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Quantum Information Meets Quantum Matter: From Quantum Entanglement to Topological Phases of Many-Body Systems PDF

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Quantum Science and Technology Bei Zeng Xie Chen Duan-Lu Zhou Xiao-Gang Wen Quantum Information Meets Quantum Matter From Quantum Entanglement to Topological Phases of Many-Body Systems Quantum Science and Technology Series Editors Raymond Laflamme, Waterloo, ON, Canada Gaby Lenhart, Sophia Antipolis, France Daniel Lidar, Los Angeles, CA, USA Arno Rauschenbeutel, Vienna University of Technology, Vienna, Austria Renato Renner, Institut für Theoretische Physik, ETH Zürich, Zürich, Switzerland MaximilianSchlosshauer,DepartmentofPhysics,UniversityofPortland,Portland, OR, USA Yaakov S. Weinstein, Quantum Information Science Group, The MITRE Corporation, Princeton, NJ, USA H. M. Wiseman, Brisbane, QLD, Australia Aims and Scope The book series Quantum Science and Technology is dedicated to one of today’s mostactiveandrapidlyexpandingfieldsofresearchanddevelopment.Inparticular, the series will be a showcase for the growing number of experimental implemen- tations and practical applications of quantum systems. These will include, but are not restricted to: quantum information processing, quantum computing, and quantum simulation; quantum communication and quantum cryptography; entan- glement and other quantum resources; quantum interfaces and hybrid quantum systems; quantum memories and quantum repeaters; measurement-based quantum control and quantum feedback; quantum nanomechanics, quantum optomechanics and quantum transducers; quantum sensing and quantum metrology; as well as quantum effects in biology. Last but not least, the series will include books on the theoretical and mathematical questions relevant to designing and understanding these systems and devices, as well as foundational issues concerning the quantum phenomena themselves. Written and edited by leading experts, the treatments will be designed for graduate students and other researchers already working in, or intending to enter the field of quantum science and technology. More information about this series at http://www.springer.com/series/10039 Bei Zeng Xie Chen Duan-Lu Zhou (cid:129) (cid:129) (cid:129) Xiao-Gang Wen Quantum Information Meets Quantum Matter From Quantum Entanglement to Topological Phases of Many-Body Systems 123 BeiZeng XieChen University of Guelph Physics Guelph,ON, Canada California Institute ofTechnology Pasadena,CA, USA Duan-LuZhou Institute of Physics Xiao-GangWen ChineseAcademy of Sciences Massachusetts Institute of Technology Beijing,China Cambridge, MA, USA ISSN 2364-9054 ISSN 2364-9062 (electronic) QuantumScience andTechnology ISBN978-1-4939-9082-5 ISBN978-1-4939-9084-9 (eBook) https://doi.org/10.1007/978-1-4939-9084-9 LibraryofCongressControlNumber:2018965449 ©SpringerScience+BusinessMedia,LLC,partofSpringerNature2019 Thisworkissubjecttocopyright.AllrightsarereservedbythePublisher,whetherthewholeorpart of the material is concerned, specifically the rights of translation, reprinting, reuse of illustrations, recitation, broadcasting, reproduction on microfilms or in any other physical way, and transmission orinformationstorageandretrieval,electronicadaptation,computersoftware,orbysimilarordissimilar methodologynowknownorhereafterdeveloped. The use of general descriptive names, registered names, trademarks, service marks, etc. in this publicationdoesnotimply,evenintheabsenceofaspecificstatement,thatsuchnamesareexemptfrom therelevantprotectivelawsandregulationsandthereforefreeforgeneraluse. The publisher, the authors and the editors are safe to assume that the advice and information in this book are believed to be true and accurate at the date of publication. Neither the publisher nor the authorsortheeditorsgiveawarranty,expressorimplied,withrespecttothematerialcontainedhereinor for any errors or omissions that may have been made. The publisher remains neutral with regard to jurisdictionalclaimsinpublishedmapsandinstitutionalaffiliations. This Springer imprint is published by the registered companySpringer Science+Business Media, LLCpartofSpringerNature Theregisteredcompanyaddressis:233SpringStreet,NewYork,NY10013,U.S.A. Foreword In1989,IattendedaworkshopattheUniversityofMinnesota.Theorganizershad hoped the workshop would spawn