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MEMOIRS of the American Mathematical Society Volume 226 • Number 1063 (fourth of 5 numbers) • November 2013 Torsors, Reductive Group Schemes and Extended Affine Lie Algebras Philippe Gille Arturo Pianzola ISSN 0065-9266 (print) ISSN 1947-6221 (online) American Mathematical Society MEMOIRS of the American Mathematical Society Volume 226 • Number 1063 (fourth of 5 numbers) • November 2013 Torsors, Reductive Group Schemes and Extended Affine Lie Algebras Philippe Gille Arturo Pianzola ISSN 0065-9266 (print) ISSN 1947-6221 (online) American Mathematical Society Providence, Rhode Island Library of Congress Cataloging-in-Publication Data Gille,Philippe,1968-author. Torsors, reductive group schemes and extended affine Lie algebras / Philippe Gille, Arturo Pianzola. pagescm. –(MemoirsoftheAmericanMathematicalSociety,ISSN0065-9266;number1063) ”November2013,volume226,number1063(fourthof5numbers).” Includesbibliographicalreferences. ISBN978-0-8218-8774-5(alk. paper) 1.Kac-Moodyalgebras. 2.Linearalgebraicgroups. 3.Geometry,Algebraic. I.Pianzola, Arturo,1955-author. II.Title. QA252.3.G55 2013 512’.482–dc23 2013025512 DOI:http://dx.doi.org/10.1090/S0065-9266-2013-00679-X Memoirs of the American Mathematical Society Thisjournalisdevotedentirelytoresearchinpureandappliedmathematics. Publisher Item Identifier. The Publisher Item Identifier (PII) appears as a footnote on theAbstractpageofeacharticle. Thisalphanumericstringofcharactersuniquelyidentifieseach articleandcanbeusedforfuturecataloguing,searching,andelectronicretrieval. Subscription information. Beginning with the January 2010 issue, Memoirs is accessible from www.ams.org/journals. The 2013 subscription begins with volume 221 and consists of six mailings, each containing one or more numbers. Subscription prices are as follows: for paper delivery, US$795 list, US$636 institutional member; for electronic delivery, US$700 list, US$560 institutionalmember. 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Permission is granted to quote brief passages from this publication in reviews,providedthecustomaryacknowledgmentofthesourceisgiven. Republication,systematiccopying,ormultiplereproductionofanymaterialinthispublication is permitted only under license from the American Mathematical Society. Requests for such permissionshouldbeaddressedtotheAcquisitionsDepartment,AmericanMathematicalSociety, 201 Charles Street, Providence, Rhode Island 02904-2294 USA. Requests can also be made by [email protected]. MemoirsoftheAmericanMathematicalSociety (ISSN0065-9266(print);1947-6221(online)) ispublishedbimonthly(eachvolumeconsistingusuallyofmorethanonenumber)bytheAmerican MathematicalSocietyat201CharlesStreet,Providence,RI02904-2294USA.Periodicalspostage paid at Providence, RI.Postmaster: Send address changes to Memoirs, AmericanMathematical Society,201CharlesStreet,Providence,RI02904-2294USA. (cid:2)c 2013bytheAmericanMathematicalSociety. Allrightsreserved. Copyrightofindividualarticlesmayreverttothepublicdomain28years afterpublication. ContacttheAMSforcopyrightstatusofindividualarticles. (cid:2) ThispublicationisindexedinMathematicalReviewsR,Zentralblatt MATH,ScienceCitation Index(cid:2)R,ScienceCitation IndexTM-Expanded,ISI Alerting ServicesSM,SciSearch(cid:2)R,Research (cid:2) (cid:2) (cid:2) AlertR,CompuMathCitation IndexR,Current ContentsR/Physical, Chemical& Earth Sciences. ThispublicationisarchivedinPortico andCLOCKSS. PrintedintheUnitedStatesofAmerica. (cid:2)∞ Thepaperusedinthisbookisacid-freeandfallswithintheguidelines establishedtoensurepermanenceanddurability. VisittheAMShomepageathttp://www.ams.org/ 10987654321 181716151413 Contents Chapter 1. Introduction 1 Chapter 2. Generalities on the algebraic fundamental group, torsors, and reductive group schemes 5 2.1. The fundamental group 5 2.2. Torsors 7 2.3. An example: Laurent polynomials in characteristic 0 8 2.4. Reductive group schemes: Irreducibility and isotropy 11 Chapter 3. Loop, finite and toral torsors 13 3.1. Loop torsors 13 3.2. Loop reductive groups 14 3.3. Loop torsors at a rational base point 15 3.4. Finite torsors 17 3.5. Toral torsors 18 Chapter 4. Semilinear considerations 21 4.1. Semilinear morphisms 21 4.2. Semilinear morphisms 22 