MEMOIRS of the American Mathematical Society Number 949 Generalized Noncrossing Partitions and Combinatorics of Coxeter Groups Drew Armstrong November 2009 • Volume 202 • Number 949 (third of 5 numbers) • ISSN 0065-9266 American Mathematical Society Number 949 Generalized Noncrossing Partitions and Combinatorics of Coxeter Groups Drew Armstrong November2009 • Volume202 • Number949(thirdof5numbers) • ISSN0065-9266 2000MathematicsSubjectClassification. Primary05E15,05E25,05A18. Library of Congress Cataloging-in-Publication Data Armstrong,Drew,1979- Generalizednoncrossingpartitionsandcombinatoricsofcoxetergroups/DrewArmstrong. p.cm. —(MemoirsoftheAmericanMathematicalSociety,ISSN0065-9266;no. 949) Revisionoftheauthor’sthesis(Ph.D.)–CornellUniversity,2006. “Volume202,number949(thirdof5numbers).” Includesbibliographicalreferences. ISBN978-0-8218-4490-8(alk.paper) 1.Combinatorialenumerationproblems. 2.Combinatorialanalysis. 3.Groupactions(Math- ematics). I.Title. 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VisittheAMShomepageathttp://www.ams.org/ 10987654321 141312111009 For Moira Contents Acknowledgements ix Chapter 1. Introduction 1 1.1. Coxeter-Catalan combinatorics 1 1.2. Noncrossing motivation 6 1.3. Outline of the memoir 9 Chapter 2. Coxeter Groups and Noncrossing Partitions 13 2.1. Coxeter systems 13 2.2. Root systems 16 2.3. Reduced words and weak order 19 2.4. Absolute order 22 2.5. Shifting and local self-duality 26 2.6. Coxeter elements and noncrossing partitions 29 2.7. Invariant theory and Catalan numbers 35 Chapter 3. k-Divisible Noncrossing Partitions 41 3.1. Minimal factorizations 41 3.2. Multichains and delta sequences 42 3.3. Definition of k-divisible noncrossing partitions 46 3.4. Basic properties of k-divisible noncrossing partitions 48 3.5. Fuss-Catalan and Fuss-Narayana numbers 59 3.6. The iterated construction and chain enumeration 66 3.7. Shellability and Euler characteristics 72 Chapter 4. The Classical Types 81 4.1. Classical noncrossing partitions 81 4.2. The classical Kreweras complement 87 4.3. Classical k-divisible noncrossing partitions 92 4.4. Type A 102 4.5. Type B 104 4.6. Type D 111 Chapter 5. Fuss-Catalan Combinatorics 115 5.1. Nonnesting partitions 115 5.2. Cluster complexes 128 5.3. Chapoton triangles 143 5.4. Future directions 147 Bibliography 155 v Abstract This memoir is a refinement of the author’s PhD thesis — written at Cornell University (2006). It is primarily a desription of new research but we have also included asubstantial amount of background material. Atthe heart of thememoir we introduce and study a poset NC(k)(W) for each finite Coxeter group W and each positive integer k. When k =1, our definition coincides with the generalized noncrossingpartitionsintroducedbyBradyandWattinK(π,1)’s for Artin groups offinitetypeandBessisinThedualbraidmonoid. WhenW isthesymmetricgroup, we obtain the poset of classical k-divisible noncrossing partitions, first studied by Edelman in Chain enumeration and non-crossing partitions. Ingeneral,weshowthatNC(k)(W)isagradedjoin-semilatticewhoseelements are counted by a generalized “Fuss-Catalan number” Cat(k)(W) which has a nice closed formula in terms of the degrees of basic invariants of W. We show that this poset is locally self-dual and we also compute the number of multichains in NC(k)(W), encoded by the zeta polynomial. We show that the order complex of the poset is shellable (hence Cohen-Macaulay) and we compute its homotopy type. Finally, we show that the rank numbers of NC(k)(W) are polynomials in k with nonzero rational coefficients alternating in sign. This defines a new family of polynomials (called “Fuss-Narayana”) associated to the pair (W,k). We observe some interesting properties of these polynomials. In the case that W is a classical Coxeter group of type A or B, we show that NC(k)(W) is