De Gruyter Textbook Hindmann / Strauss • Algebra in the Stone-Čech Compactification Neil Hindman, Dona Strauss Algebra in the Stone-Čech Compactification Theory and Applications 2nd revised and extended edition De Gruyter Mathematics Subject Classification 2010: Primary: 05D10, 22A15, 54D35, 54H20; Secondary: 03E05, 20M10, 54H13. ISBN: 978-3-11-025623-9 e-ISBN: 978-3-11-025835-6 Library of Congress Cataloging-in-Publication Data Hindman, Neil, 1943– Algebra in the Stone-Cech compactification : theory and applications / by Neil Hindman, Donna Strauss. – 2nd revised and extended ed. p. cm. – (De gruyter textbook) Includes bibliographical references and index. ISBN 978-3-11-025623-9 (alk. paper) 1. Stone-Cech compactification. 2. Topological semigroups. I. Strauss, Dona, 1934– II. Title. QA611.23.H56 2012 514′.32–dc23 2011039515 Bibliographic information published by the Deutsche Nationalbibliothek The Deutsche Nationalbibliothek lists this publication in the Deutsche Nationalbibliografie; detailed bibliographic data are available in the internet at http://dnb.d-nb.de. © 2012 Walter de Gruyter GmbH & Co. KG, 10785 Berlin/Boston Typesetting: Da-TeX Gerd Blumenstein, Leipzig, www.da-tex.de Printing and binding: Hubert & Co. GmbH & Co. KG, Göttingen °° Printed on acid-free paper Printed in Germany www.degruyter.com Preface to the First Edition The semigroup operation defined on a discrete semigroup .S;(cid:2)/ has a natural exten- sion, also denoted by (cid:2), to the Stone–Cˇech compactification ˇS of S. Under the extended operation, ˇS is a compact right topological semigroup with S contained in its topological center. That is, for each p 2 ˇS, the function (cid:2) W ˇS ! ˇS is p continuous and for each s 2 S, the function (cid:3) W ˇS ! ˇS is continuous, where s (cid:2) .q/Dq(cid:2)p and(cid:3) .q/Ds(cid:2)q. p s InPartIofthisbook,assumingonlythemathematicalbackgroundstandardlypro- videdinthefirstyearofgraduateschool,wedevelopthebasicbackgroundinforma- tion about compact right topological semigroups, the Stone–Cˇech compactification of a discrete space, and the extension of the semigroup operation on S to ˇS. In PartII,westudyindepththealgebraofthesemigroup.ˇS;(cid:2)/andinPartIIIpresent some of the powerful applications of the algebra of ˇS to the part of combinatorics knownasRamseyTheory. WeconcludeinPartIVwithconnectionswithTopological Dynamics,ErgodicTheory,andthegeneraltheoryofsemigroupcompactifications. The study of the semigroup .ˇS;(cid:2)/ has interested several mathematicians since it wasfirstdefinedinthelate1950s. Asaglanceatthebibliographywillshow,alarge numberofresearchpapershavebeendevotedtoitsproperties. ThereareseveralreasonsforaninterestinthealgebraofˇS. ItisintrinsicallyinterestingasbeinganaturalextensionofS whichplaysaspecial role among semigroup compactifications of S. It is the largest possible compactifi- cationofthiskind: IfT isacompactrighttopologicalsemigroup, ' isacontinuous homomorphism from S to T, 'ŒS(cid:4) is dense in T, and (cid:3) is continuous for each '.s/ s 2S,thenT isaquotientofˇS. We believe that ˇN is interesting and challenging for its own sake, as well as for its applications. Although it is a natural extension of the most familiar of all semi- groups,ithasanalgebraicstructureofextraordinarycomplexity,whichisconstantly surprising. Forexample,ˇN containsmanycopiesofthefreegroupon2cgenerators [244]. AlgebraicquestionsaboutˇN whichsounddeceptivelysimplehaveremained unsolvedformanyyears. Itis,forinstance,notknownwhetherˇN containsanyel- ementsoffiniteorder,otherthanidempotents. Andthecorrespondingquestionabout the existence of nontrivial finite groups was only very recently answered by Y. Ze- lenyuk. (HisnegativeanswerispresentedinChapter7.) The semigroup ˇS is also interesting because of its applications to combinatorial numbertheoryandtotopologicaldynamics. Algebraic properties of ˇS have been a useful tool in Ramsey theory. Results in Ramsey Theory have a twin beauty. On the one hand they are representatives of vi PrefacetotheFirstEdition pure mathematics at its purest: simple statements easy for almost anyone to under- stand(thoughnotnecessarilytoprove). Ontheotherhand,theareahasbeenwidely applied from its beginning. In fact a perusal of the titles of several of the original papers reveals that many of the classical results were obtained with applications in mind. (Hilbert’sTheorem–Algebra;Schur’sTheorem–NumberTheory;Ramsey’s Theorem–Logic;theHales–JewettTheorem–GameTheory). The most striking example of an application of the algebraic structure of ˇS to Ramsey Theory is perhaps provided by the Finite Sums Theorem. This theorem says that whenever N is partitioned into finitely many classes (or in the terminol- ogycommonwithinRamseyTheory,isfinitelycolored),thereisasequencehx