On Noncrossing and Nonnesting Partitions of Type D

Abstract: Abstract. We present an explicit bijection between noncrossing and nonnesting partitions of Coxeter systems of type D which preserves openers, closers and transients. OverviewThe lattice of set partitions of a set of n elements can be interpreted as the intersection lattice for the hyperplane arragement corresponding to a root system of type A n−1 , i.e. the symmetric group of n objects, S n . In particular, two of its subposets are very wellbehaved and widely studied, i.e. the lattice of, respectively, noncro… Show more

“…[2,12,13,43], so it is quite natural to ask for a generalization of our results to Weyl groups of type B and D.…”

“…There are several bijections between noncrossing and nonnesting set partitions (see, for example [2,13,17,29,45]), and since in [19] a Gray code for noncrossing partitions is presented, it is tempting to try employing these bijections in order to obtain a Gray code for nonnesting partitions. But, as referred in [48], a Gray code for a combinatorial class is intrinsically bound to the representation of objects in the class, and in the present case, the Gray code is not preserved under bijection.…”

“…In particular, there exist several bijections between noncrossing and nonnesting partitions, see e.g. [12,13,17,23,29,45], so it is very natural to wonder if all results which hold for noncrossing partitions hold for nonnesting partitions as well. Unfortunately, nonnesting partitions are much more mysterious and intricate, and plenty of results valid for noncrossing partitions do not translate to nonnesting partitions.…”

“…[1,2,[11][12][13]17,23,29,30,34,43,45,49], and among other things they have applications to the theory of free probability, see [37,51,52]. In particular, there exist several bijections between noncrossing and nonnesting partitions, see e.g.…”

Gray codes and lexicographical combinatorial generation for nonnesting and sparse nonnesting set partitions

“…[2,12,13,43], so it is quite natural to ask for a generalization of our results to Weyl groups of type B and D.…”

“…There are several bijections between noncrossing and nonnesting set partitions (see, for example [2,13,17,29,45]), and since in [19] a Gray code for noncrossing partitions is presented, it is tempting to try employing these bijections in order to obtain a Gray code for nonnesting partitions. But, as referred in [48], a Gray code for a combinatorial class is intrinsically bound to the representation of objects in the class, and in the present case, the Gray code is not preserved under bijection.…”

“…In particular, there exist several bijections between noncrossing and nonnesting partitions, see e.g. [12,13,17,23,29,45], so it is very natural to wonder if all results which hold for noncrossing partitions hold for nonnesting partitions as well. Unfortunately, nonnesting partitions are much more mysterious and intricate, and plenty of results valid for noncrossing partitions do not translate to nonnesting partitions.…”

“…[1,2,[11][12][13]17,23,29,30,34,43,45,49], and among other things they have applications to the theory of free probability, see [37,51,52]. In particular, there exist several bijections between noncrossing and nonnesting partitions, see e.g.…”

Gray codes and lexicographical combinatorial generation for nonnesting and sparse nonnesting set partitions

“…In fact, they showed that their bijections are the unique ones preserving those statistics. There are other bijections between noncrossing and nonnesting partitions of classical types due to Rubey and Stump [18] for type B and Conflitti and Mamede [8] for type D. However their bijections preserve not the types but 'openers' and 'closers'.…”

New interpretations for noncrossing partitions of classical types

Charmed roots and the Kroweras complement