Combinatorial Applications of M¨Obius Inversion 1

PROCEEDINGS OF THE AMERICAN MATHEMATICAL SOCIETY Volume 00, Number 0, Pages 000–000 S 0002-9939(XX)0000-0

COMBINATORIAL APPLICATIONS OF MOBIUS¨ INVERSION

MARIE JAMESON AND ROBERT P. SCHNEIDER

(Communicated by Matthew Papanikolas)

Abstract. In important work on the parity of the partition function, Ono [5] related values of the partition function to coeﬃcients of a certain mock theta function modulo 2. In this paper, we use M¨obiusinversion to give analogous results which relate several combinatorial functions via identities rather than congruences.

1. Introduction and Statement of Results Infinite products are ubiquitous in number theory and the theory of q-series. For example, recall Euler’s identity ∞ ∞ Y X (1 − qn) = (−1)kqk(3k−1)/2, n=1 k=−∞ and Jacobi’s identity ∞ ∞ Y X (1 − qn)3 = (−1)n(2n + 1)qn(n+1)/2. n=1 n=0 More recently, Borcherds defined “infinite product modular forms” ∞ Y F (z) = qh (1 − qn)a(n), n=1 where q := e2πiz and the a(n)’s are coefficients of certain weight 1/2 modular forms (see Chapter 4 of [5]). This was generalized by Bruinier and Ono in [3]. At first glance, this does not look like the stuff of combinatorics. However, one might consider the partition function p(n) and ask whether the product ∞ Y (1.1) (1 − qn)p(n) n=1 has any special properties. In this direction, recent work of Ono [5] studies the parity of p(n). For 1 < D ≡ 23 (mod 24), Ono defined ∞ −D C(m;Dm2) Y Y −b m( b ) ΨD(q) := 1 − ζD q , m=1 0≤b≤D−1

2010 Mathematics Subject Classiﬁcation. Primary 11A25, 11P84, 05A17.

c XXXX American Mathematical Society 1 2 MARIE JAMESON AND ROBERT P. SCHNEIDER

2πi/D 2 where m is the reduction of m (mod 12), ζD := e , and C(m; Dm ) is the coeﬃcient of a mock theta function. It turns out that ( p n+1 (mod 2) if m ≡ 1, 5, 7, 11 (mod 12) C(m; n) ≡ 24 . 0 otherwise Ono considers the logarithmic derivative ∞ d ∞ ∞ X 1 q dq ΨD(q) X X −D (1.2) B (n)qn := √ · = mC(m; Dm2) qmn D Ψ (q) n n=1 −D D m=1 n=1 and notes that reducing mod 2 gives

d 2 1 q dq ΨD(q) X Dm + 1 X (1.3) √ · ≡ p qmn (mod 2). −D ΨD(q) 24 m≥1 n≥1 gcd(m,6)=1 gcd(n,D)=1 This observation was instrumental in proving strong results regarding the parity of the partition function [5]. However, in this work we desire to establish identities rather than congruences, so it seems pertinent to again consider products of the form (1.1), but now at the level of q-series identities. From this perspective, we wish to explore the logarithmic derivative of ∞ Y (1.4) (1 − qn)a(n) n=1 for other, more general combinatorial functions a(n). Then for a nonnegative integer n, deﬁne Q(n) := #of partitions of n into distinct parts Qb(n) := # of partitions of n whose parts occur with the same multiplicity and ∞ X n FQ(q) := Q(n)q n=1 ∞ X F (q) := Q(n)qn Qb b n=1 ∞ Y Ψ(Q; q) := (1 − qn)Q(n)/n. n=1 Theorem 1.1. We have that q d Ψ(Q; q) dq = −F (q). Ψ(Q; q) Qb Moreover, for all n ≥ 1 we have X Q(n) = µ(d)Qb(n/d), d|n where µ denotes the M¨obius function. COMBINATORIAL APPLICATIONS OF MOBIUS¨ INVERSION 3

