved discussion of phonons (section IIB) and minor corrections; 19+15 pages, 5 figures

Published

2019

28. Second impact syndrome: The influence of climate change and increased disaster frequency on livelihoods and adaptive capacity in rural Haiti

Author

McGreevy, John Ryan and Adrien, Elisson

Published

2023

29. Magnetotransport in a model of a disordered strange metal

Author

Patel, Aavishkar A., McGreevy, John, Arovas, Daniel P., and Sachdev, Subir

Subjects

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

Abstract

Despite much theoretical effort, there is no complete theory of the 'strange' metal state of the high temperature superconductors, and its linear-in-temperature, $T$, resistivity. Recent experiments showing an unexpected linear-in-field, $B$, magnetoresistivity have deepened the puzzle. We propose a simple model of itinerant electrons, interacting via random couplings with electrons localized on a lattice of quantum 'dots' or 'islands'. This model is solvable in a large-$N$ limit, and can reproduce observed behavior. The key feature of our model is that the electrons in each quantum dot are described by a Sachdev-Ye-Kitaev model describing electrons without quasiparticle excitations. For a particular choice of the interaction between the itinerant and localized electrons, this model realizes a controlled description of a diffusive marginal-Fermi liquid (MFL) without momentum conservation, which has a linear-in-$T$ resistivity and a $T \ln T$ specific heat as $T\rightarrow 0$. By tuning the strength of this interaction relative to the bandwidth of the itinerant electrons, we can additionally obtain a finite-$T$ crossover to a fully incoherent regime that also has a linear-in-$T$ resistivity. We show that the MFL regime has conductivities which scale as a function of $B/T$; however, its magnetoresistance saturates at large $B$. We then consider a macroscopically disordered sample with domains of MFLs with varying densities of electrons. Using an effective-medium approximation, we obtain a macroscopic electrical resistance that scales linearly in the magnetic field $B$ applied perpendicular to the plane of the sample, at large $B$. The resistance also scales linearly in $T$ at small $B$, and as $T f(B/T)$ at intermediate $B$. We consider implications for recent experiments reporting linear transverse magnetoresistance in the strange metal phases of the pnictides and cuprates., Comment: 21 pages + Appendices + References, 4 figures

Published

2017

30. Neutrino Oscillation Measurements Computed in Quantum Field Theory

Author

Kobach, Andrew, Manohar, Aneesh V., and McGreevy, John

Subjects

High Energy Physics - Phenomenology, High Energy Physics - Theory

Abstract

We perform a calculation in quantum field theory of neutrino oscillation probabilities, where we include simultaneously the source, detector, and neutrino fields in the Hamiltonian. Within the appropriate limits associated with current neutrino oscillation experiments, we recover the standard oscillation formula. On the other hand, we find that the dominant contributions to the amplitude are associated with different neutrino mass eigenstates being emitted at different times, such that they arrive at the detector at the same time. This is contrary to the neutrino wave packet picture, where they are emitted simultaneously and separate as they travel to the detector. This has direct consequences regarding the mechanisms that lead to a damping of neutrino oscillations for very long baselines. Our analysis also provides a pedagogical example of a measurement process in quantum mechanics., Comment: 12+12 pages, 3 figures; v2: improved appendix B, added refs, close to published version

Published

2017

31. Strange metal from local quantum chaos

Author

Ben-Zion, Daniel and McGreevy, John

Subjects

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

Abstract

How to make a model of a non-Fermi-liquid metal with efficient current dissipation is a long-standing problem. Results from holographic duality suggest a framework where local critical fermionic degrees of freedom provide both a source of decoherence for the Landau quasiparticle, and a sink for its momentum. This leads us to study a Kondo lattice type model with SYK models in place of the spin impurities. We find evidence for a stable phase at intermediate couplings., Comment: 21+11 pages, 15 figures. v2: added references and minor clarifications

Published

2017

32. 'No Longer a European Export'

Author

McGreevy, John T.