new ideas about the origin of high-temperature superconductivity, which had recently been discovered. But I was especially impressed by a talk about the fractional quantum Hall effect by a young physicist named Xiao-Gang Wen. FromWen,Iheardforthefirsttimeaboutaconceptcalledtopologicalorder.He explainedthatforsomequantumphasesoftwo-dimensionalmatterthegroundstate becomes degenerate when the system resides on a surface of nontrivial topology such as a torus, and that the degree of degeneracy provides a useful signature for distinguishing different phases. I was fascinated. Up until then, studies of phases of matter and the transitions between them usuallybuiltonprinciplesannunciateddecadesearlierbyLevLandau.Landauhad emphasized the crucial role of symmetry, and of local-order parameters that dis- tinguishdifferentsymmetryrealizations.ThoughmuchofwhatWensaidwentover myhead,Ididmanagetogleanthathewasproposingawaytodistinguishquantum phasesfoundedonmuchdifferentprinciplesthanLandau’s.Asaparticlephysicist, I deeply appreciated the power of Landau theory, but I was also keenly aware that the interface of topology and physics had already yielded many novel and fruitful insights. Mullingovertheseideasontheplaneridehome,Iscribbledafewlinesofverse: Nowweareallowed TodisavowLandau. Wow… Without knowing where it might lead, one could sense the opening of a new chapter. At around that same time, another new research direction was beginning to gathersteam,thestudyofquantuminformation.RichardFeynmanandYuriManin hadsuggestedthatacomputerprocessingquantuminformationmightperformtasks beyondthereachofordinarydigitalcomputers.DavidDeutschformalizedtheidea, which attracted the attention of computer scientists, and eventually led to Peter v vi Foreword Shor’s discoverythat aquantumcomputer can factor large numbersinpolynomial time. Meanwhile, Alexander Holevo, Charles Bennett, and others seized the opportunity to unify Claude Shannon’s information theory with quantum physics, erecting new schemes for quantifying quantum entanglement and characterizing processes in which quantum information is acquired, transmitted, and processed. ThediscoveryofShor’salgorithmcausedaburstofexcitementandactivity,but quantuminformationscienceremainedoutsidethemainstreamofphysics,andfew scientists at that time glimpsed the rich connections between quantum information and the study of quantum matter. One notable exception was Alexei Kitaev, who had two remarkable insights in the 1990s. He pointed out that finding the ground-state energy of a quantum system defined by a “local” Hamiltonian, when suitablyformalized,isashardasanyproblemwhosesolutioncanbeverifiedwitha quantumcomputer.ThisidealaunchedthestudyofHamiltoniancomplexity.Kitaev alsodiscernedtherelationshipbetweenWen’sconceptoftopologicalorderandthe quantum error-correcting codes that can protect delicate quantum superpositions from the ravages of environmental decoherence. Kitaev’s notion of a topological quantum computer, a mere theorist’s fantasy when proposed in 1997, is by now pursued in experimental laboratories around the world (though the technology still hasfartogobeforetrulyscalablequantumcomputerswillbecapableofaddressing hard problems). Thereafter progress accelerated, led by a burgeoning community of scientists workingattheinterfaceofquantuminformationandquantummatter.GuifreVidal realizedthatmany-particlequantumsystemsthatareonlyslightlyentangledcanbe succinctlydescribedusingtensornetworks.Thisnewmethodextendedthereachof mean-field theory and provided an illuminating new perspective on the successes oftheDensityMatrixRenormalizationGroup(DMRG).Byprovingthattheground stateofalocalHamiltonianwithanenergygaphaslimitedentanglement(thearea law), Matthew Hastings showed that tensor network tools are widely applicable. These tools eventually led to a complete understanding of gapped quantum phases in one spatial dimension. The experimental discovery of topological insulators focused attention on the interplay of symmetry and topology. The more general notion of a symmetry- protectedtopological(SPT)phasearose,inwhichaquantumsystemhasanenergy gapinthebulkbutsupportsgaplessexcitationsconfinedtoitsboundarywhichare protected by specified symmetries. (For topological insulators, the symmetries are particle-number conservation and time reversal invariance.) Again, tensor network methods proved to be well suited for