i1 n nD1 with FS.hx i1 / contained in one class (or monochrome). (Here FS.hx i1 / D n nD1 n nD1 P ¹ x W F is a finite nonempty subset of Nº.) This theorem had been an open n2F n problem for some decades, even though several mathematicians (including Hilbert) hadworkedonit. AlthoughitwasinitiallyprovedwithoutusingˇN, thefirstproof givenwasoneofenormouscomplexity. In 1975 F. Galvin and S. Glazer provided a brilliantly simple proof of the Finite SumsTheoremusingthealgebraicstructureofˇN. Sincethistimenumerousstrong combinatorial results have been obtained using the algebraic structure of ˇS, where S isanarbitrarydiscretesemigroup. Intheprocess,moredetailedknowledgeofthe algebraofˇS hasbeenobtained. Other famous combinatorial theorems, such as van der Waerden’s Theorem or Rado’sTheorem,haveelegantproofsbasedonthealgebraicpropertiesofˇN. These proofs have in common with the Finite Sums Theorem the fact that they were ini- tially established by combinatorial methods. A simple extension of the Finite Sums Theorem was first established using the algebra of ˇN. This extension says that wheneverN isfinitelycoloredthereexistsequenceshx i1 andhy i1 suchthat n nD1 n nD1 FS.hx i1 /[FP.hy i1 /ismonochrome,whereFP.hy i1 /D¹Q y WF n nD1 n nD1 n nD1 n2F n is a finite nonempty subset of Nº. This combined additive and multiplicative result wasfirstprovedin1975usingthealgebraicstructureofˇN anditwasnotuntil1993 thatanelementaryproofwasfound. Other fundamental results have been established for which it seems unlikely that elementaryproofswillbefound. AmongsuchresultsisadensityversionoftheFinite Sums Theorem, which says roughly that the sequence hx i1 whose finite sums n nD1 are monochrome can be chosen inductively in such a way that at each stage of the induction the set of choices for the next term has positive upper density. Another suchresultistheCentralSetTheorem,whichisacommongeneralizationofmanyof thebasicresultsofRamseyTheory. Significantprogresscontinuestobemadeinthe combinatorialapplications. ThesemigroupˇS alsohasapplicationsintopologicaldynamics. Asemigroup S X ofcontinuousfunctionsactingonacompactHausdorffspaceX hasaclosurein X (the space of functions mapping X to itself with the product topology), which is a PrefacetotheFirstEdition vii compact right topological semigroup. This semigroup, called the enveloping semi- group, was first studied by R. Ellis [134]. It is always a quotient of the Stone–Cˇech compactification ˇS, as is every semigroup compactification of S, and is, in some importantcases,equaltoˇS. Inthisframework,thealgebraicpropertiesofˇS have implicationsforthedynamicalbehaviorofthesystem. Theinteractionwithtopologicaldynamicsworksbothways. Severalnotionswhich originatedintopologicaldynamics,suchassyndeticandpiecewisesyndeticsets,are importantindescribingthealgebraicstructureofˇS. Forexample, apointp ofˇS isintheclosureofthesmallestideal of ˇS ifandonlyifforeveryneighborhood U ofp,U \S ispiecewisesyndetic. This last statement can be made more concise when one notes the particular con- structionofˇS thatweuse. Thatis,ˇS isthesetofallultrafiltersonS,theprincipal ultrafiltersbeingidentifiedwiththepointsofS. Underthisconstruction,anypointp of ˇS is precisely ¹U \S W U is a neighborhood of pº. Thusp is in the closure of thesmallestidealofˇS ifandonlyifeverymemberofp ispiecewisesyndetic. Inthisbook,wedevelopthealgebraictheoryofˇS andpresentseveralofitscom- binatorial applications. We assume only that the reader has had graduate courses in algebra, analysis, and general topology as well as a familiarity with the basic facts about ordinal and cardinal numbers. In particular we develop the basic structure of compactrighttopologicalsemigroupsandprovideanelementaryconstructionofthe Stone–Cˇechcompactificationofadiscretespace. With only three exceptions, this book is self contained for those with that min- imal background. The three cases where we appeal to non elementary results not provedhereareTheorem6.36(duetoM.RudinandS.Shelah)whichassertstheex- istence of a collection of 2celements of ˇN no two of which are comparable in the Rudin–Keisler order, Theorem 12.37 (due to S. Shelah) which states that the exis- tenceofP-pointsinˇNnN cannotbeestablishedinZFC,andTheorem20.13(dueto H.Furstenberg)whichisanergodictheoreticresultthatweusetoderiveSzemerédi’s Theorem. AllofourapplicationsinvolveHausdorffspaces,sowewillbeassumingthrough- out,exceptinChapter7,thatallhypothesizedtopologicalspacesareHausdorff. The first five chapters are meant to provide the basic preliminary material. The concepts and theorems given in the first three of these chapters are also available in otherbooks. Theremainingchaptersofthebookcontainresultswhich,forthemost part, can only be found in