For example, one can compute that 1 1 1 43 233 Ψ(Q; q) = 1 − q − q3 − q3 + q4 + q5 − q6 + ··· 2 6 24 120 720 q d Ψ(Q; q) dq = −q − 2q2 − 3q3 − 4q4 − 4q5 − 8q6 − · · · Ψ(Q; q) q d Ψ(Q; q) F (q) = q + 2q2 + 3q3 + 4q4 + 4q5 + 8q6 + ··· = − dq . Qb Ψ(Q; q) In fact, while it is not obvious from a combinatorial perspective, this theorem is simple; it follows from the straightforward observation that X Qb(n) = Q(d). d|n Now we present two results in a slightly different direction that are perhaps more surprising. Looking again to the work of Ono [5], we can apply Möbius inversion to (1.2) to find 1 X −D (1.5) C(n; Dn2) = µ(d) B (n/d). n d D d|n It is natural to ask whether there are analogs of this statement for related q-series, even if the series do not arise as logarithmic derivatives of Borcherds products. We begin our search of interesting combinatorial functions by noting that the generating function for the partition function p(n) obeys the identity of Euler

∞ ∞ 2 X X qn P (q) := p(n)qn = (q)2 n=0 n=0 n Qn k where (q)n is the Pochhammer symbol, deﬁned by (q)0 = 1 and (q)n = k=1(1−q ) for n ≥ 1. We wish to investigate other functions of a similar form, such as those presented in the following theorems, which are formally analogous to (1.5) but involving other combinatorial functions. Let pa(n) denote the number of partitions of n into a parts, and deﬁne pba(n) to be the number of partitions of n into parts the numbers of which are divisible by a, i.e. ∞ X pba(n) := paj(n). j=1

On analogy to the identities for P (q) above, we let Pa(q) and Pba(q) denote the generating functions of pa(n) and pba(n), respectively. Then we have the following identities for Pa(q) and Pba(q). Theorem 1.2. We have that ∞ X Pa(q) = µ(n)Pdan(q) n=1 ∞ X pa(n) = µ(j)pcaj(n). j=1 4 MARIE JAMESON AND ROBERT P. SCHNEIDER

Observe that for a = 1, we have that p1(n) = 1 for all integers n, and also that ∞ X pb1(n) = pj(n) = p(n). j=1 In this case, the generating functions are given by ∞ ∞ X X q P (q) = p (n)qn = qn = 1 1 1 − q n=1 n=1 and ∞ ∞ X n X n Pc1(q) = pb1(n)q = p(n)q . n=1 n=1 Thus by Theorem 1.2, we have the explicit identities ∞ X q P1(q) = µ(n)Pcn(q) = 1 − q n=1 and, perhaps more interestingly, ∞ X p1(n) = µ(j)pbj(n) = 1. j=1 Looking again for identities similar to those given above for P (q), for a positive integer a set

∞ 2 ∞ X qn +an X B (q) := =: b (N)qN a (q)2 a n=1 n N=1 ∞ n2+an ∞ X q X N Bba(q) := =: ba(N)q . (q)2 (1 − qan) n=1 n N=1

Generalizations of q-series such as Ba(q) and Bba(q) have been studied by An- drews [1]. One can give a combinatorial interpretation for the coeﬃcients ba(N) and ba(N) as follows. Consider the Ferrers diagram of a given partition of an integer N with an n × n Durfee square, and having a rectangle of base n and height m adjoined immediately below the n × n Durfee square. For example, the partition of N = 12 shown below has a 2 × 2 Durfee square (marked by a solid line), and either a 2 × 2 or 2 × 1 rectangle below it (the 2 × 1 rectangle is marked by a dashed line). COMBINATORIAL APPLICATIONS OF MOBIUS¨ INVERSION 5

We refer to this rectangular region of the diagram as an n × m “Durfee rectangle,” and note that a given Ferrers diagram may have nested Durfee rectangles of sizes n×1, n×2, . . . , n×M, where M is the height of the largest such rectangle (assuming that at least one Durfee rectangle is present in the diagram). We then have that ba(N) =# of partitions of N having an n × n Durfee square and at least an n × a Durfee rectangle bba(N) =# of partitions of N having an n × n Durfee square and at least an n × a Durfee rectangle (counted with multiplicity as an n × a rectangle may be nested within taller Durfee rectangles of size n × ak, for k ≥ 1). Assuming these notations, we have the following result. Theorem 1.3. We have that ∞ X bba(n) = baj(n). j=1 Moreover, we have ∞ X Ba(q) = µ(n)Bdan(q) n=1 ∞ X ba(n) = µ(j)bcaj(n). j=1