establishing a complete classification of one-dimensional SPT phases, and guided progress toward understanding higher dimensions, though many open questions remain. WenowhaveamuchdeeperunderstandingoftopologicalorderthanwhenIfirst heard about it from Wen nearly 30 years ago. A central new insight is that topo- logicallyorderedsystemshavelong-rangeentanglement,andthattheentanglement has universal properties, like topological entanglement entropy, which are insen- sitivetothemicroscopicdetailsoftheHamiltonian.Indeed,topologicalorderisan intrinsicpropertyofaquantumstateandcanbeidentifiedwithoutreferencetoany Foreword vii particular Hamiltonian at all. To understand the meaning of long-range entangle- ment,imagineaquantumcomputerwhichappliesasequenceofgeometricallylocal operations to an input quantum state, producing an output product state which is completely disentangled. If the time required to complete this disentangling com- putation is independent of the size of the system, then we say the input state is short-range entangled; otherwise, it is long-range entangled. More generally (loosely speaking), two states are in different quantum phases if no constant-time quantum computation can convert one state to the other. This fundamental con- nection between quantum computation and quantum order has many ramifications which are explored in this book. When is the right time for a book that summarizes the status of an ongoing research area? It’s a subtle question. The subjectshould be sufficientlymature that enduringconceptsandresultscanbeidentifiedandclearlyexplained.Ifthepaceof progressissufficientlyrapid,andthetopicsemphasizedarenotwellchosen,thenan ill-timedbookmightbecomeobsoletequickly.Ontheotherhand,thesubjectought not to be too mature; only if there are many exciting open questions to attack will the book be likely to attract a sizable audience eager to master the material. IfeelconfidentthatQuantumInformationMeetsQuantumMatterisappearingat an opportune time, and that the authors have made wise choices about what to include. They are world-class experts and are themselves responsible for many ofthescientificadvancesexplainedhere.Thestudentorseniorscientistwhostudies this book closely will be well grounded in the tools and ideas at the forefront of current research at the confluence of quantum information science and quantum condensed matter physics. Indeed, I expect that in the years ahead a steadily expanding community of scientists, including computer scientists, chemists, andhigh-energy physicists, will want to be well acquainted with the ideas at the heart of Quantum Information Meets Quantum Matter. In particular, growingevidence suggests that thequantum physics of spacetime itself is an emergent manifestation of long-range quantum entanglementinanunderlyingmorefundamentalquantumtheory.Morebroadly,as quantum technology grows ever more sophisticated, I believe that the theoretical and experimental study of highly complex many-particle systems will be an increasingly central theme of twenty-first-century physical science. If that’s true, QuantumInformationMeetsQuantumMatterisboundtoholdanhonoredplaceon the bookshelves of many scientists for years to come. Pasadena, CA, USA John Preskill September 2018 Preface After decades of development, quantum information science and technology has nowcometoitsgoldenage.Itisnotonlywidelybelievedthatquantuminformation processing offers the secure and high rate information transmission, fast compu- tationalsolutionofcertainimportantproblems,whichareattheheartofthemodern informationtechnology.Butalso,itprovidesnewangles,tools,andmethodswhich helpinunderstandingotherfieldsofscience,amongwhichoneimportantareaisthe link to modern condensed matter physics. For a long time, people believe that all phases of matter are described by Landau’s symmetry-breaking theory, and the transitions between those phases are described by the change of those symmetry-breaking orders. However, after the discovery of fractional quantum Hall effect, it was realized in 1989 that the frac- tional quantum Hall states contain a new type of order (named topological order) whichisbeyondLandausymmetry-breakingtheory.Traditionalmany-bodytheory for condensed matter systems is mostly based on various correlation functions, which suite Landau symmetry-breaking theory very well. But this kind of approaches is totally inadequate for