Subjects

Company growth, Market trend/market analysis, Humanities, Literature/writing, Political science

Abstract

How the Church became truly global Quick: Name the countries with the most baptized Catholics. You might guess Brazil (172.2 million) or the United States (72.3 million). You might miss [...]

Published

2022

33. 'Natural Enemies' No More

Author

McGreevy, John T.

Subjects

Christianity and politics -- Analysis, Catholics -- Political activity, Democracy -- Religious aspects -- United States, Humanities, Literature/writing, Political science

Abstract

How Rome finally embraced democracy Should Catholics promote democracy? The answer did not seem obvious in 1941. Exiled to New York City as the Wehrmacht occupied France, philosopher Jacques Maritain, [...]

Published

2022

34. Mixed s-sourcery: Building many-body states using bubbles of Nothing

Author

Swingle, Brian and McGreevy, John

Subjects

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

Abstract

In arXiv:1407.8203, we introduced the idea of s-sourcery, a general formalism for building many-body quantum ground states using renormalization-group-inspired quantum circuits. Here we define a generalized notion of s-sourcery that applies to mixed states, and study its properties and applicability. We prove a number of theorems establishing the prevalence of mixed s-source fixed points. For our examples we focus on thermal states of local Hamiltonians. Thermal double states (also called thermofield double states) and the machinery of approximate conditional independence are used heavily in the constructions., Comment: only 61 pages, lots of pictures

Published

2016

35. Viewpoint: duality for fermionic vortices

Author

McGreevy, John

Subjects

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

Abstract

This is a version (less professional editing, more details and jokes) of an APS Physics Viewpoint about three recent papers extending charge-vortex duality to fermionic vortices., Comment: 7 pages, 1 figure. Fancier version at http://physics.aps.org/articles/v9/72

Published

2016

36. TASI lectures on quantum matter (with a view toward holographic duality)

Author

McGreevy, John

Subjects

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

Abstract

These are notes from my lectures at TASI 2015. The goal is to provide context for the study of strongly-correlated quantum many-body systems using quantum field theory, and possibly string theory., Comment: 88 pages, many pictures

Published

2016

37. Renormalization Group Circuits for Gapless States

Author

Swingle, Brian, McGreevy, John, and Xu, Shenglong

Subjects

Condensed Matter - Strongly Correlated Electrons, Quantum Physics

Abstract

We show that a large class of gapless states are renormalization group fixed points in the sense that they can be grown scale by scale using local unitaries. This class of examples includes some theories with dynamical exponent different from one, but does not include conformal field theories. The key property of the states we consider is that the ground state wavefunction is related to the statistical weight of a local statistical model. We give several examples of our construction in the context of Ising magnetism., Comment: 22+9 pages

Published

2016

38. Worldsheet matter for electric flux strings

Author

Ben-Zion, Daniel, Das, Diptarka, and McGreevy, John

Subjects

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

Abstract

We develop a scheme to make exactly solvable gauge theories whose electric flux lines host (1+1)-dimensional topological phases. We use this exact `decorated-string-net' framework to construct several classes of interesting models. In particular, we construct an exactly solvable model of a quantum spin liquid whose (gapped) elementary excitations form doublets under an internal symmetry, and hence may be regarded as spin-carrying spinons. The model may be formulated, and is solvable, in any number of dimensions, on any bipartite graph. Another example, in any dimension, has $Z_2$ topological order and anyons which are Kramers' doublets of time reversal symmetry. Further, we make exactly solvable models of 3d topological paramagnets., Comment: 20+12 pages, 2 figures

Published

2015

39. Area Law for Gapless States from Local Entanglement Thermodynamics

Author

Swingle, Brian and McGreevy, John

Subjects

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

Abstract

We demonstrate an area law bound on the ground state entanglement entropy of a wide class of gapless quantum states of matter using a strategy called local entanglement thermodynamics. The bound depends only on thermodynamic data, actually a single exponent, the hyper-scaling violation exponent $\theta$. All systems in $d$ spatial dimensions obeying our scaling assumptions and with $\theta < d-1$ obey the area law, while systems with $\theta = d-1$ can violate the area law at most logarithmically. We also discuss the case of frustration-free Hamiltonians and show that to violate the area law more than logarithmically these systems must have an unusually large number of low energy states. Finally, we make contact with the recently proposed $s$-source framework and argue that $\theta$ and $s$ are related by $s=2^\theta$., Comment: 8 pages, 1 figure

Published

2015

40. RESPONSE.

Author

McGreevy, John T.