isomorphic to a poset of “noncrossing” set partitions in which each blockhassizedivisiblebyk. Thismotivatesourgeneraluseoftheterm“k-divisible noncrossingpartitions”fortheposetNC(k)(W). IntypesAandB weprove“rank- selection”and“type-selection”formulas refining the enumeration ofmultichains in NC(k)(W). Wealsodescribebijectionsrelatingmultichainsofclassicalnoncrossing partitions to “k-divisible” and “k-equal” noncrossing partitions. Our main tool is the family of Kreweras complement maps. Along the way we include a comprehensive introduction to related background material. Before defining our generalization NC(k)(W), we develop from scratch ReceivedbytheeditorDecember8,2006;andinrevisedformOctober18,2007. ArticleelectronicallypublishedonJuly22,2009;S0065-9266(09)00565-1. 2000 MathematicsSubjectClassification. Primary05E15,05E25,05A18. Key words and phrases. Noncrossing partition, Coxeter group, Coxeter element, Catalan number,Fuss-Catalannumber,nonnestingpartition,clustercomplex. ThisworkwassupportedinpartbyNSFgrantDMS-0603567. (cid:1)c2009 American Mathematical Society vii viii ABSTRACT thetheoryofthegeneralizednoncrossingpartitionsNC(1)(W)asdefinedbyBrady and Watt in K(π,1)’s for Artin groups of finite type and Bessis in The dual braid monoid. This involves studying a finite Coxeter group W with respect to its gen- erating set T of all reflections, instead of the usual Coxeter generating set S. This is the first time that this material has appeared together. Finally, it turns out that our poset NC(k)(W) shares many enumerative fea- tures in common with the generalized nonnesting partitions of Athanasiadis in Generalized Catalan numbers, Weyl groups and arrangements of hyperplanes and in On a refinement of the generalized Catalan numbers for Weyl groups; and the generalized cluster complexes of Fomin and Reading in Generalized cluster com- plexes and Coxeter combinatorics. Wegiveabasicintroductiontothesetopicsand wemakeseveralconjecturesrelatingthesethreefamiliesof“Fuss-Catalanobjects”. Acknowledgements This work has taken several years and gone through several phases to arrive in its present form. The following people have contributed along the way; they deserve my sincerest thanks. First, IthankLouBillera, myadvisoratCornellUniversity, underwhoseguid- ance the original draft [2] was written. I thank my wife Heather for her thorough readingofthe manuscript andfor helpful mathematical discussions. Thankstothe anonymous referee for many valuable suggestions. And thanks to Hugh Thomas who made several contributions to my understanding; in particular, he suggested the proof of Theorem 3.7.2. Ihavebenefittedfromvaluableconversationswithmanymathematicians; their suggestionshaveimprovedthismemoirincountlessways. Thanksto: (inalphabet- ical order) Christos Athanasiadis, David Bessis, Tom Brady, Ken Brown, Fr´ed´eric Chapoton, Sergey Fomin, Christian Krattenthaler, Cathy Kriloff, Jon McCam- mond, Nathan Reading, Vic Reiner and Eleni Tzanaki. I would especially like to thank Christian Krattenthaler for his close attention to the manuscript and for his subsequent mathematical contributions [84, 85, 86, 87]. Thank you to the American Institute of Mathematics, Palo Alto, and to the organizers — Jon McCammond, Alexandru Nicaand Vic Reiner — of the January 2005conference[1]atwhichIwasabletomeetmanyoftheabove-namedresearchers for the first time. Thanks also to John Stembridge for the use of his software packages posets and coxeter for Maple [128]. Finally, I thank the people who introduced me to noncrossing partitions. My first research experience was under the supervision of Roland Speicher at Queen’s University. His papers on noncrossing partitions, as well as those of Paul Edel- man and Rodica Simion, inspired me to look further. In particular, I thank Paul Edelman for his encouragement and advice. ix