topological orders, since all different topo- logical orders have the similar short-range correlations. The traditional condensed matter theory mostly only considers two kinds of many-bodystates:productstates(suchasinvariousmean-fieldtheories)andstates obtained by filling orbitals (such as in Fermi liquid theory). Those two types of states fail to include the more general topologically ordered states. So the big questionis,canweunderstandwhatismissingintheabovetwotypesofstates,so that they fail to capture the topological order? What quantum information science brings is the information-theoretic under- standing of correlation, and a new concept called “entanglement”, which is a pure quantum correlation that has no classical counterpart. Such input from quantum information science led to a recent realization that the new topological order in some strongly correlated systems is nothing but the pattern of many-body entan- glement. The study of topological order and the related new quantum phases is ix x Preface actually a study of patterns of entanglement. The nontrivial patterns of entangle- mentaretherootofmanyhighlynovelphenomenaintopologicallyorderedphases (such as fractional quantum Hall states and spin liquid states), which include fractional charge, fractional statistics, protected gapless boundary excitations, emergence of gauge theory, Fermi statistics from purely bosonic systems, etc. The connection between quantum information science and condensed matter physics is not accidental, but has a very deep root. Quantum theory has explained and unified many microscopic phenomena, ranging from discrete spectrum of Hydrogen atom, black-body radiation, to interference of electron beam, etc. However, what quantum theory really unifies is information and matter. We know that a change or frequency is a property of information. But according to quantum theory, frequency corresponds to energy. According to the theory of relativity, energycorrespondstomass.Energyandmassarepropertiesofmatter.Inthissense, frequency leads to mass and information becomes matter. Butdowebelievethatmatter(andtheelementaryparticlesthatformthematter) all come from qubits? Is it possible that qubits are the building blocks of all the elementary particles? If matter were formed by simple spin-0 bosonic elementary particles,thenitwasquitepossiblethatthespin-0bosonicelementaryparticles,and thematterthattheyform,allcamefromqubits.Wecansimplyviewthespaceasa collection of qubits and the 0-state of qubits as the vacuum. Then, the 1-state of qubit will correspond to a spin-0 bosonic elementary particle in space. But our world is much more complicated. The matter in our world is formed by particles that have two really strange properties: Fermi statistics and fractional angular momentum (spin-1/2). Our world also have light, which correspond to spin-1 particles thatstrangelyonlyhavetwocomponents.Suchspin-1particles arecalled gauge bosons. Canspaceformedbysimplequbitsproducespin-1/2fermionsandspin-1gauge bosons?Inthelast20years(andasexplainedinthisbook),westarttorealizethat althoughqubitsareverysimple,theirorganization—theirquantumentanglement— can be extremely rich and complex. The long-range quantum entanglement of qubits makes it possible to use simple qubits to produce spin-1/2 fermions and spin-1 gauge bosons, as well as the matter formed by those elementary particles. Thousands of research papers studying the properties of quantum entanglement have been published in the past two decades. Notable progress includes, but not limited to, extensive study of correlation and entanglement properties in various strongly correlated systems, development of concepts of entanglement area law whichresultsinanewtoolcalledtensornetworkmethod,theroleofentanglement play in quantumphase transitions, theconcept oflong-range entanglement, and its useinthestudyoftopologicalphaseofmatter.Also,extensiveattentionshavebeen attracted on the new states of quantum matter and the emergence of fractional quantum numbers and fractional/Fermi statistics, with many published papers during the last decades along these directions. Itisnotpossibletoincludealltheseexcitingdevelopmentsinasinglebook.The scopeofthisbookisrathertointroducesomegeneralconceptsandbasicideasand methods that the viewpoints of quantum information scientists have on condensed

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