Subjects

*MODERN history, *HISTORIOGRAPHY

Abstract

The article presents a response from the author of the book "Catholicism: A Global History from the French Revolution to Pope Francis" on several reviews made on the book. He states that his goal was to place Catholicism from a global standpoint. He agrees with reviewer James Jay Carney that he is consistently strong in his depictions of Catholicism in Latin America but weaker on the day-to-day life of Catholicism in sub-Saharan Africa.

Published

2024

41. Conformal Field Theory Ground States as Critical Points of an Entropy Function

Author

Lin, Ting-Chun, primary and McGreevy, John, additional

Published

2023

42. Response

Author

McGreevy, John T., primary

Published

2023

43. All-fermion electrodynamics and fermion number anomaly inflow

Author

Kravec, S. M., McGreevy, John, and Swingle, Brian

Subjects

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

Abstract

We demonstrate that 3+1-dimensional quantum electrodynamics with fermionic charges, fermionic monopoles, and fermionic dyons arises at the edge of a 4+1-dimensional gapped state with short-range entanglement. This state cannot be adiabatically connected to a product state, even in the absence of any symmetry. This provides independent evidence for the obstruction found by arXiv:1306.3238 to a 3+1-dimensional short-distance completion of all-fermion electrodynamics. The non-triviality of the bulk is demonstrated by a novel fermion number anomaly., Comment: 37 pages, 5 figures

Published

2014

44. Renormalization group constructions of topological quantum liquids and beyond

Author

Swingle, Brian and McGreevy, John

Subjects

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

Abstract

We give a detailed physical argument for the area law for entanglement entropy in gapped phases of matter arising from local Hamiltonians. Our approach is based on renormalization group (RG) ideas and takes a resource oriented perspective. We report four main results. First, we argue for the "weak area law": any gapped phase with a unique ground state on every closed manifold obeys the area law. Second, we introduce an RG based classification scheme and give a detailed argument that all phases within the classification scheme obey the area law. Third, we define a special sub-class of gapped phases, \textit{topological quantum liquids}, which captures all examples of current physical relevance, and we rigorously show that TQLs obey an area law. Fourth, we show that all topological quantum liquids have MERA representations which achieve unit overlap with the ground state in the thermodynamic limit and which have a bond dimension scaling with system size $L$ as $e^{c \log^{d(1+\delta)}(L)}$ for all $\delta >0$. For example, we show that chiral phases in $d=2$ dimensions have an approximate MERA with bond dimension $e^{c \log^{2(1+\delta)}(L)}$. We discuss extensively a number of subsidiary ideas and results necessary to make the main arguments, including field theory constructions. While our argument for the general area law rests on physically-motived assumptions (which we make explicit) and is therefore not rigorous, we may conclude that "conventional" gapped phases obey the area law and that any gapped phase which violates the area law must be a dragon., Comment: 91 pages, 8 figures

Published

2014

45. What Does It Take Now?

Author

McGreevy, John T.

Subjects

What It Took to Win: A History of the Democratic Party (Nonfiction work) -- Kazin, Michael, Books -- Book reviews, Humanities, Literature/writing, Political science

Abstract

It is the world's oldest mass political organization, founded by Andrew Jackson and Martin Van Buren in the early nineteenth century, promoted at first through partisan newspapers and now releasing [...]