research papers at present, as well as several previously unpublishedresults. Notesonthehistoricaldevelopmentaregivenattheendofeachchapter. Let us make a few remarks about organization. Chapters are numbered consecu- tivelythroughoutthebook,regardlessofwhichofthefourpartsofthebookcontains them. Lemmas, theorems, corollaries, examples, questions, comments, and remarks are numbered consecutively in one group within chapters (so that Lemma 2.4 will viii PrefacetotheFirstEdition be found after Theorem 2.3, for example). There is no logical distinction between a theorem and a remark. The difference is that proofs are never included for remarks. Exercisescomeattheendofsectionsandarenumberedconsecutivelywithinsections. The authors would like to thank Andreas Blass, Karl Hofmann, Paul Milnes, and Igor Protasov for much helpful correspondence and discussions. Special thanks go to John Pym for a careful and critical reading of an early version of the manuscript. The authors also wish to single out Igor Protasov for special thanks, as he has con- tributedseveralnewtheoremstothebook. TheywouldliketothankArthurGrainger, AmirMaleki,DanTang,ElaineTerry,andWenJinWoan forparticipatinginasem- inar where much of the material in this book was presented, and David Gunderson forpresentinglecturesbasedontheearlymaterialinthebook. Acknowledgementis also due toourcollaborators whoseefforts are featured inthis book. These collabo- rators include John Baker, Vitaly Bergelson, John Berglund, Andreas Blass, Dennis Davenport,WalterDeuber,AhmedEl-Mabhouh,HillelFurstenberg,SalvadorGarcía- Ferreira,YitzhakKatznelson,JimmieLawson,AmhaLisan,ImreLeader,HannoLef- mann, Amir Maleki, Jan van Mill, Paul Milnes, John Pym, Petr Simon, Benjamin Weiss,andWen-jinWoan. The authors would like to acknowledge support of a conference on the subject of this book in March of 1997 by DFG Sonderforschungsbereich 344, Diskrete Struk- turen in der Mathematik, Universität Bielefeld, and they would like to thank Walter Deuberfororganizingthisconference. BothauthorswouldliketothanktheEPSRC (UK) for support of a visit and the first author acknowledges support received from theNationalScienceFoundation(USA)undergrantDMS9424421duringtheprepa- rationofthisbook. Finally, the authors would like to thank their spouses, Audrey and Ed, for their patiencethroughoutthewritingofthisbookaswellashospitalityextendedtoeachof usduringvisitswiththeother. April1998 NeilHindman,DonaStrauss Preface to the Second Edition Inthefourteenyearssincethepublicationofthefirstedition,researchinthealgebraic theory of the Stone–Cˇech compactification of a discrete semigroup has been very active. (We have added more than 165 research papers to the bibliography.) In this editionwehaveaddedseveralofthemoreaccessibleresultsthathavebeenestablished during this time. These include six new sections, namely 1.1.1, 4.5, 7.4, 9.5, 14.6, and 15.6. They also include more than 50 new lemmas and theorems. In addition, many typographical errors have been corrected, and the notes at the end of chapters havebeenextended. Thefirsteditionhasbeenwidelycitedinthemathematicalliterature,andwehave beenveryconcernedwithmaintainingitsvalueasareference. Accordingly,withtwo exceptions,anyresultsinthesecondeditionthatshareanumberwitharesultfromthe first edition are either identical with that result or trivially imply the result from the first edition. (The two exceptions are Lemmas 12.40 and 12.41 which are technical lemmas replacing earlier technical lemmas which we do not feel are of independent interest.) Newmaterialthathasbeeninsertedbeforetheoldendofchapterreceivesa newnumberoftheformx.y.zwherethenumberx.yistheitemfromthefirstedition that immediately precedes it. For example in between Definition 14.14 and Theo- rem 14.15 from the first edition come a definition and eight lemmas and theorems numbered14.14.1through14.14.9. Insomecases,wehavehadtomoveresultsearlierinthetextbecausenewlyinserted materialneededtheseresults. Forexample,Lemma6.6wasneededfornewmaterial whichfitnaturallyinChapter5soitbecameLemma5.19.1. WealsokeptLemma6.6 initsplaceandsimplycitedLemma5.19.1foritsproof. Wedonot,however,repeat definitionswhichwehavebeenforcedtomoveearlierinthetext. Inthosecases,the numberassociatedwiththedefinitioninthefirsteditionissimplyomitted. Wehaveaddedonemoreresult,namelyTheorem17.35.1,tothethreeresultsinthe firsteditionwhichweusebutdonotprove. Intheprefacetothefirstedition,wesaidthatwethoughtitunlikelythatanelemen- taryproofofthedenseFiniteSumsTheoremwouldbefound. However,H.Towsner hasrecentlydiscoveredsuchaproof[378]. ThefirstauthoracknowledgessupportreceivedfromtheNationalScienceFounda- tion(USA)viagrantDMS-0852512duringthepreparationofthisrevision. Washington/Leeds,September2001 NeilHindman,DonaStrauss