2. Proof of Theorem 1.1 First we prove a lemma regarding logarithmic derivatives. Lemma 2.1. For any sequence {a(n)}, we have that d Q∞ n a(n) ∞ q dq n=1(1 − q ) X X = − a(d)dqn. Q∞ (1 − qn)a(n) n=1 n=1 d|n

P∞ xm Proof. Since log(1 − x) = − m=1 m , we have that d Q∞ n a(n) ∞ !! ∞ ! q dq n=1(1 − q ) d Y d X = q log (1 − qn)a(n) = q a(n) log (1 − qn) Q∞ (1 − qn)a(n) dq dq n=1 n=1 n=1 ∞ ∞ ! ∞ ∞ ! d X X qmn X X = −q a(n) = − a(n) nqmn dq m n=1 m=1 n=1 m=1 ∞ X X = − a(d)dqn n=1 d|n as desired. Proof of Theorem 1.1. First note that for all n ≥ 1 we have X Qb(n) = Q(d), d|n 6 MARIE JAMESON AND ROBERT P. SCHNEIDER

P so Q(n) = d|n µ(d)Qb(n/d) by M¨obiusinversion. By Lemma 2.1, we have that d ∞ ∞ q dq Ψ(Q; q) X X X = − Q(d)qn = − Qb(n)qn Ψ(Q; q) n=1 d|n n=1 as desired. 3. Proof of Theorems 1.2 and 1.3 Suppose that for each positive integer a, we have two arithmetic functions f(a; n) and fb(a; n) such that ∞ X fb(a; n) = f(aj; n), j=1 where the above sum converges absolutely. We will deﬁne their generating functions as follows. ∞ X F (a; q) := f(a; n)qn n=1 ∞ X Fb(a; q) := fb(a; n)qn. n=1 We then have the following result. Lemma 3.1. We have that ∞ X F (a; q) = µ(n)Fb(an; q) n=1 and ∞ X f(a; n) = µ(j)fb(aj; n). j=1 Proof. Recall that ( X 1 if n = 1 µ(n) = . 0 otherwise d|n It follows that ∞   X X k X F (a; q) =  f(an; k)q  µ(d) n=1 k≥1 d|n

∞  ∞  X X X k = µ(n)  f(anj; k) q n=1 k≥1 j=1 ∞ X X = µ(n) fb(an; n)qk n=1 k≥1 ∞ X = µ(n)Fb(an; q). n=1 P∞ Then by comparing coeﬃcients, one ﬁnds that f(a; n) = j=1 fb(aj; n), as desired. COMBINATORIAL APPLICATIONS OF MOBIUS¨ INVERSION 7

This lemma can be used to prove both Theorem 1.2 and Theorem 1.3. We note that Lemma 3.1 can be applied in extremely general settings, and one has great freedom in creatively choosing the constant a to be varied. For instance, taking a = 1 gives rise to any number of identities, as 1 can be inserted as a factor practically anywhere in a given expression. Proof of Theorem 1.2. The theorem follows by a direct application of Lemma 3.1. Proof of Theorem 1.3. First note that ∞ X ba(N) = baj(N), j=1 since ∞ n2+an ∞ n2+an ∞ X q X q X ajn Bba(q) = = q (q)2 (1 − qan) (q)2 n=1 n n=1 n j=0 ∞ ∞ 2 ∞ X X qn +ajn X = = B (q). (q)2 aj j=1 n=1 n j=1 The rest follows by applying Lemma 3.1. Acknowledgements The authors thank Ken Ono and Robert Lemke Oliver for their useful comments and insights.

References 1. George E. Andrews. Concave compositions. Electron. J. Combin., 18(2):Paper 6, 13, 2011. 2. Tom M. Apostol. Introduction to analytic number theory. Springer-Verlag, New York, 1976. Undergraduate Texts in Mathematics. 3. Jan H. Bruinier and Ken Ono. The arithmetic of Borcherds’ exponents. Math. Ann., 327(2):293– 303, 2003. 4. Ken Ono. The web of modularity: arithmetic of the coeﬃcients of modular forms and q-series, volume 102 of CBMS Regional Conference Series in Mathematics. Published for the Conference Board of the Mathematical Sciences, Washington, DC, 2004. 5. Ken Ono. Parity of the partition function. Adv. Math., 225(1):349–366, 2010.

Department of Mathematics and Computer Science, Emory University, Atlanta, Geor- gia 30322 E-mail address: [email protected]