4.3. Case of affine schemes 23 4.4. Group functors 24 4.5. Semilinear version of a theorem of Borel-Mostow 27 4.6. Existence of maximal tori in loop groups 29 4.7. Variations of a result of Sansuc 31 Chapter 5. Maximal tori of group schemes over the punctured line 35 5.1. Twin buildings 36 5.2. Proof of Theorem 5.1 37 Chapter 6. Internal characterization of loop torsors and applications 41 6.1. Internal characterization of loop torsors 41 6.2. Applications to (algebraic) Laurent series 45 Chapter 7. Isotropy of loop torsors 47 7.1. Fixed point statements 47 7.2. Case of flag varieties 49 7.3. Anisotropic loop torsors 52 Chapter 8. Acyclicity 57 8.1. The proof 57 8.2. Application: Witt-Tits decomposition 59 iii iv CONTENTS 8.3. Classification of semisimple k–loop adjoint groups 59 8.4. Action of GL (Z) 61 n Chapter 9. Small dimensions 71 9.1. The one-dimensional case 71 9.2. The two-dimensional case 71 Chapter 10. The case of orthogonal groups 83 Chapter 11. Groups of type G 85 2 Chapter12. Case ofgroups of typeF ,E andsimply connectedE innullity 4 8 7 3 87 Chapter 13. The case of PGL 91 d 13.1. Loop Azumaya algebras 91 13.2. The one-dimensional case 92 13.3. The geometric case 95 13.4. Loop algebras of inner type A 98 Chapter 14. Invariants attached to EALAs and multiloop algebras 99 Chapter 15. Appendix 1: Pseudo-parabolic subgroup schemes 101 15.1. The case of GLn,Z 102 15.2. The general case 104 Chapter 16. Appendix 2: Global automorphisms of G–torsors over the projective line 107 Bibliography 109 Abstract We give a detailed description of the torsors that correspond to multiloop algebras. These algebras are twisted forms of simple Lie algebras extended over Laurentpolynomialrings. TheyplayacrucialroleintheconstructionofExtended Affine Lie Algebras (which are higher nullity analogues of the affine Kac-Moody Lie algebras). The torsor approach that we take draws heavily for the theory of reductive group schemes developed by M. Demazure and A. Grothendieck. It also allows us to find a bridge between multiloop algebras and the work of F. Bruhat and J. Tits on reductive groups over complete local fields. ReceivedbytheeditorJuly3,2011,and,inrevisedform,February21,2012. ArticleelectronicallypublishedonMay23,2013;S0065-9266(2013)00679-X. 2010 MathematicsSubjectClassification. Primary17B67,11E72,14L30,14E20. Key words and phrases. Reductivegroupscheme,torsor,multiloopalgebra,extendedaffine Liealgebras. A.PianzolawishestothankNSERCandCONICETfortheircontinuoussupport. Affiliations at time of publication: Philippe Gille, UMR 8553 du CNRS, Ecole Normale Sup´erieure,45rued’Ulm,75005Paris,France,email: [email protected];andArturoPianzola,Depart- ment of Mathematical Sciences, University of Alberta, Edmonton, Alberta T6G 2G1, Canada; and Centro de Altos Estudios en Ciencia Exactas, Avenida de Mayo 866, (1084) Buenos Aires, Argentina,email: [email protected]. (cid:2)c2013 American Mathematical Society v CHAPTER 1 Introduction To our good friend Benedictus Margaux Many interesting infinite dimensional Lie algebras can be thought as being “finite dimensional” when viewed, not as algebras over the given base field, but rather as algebras over their centroids. From this point of view, the algebras in question look like “twisted forms” of simpler objects with which one is familiar. The quintessential example of this type of behaviour is given by the affine Kac- Moody Lie algebras. Indeed the algebras that we are most interested in, Extended AffineLieAlgebras(orEALAsforshort),canroughlybethoughtofashighernullity analogues of the affine Kac-Moody Lie algebras. Once the twisted form point of view is taken the theory of reductive group schemes developed by Demazure and Grothendieck [SGA3] arises naturally. Two key concepts which are common to[GP2] and the present work are those of a twisted form of an algebra, and of a multiloop algebra. At this point we briefly recall what these objects are, not only for future reference, but also to help us redact a more comprehensive Introduction. *** Unless specific mention to the contrary throughout this paper k will denote a field of characteristic 0, and k a fixed algebraic closure of k. We denote k–alg the category of associative unital commutative k–algebras, and R