Published

2022

46. Charge transport by holographic Fermi surfaces

Author

Faulkner, Thomas, Iqbal, Nabil, Liu, Hong, McGreevy, John, and Vegh, David

Subjects

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

Abstract

We compute the contribution to the conductivity from holographic Fermi surfaces obtained from probe fermions in an AdS charged black hole. This requires calculating a certain part of the one-loop correction to a vector propagator on the charged black hole geometry. We find that the current dissipation is as efficient as possible and the transport lifetime coincides with the single-particle lifetime. In particular, in the case where the spectral density is that of a marginal Fermi liquid, the resistivity is linear in temperature., Comment: 37 pages, 9 figures; references added

Published

2013

47. How to construct a gravitating quantum electron star

Author

Allais, Andrea and McGreevy, John

Subjects

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

Abstract

Motivated by the holographic study of Fermi surfaces, we develop methods to solve Einstein gravity coupled to fermions and gauge fields, with AdS boundary conditions and a chemical potential., Comment: 47 pages, 7 figures

Published

2013

48. A gauge theory generalization of the fermion-doubling theorem

Author

Kravec, S. M. and McGreevy, John

Subjects

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

Abstract

It is possible to characterize certain states of matter by properties of their edge states. This implies a notion of `surface-only models': models which can only be regularized at the edge of a higher-dimensional system. After incorporating the fermion-doubling results of Nielsen and Ninomiya into this framework, we employ this idea to identify new obstructions to symmetry-preserving regulators of quantum field theory. We focus on an example which forbids regulated models of Maxwell theory with manifest electromagnetic duality symmetry., Comment: 10 pages

Published

2013

49. Continuous transitions between composite Fermi liquid and Landau Fermi liquid: a route to fractionalized Mott insulators

Author

Barkeshli, Maissam and McGreevy, John

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

One of the most successful theories of a non-Fermi liquid metallic state is the composite Fermi liquid (CFL) theory of the half-filled Landau level. In this paper, we study continuous quantum phase transitions out of the CFL state and into a Landau Fermi liquid, in the limit of no disorder and fixed particle number. This transition can be induced by tuning the bandwidth of the Landau level relative to the interaction energy, for instance through an externally applied periodic potential. We find a transition to the Landau Fermi liquid through a gapless Mott insulator with a Fermi surface of neutral fermionic excitations. In the presence of spatial symmetries, we also find a direct continuous transition between the CFL and the Landau Fermi liquid. The transitions have a number of characteristic observable signatures, including the presence of two crossover temperature scales, resistivity jumps, and vanishing compressibility. When the composite fermions are paired instead, our results imply quantum critical points between various non-Abelian topological states, including the \nu = 1/2 Moore-Read Pfaffian (Ising x U(1) topological order), a version of the Kitaev B phase (Ising topological order), and paired electronic superconductors. To study such transitions, we use a projective construction of the CFL, which goes beyond the conventional framework of flux attachment to include a broader set of quantum fluctuations. These considerations suggest a possible route to fractionalized Mott insulators by starting with FQH states and tuning the Landau level bandwidth., Comment: 15 pages

Published

2012

50. Quantum spin liquids and the metal-insulator transition in doped semiconductors

Author

Potter, Andrew C., Barkeshli, Maissam, McGreevy, John, and Senthil, T.

Subjects

Condensed Matter - Strongly Correlated Electrons

Abstract

We describe a new possible route to the metal-insulator transition in doped semiconductors such as Si:P or Si:B. We explore the possibility that the loss of metallic transport occurs through Mott localization of electrons into a quantum spin liquid state with diffusive charge neutral "spinon" excitations. Such a quantum spin liquid state can appear as an intermediate phase between the metal and the Anderson-Mott insulator. An immediate testable consequence is the presence of metallic thermal conductivity at low temperature in the electrical insulator near the metal-insulator transition. Further we show that though the transition is second order the zero temperature residual electrical conductivity will jump as the transition is approached from the metallic side. However the electrical conductivity will have a non-monotonic temperature dependence that may complicate the extrapolation to zero temperature. Signatures in other experiments and some comparisons with existing data are made., Comment: 4 pages text + 3 pages Appendices, 3 Figures; v2 - References Added

Published

2012