object of k–alg. Let n ≥ 0 and m > 0 be integers that we assume are fixed in our discussion. Consider the Laurent polynomial rings R=R =k[t±1,...,t±1] and R(cid:3) =R = n 1 n n,m k[t±1 m1 ,...,t±nm1 ]. For convenience we also consider the direct limit R∞(cid:3) =−li→mRn,m taken over m which in practice will allow us to “see” all the R at the same n,m time. The natural map R → R(cid:3) is not only faithfully flat but also ´etale. If k is algebraically closed this extension is Galois and plays a crucial role in the study of multiloop algebras. The explicit description of Gal(R(cid:3)/R) is given below. LetAbeak–algebra. Weareingeneralinterestedinunderstandingforms(for the fppf-topology) of the algebra A⊗ R, namely algebras L over R such that k (1.1) L⊗ S (cid:6)A⊗ S (cid:6)(A⊗ R)⊗ S R k k R for some faithfully flat and finitely presented extension S/R. The case which is of most interest to us is when S can be taken to be a Galois extension R(cid:3) of R of Laurent polynomial algebras described above.1 GivenaformLasaboveforwhich(1.1)holds,wesaythatListrivializedbyS. TheR–isomorphismclassesofsuchalgebrascanbecomputedbymeansofcocycles, 1TheIsotrivialityTheoremof[GP1]and[GP3]showsthatthisassumptionissuperflousif Aut(A)isaanalgebraick–groupwhoseconnectedcomponentisreductive,forexampleifAisa finitedimensionalsimpleLiealgebra. 1 2 1. INTRODUCTION just as one does in Galois cohomology: (cid:2) (cid:3) (1.2) Isomorphism classes ofS/R–forms ofA⊗ R←→H1 S/R,Aut(A) . k fppf The right hand side is the part “trivialized by S” of the pointed set of non- abelian cohomology on the flat site of Spec(R) with coefficients in the sheaf of groups(cid:2) Aut(A). In(cid:3)the case when S is Galois over R we can inde(cid:2)ed identify H1 S/R,Aut(A) with the “usual” Galois cohomology set H1 Gal(S/R), fppf (cid:3) Aut(A)(S) as in [Se]. Assume now that k is algebraically closed and fix a compatible set of primi- tive m–th roots of unity ξ , namely such that ξe = ξ for all e > 0. We can m me m then identify Gal(R(cid:3)/R) with (Z/mZ)n where for each e = (e ,...,e ) ∈ Zn the 1 n corresponding element e=(e1,··· ,en)∈Gal(R(cid:3)/R) acts on R(cid:3) via etim1 =ξmeitim1 . The primary example of forms L of A⊗ R which are trivialized by a Galois k extension R(cid:3)/R as above are the multiloop algebras based on A. These are defined asfollows. Considerann–tupleσσσ =(σ ,...,σ )ofcommutingelementsofAut (A) 1 n k satisfying σm =1. For each n–tuple (i ,...,i )∈Zn we consider the simultaneous i 1 n (cid:4) eigenspace(cid:5)Ai1...in ={x∈A:σj(x)=ξmijx for all 1≤j ≤n}.ThenA= Ai1...in, and A = A if we restrict the sum to those n–tuples (i ,...,i ) for which i1...in 1 n 0≤i <m . j j The multiloop algebra corresponding to σσσ, commonly denoted by L(A,σσσ), is defined by L(A,σσσ)=(i1,...,⊕in)∈ZnAi1...in ⊗tim1 ...tnimn ⊂A⊗kR(cid:3) ⊂A⊗kR∞(cid:3) NotethatL(A,σσσ),whichdoesnotdependonthechoiceofcommonperiodm,isnot onlyak–algebra(ingeneralinfinite-dimensional), butalsonaturallyanR–algebra. ItiswhenL(A,σσσ)isviewedasanR–algebrathatGaloiscohomologyandthetheory of torsors enter into the picture. Indeed a rather simple calculation shows that L(A,σσσ)⊗ R(cid:3) (cid:6)A⊗ R(cid:3) (cid:6)(A⊗ R)⊗ R(cid:3). R k k R Thus L(A,σσσ) corresponds to a torsor over Spec(R) under Aut(A). When n = 1 multiloop algebras are called simply loop algebras. To illustrate our methods, let us look at the case of (twisted) loop algebras as they appear in the theory of affine Kac-Moody Lie algebras. Here n = 1, k = C and A = g is a finite-dimensional simple Lie algebra. Any such L is naturally a Lie algebra over R:=C[t±1] and L⊗RS (cid:6)g⊗CS (cid:6)(g⊗CR)⊗RS for some (unique) g, and some finite´etaleextensionS/R.Inparticular,LisanS/R–formoftheR–algebrag⊗CR, withrespect tothe´etale topology of Spec(R). Thus L corresponds toatorsor over Spec(cid:2)(R) under(cid:3)Aut(g) whose isomorphism class is an element of the pointed set H1´et R,Aut(g) . We may in fact take S to be R(cid:3) =C[t±m1 ]. Assume that A is a finite-dimensional. The crucial point in the classification of forms of A⊗ R by cohomological methods is the exact sequence of pointed sets k (cid:2) (cid:3) (cid:2) (cid:3) (cid:2) (cid:3) (1.3) H1 R,Aut0(A) →H1 R,Aut(A) −ψ→H1 R,Out(A) , e´t e´t e´t where Out(A) is the (finite constant) group of connected components of the alge- braic k–group Aut(A).2 2StrictlyspeakingweshouldbeusingtheaffineR–groupschemeAut(A⊗kR)insteadofthe algebraic k–group Aut(A). This harmless and useful abuse of notation will be used throughout thepaper. PHILIPPEGILLEandARTUROPIANZOLA 3 Grot(cid:2)hendieck’s (cid:3)theory of the algebraic fundamental group allows us to iden- tify H1 R,Out(A) with the set of conjugacy classes of n–tuples of commuting e´t elements of the corresponding finite (abstract) group Out(A) (again under the as- sumptionthatk isalgebraicallyclosed). Thisisanimportantcohomologicalinvari- ant attached to any twisted form of A⊗ R. We point out that the cohomological k information is always about the twisted forms viewed as algebras over R (and not k). In practice, as the affine Kac-Moody case illustrates, one is interested in un- derstanding these algebras as objects over k (and not R). A technical tool (the centroid trick) developed and used in [ABP2] and [GP2] allows us to compare k vs R information. We begin by looking at the nullity n=1 case. The map ψ of (1.3) is injective [P1]. This fundamental fact follows from a general result about the vanishing of H1 for reductive group schemes over certain Dedekind rings which includes k[t±1]. This result can be thought of as an analogue of “Serre Conjecture I” for some very special rings of dimension 1. It follows from what has been said that we can attach a conjugacy class of the finite group Out(A) that characterizes L up to R–isomorphism. In particular, if Aut(A) is connected, then all forms (and consequently, all twisted loop algebras) of A are trivial, i.e. isomorphic to A⊗ R k as R–algebras. This yields the classification of the affine Kac-Moody Lie algebras bypurelycohomologicalmethods. Onecaninfactdefinetheaffinealgebrasbysuch methods (which is a completely different approach than the classical definition by generators and relations). Surprisingly enough the analogue of “Serre Conjecture II” for k[t±1,t±1] fails, 1 2 asexplainedin[GP2]. Thesingle familyofcounterexamplesknownarethetheso- calledMargauxalgebras. Theclassificationofformsinnullity2caseisinfactquite interestingandchallenging. Unlikethenullityonecasethereareformswhicharenot multiloop algebras (the Margaux algebra is one such example). The classification in nullity 2 by cohomological methods, both over R and over k, will be given in §9 as an application of one of our main results (the Acyclicity Theorem). This classification(overkbutnotoverR)canalsobeattainedentirelybyEALAmethods [ABP3]. The twoapproaches complement each other and are the culmination of a projectstartedadecadeago. WealsoprovideclassificationresultsforloopAzumaya algebras in §13. Questions related to the classification and characterization of EALAs in ar- bitrary nullity are at the heart of our work. In this situation A = g is a finite dimensional simple Lie algebraover k. The twistedforms relevantto EALAtheory are always multiloop algebras based on g [ABF(cid:2)P]. It is th(cid:3)erefore desirable to try to characterize and understand the part of H1 R,Aut(g) corresponding to mul- e´t tiloop algebras. We address this problem by introducing the concept of loop and toral torsors (with k not necessarily algebraically closed). These concepts are key ideaswithinourwork. ItiseasytoshowusingatheoremofBorelandMostowthat a multiloop algebra based on g, viewed as a Lie algebra over R , always admits a n Cartan subalgebra (in the sense of [SGA3]). We establish that the converse also holds. Central to our work is the study of the canonical map (cid:2) (cid:3) (cid:2) (cid:3) (1.4) H1 R ,Aut(g) →H1 F ,Aut(g) e´t n e´t n where F stands for the iterated Laurent series field k((t ))...((t )). The Acyclic- n 1 n ity Theorem proved in §8 shows that the restriction of the canonical map (1.4)

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The authors give a detailed description of the torsors that correspond to multiloop algebras. These algebras are twisted forms of simple Lie algebras extended over Laurent polynomial rings. They play a crucial role in the construction of Extended Affine Lie Algebras (which are higher nullity analogu
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