Abstract
Bloch–Okounkov studied certain functions on partitions f called shifted symmetric polynomials. They showed that certain q-series arising from these functions (the so-called q-brackets \(\left<f\right>_q\)) are quasimodular forms. We revisit a family of such functions, denoted \(Q_k\), and study the p-adic properties of their q-brackets. To do this, we define regularized versions \(Q_k^{(p)}\) for primes p. We also use Jacobi forms to show that the \(\left<Q_k^{(p)}\right>_q\) are quasimodular and find explicit expressions for them in terms of the \(\left<Q_k\right>_q\).
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1 Introduction and statement of results
In [10], Serre introduced the theory of p-adic modular forms, which are p-adic limits of compatible families of q-expansions of classical level one modular forms. The first example of this phenomenon comes from the Eisenstein series
where k is a positive even integer, \(\tau \in \mathbb {H},\) \(q = e^{2 \pi i \tau }\), \(B_k\) is the kth Bernoulli number, \(\sigma _{k - 1}(n)\) is the sum of the \(k - 1\) powers of the divisors of n, and \(\widetilde{M}_k\) is the space of weight k quasimodular forms. For primes \(p \ge 5\), we regularize \(G_k\) to
where
In order to find congruences for these regularized Eisenstein series, we recall Euler’s theorem, which says that if \((a, n) = 1\) then \(a^{\phi (n)} \equiv 1 \pmod {n},\) where
is Euler’s totient function. Together, Euler’s theorem and the Kummer congruences for the Bernoulli numbers give the following: if \( k_1, k_2 \not \equiv 0 \pmod {p - 1}\), then
Since we also have that \(G_{k}^{(p)} \equiv G_k \pmod {p^r}\) whenever \(k > r\), this makes
into a p-adic modular form for \(k \not \equiv 0 \pmod {p - 1}\). Note that if instead \( k \equiv 0 \pmod {p - 1}\), then the constant term is not p-integral, but the normalized Eisenstein series \(E_k(\tau )\) satisfies \( E_k(\tau ) \equiv 1 \pmod {p^r}\) whenever \(k \equiv 0 \pmod {\phi (p^r)}\).
Katz [7] and others have reformulated and expanded this theory to consider p-adic modular forms as p-adic analytic functions on elliptic curves. However, in this paper we will only consider p-adic modular forms in the sense of Serre.
In this article, we wish to examine the p-adic properties of certain quasimodular forms \(\langle Q_k \rangle _q\) and show that they are in many ways analogous to the Eisenstein series \(G_k\) and fit into Serre’s framework.
Let \(\mathcal {P}\) be the set of all integer partitions. For any function \(f: \mathcal {P}\rightarrow \mathbb {Q}\), we define the “q-bracket of f” to be the following formal power series obtained by “averaging”:
where \(|\lambda |\) denotes the size of a partition \(\lambda \) and \(\eta (\tau )\) is Dedekind’s eta-function.
A result Bloch and Okounkov [3] gives that for a large class of functions \(f: \mathcal {P}\rightarrow \mathbb {Q}\), called shifted symmetric polynomials, the q-series \(\left<f\right>_q\) is a quasimodular form on the full modular group. The space of shifted symmetric polynomials is generated by functions \(Q_k\), which we will define explicitly in Sect. 2; the first few are given by
Note that we use the same letter \(Q_k\) to denote both this function and the corresponding generator of the formal polynomial algebra
in infinitely many variables. Then any element
can be considered as a function on partitions by setting
and we can speak of its q-bracket \(\left<f\right>_q\). We give \(\mathcal {R}\) a grading by assigning to \(Q_k\) the weight k. Then the Bloch–Okounkov Theorem states that for \(f \in \mathcal {R}\) homogeneous of grading k, \(\left<f\right>_q\) is a quasimodular form of weight k on the full modular group. In their paper, Bloch and Okounkov also defined so-called n-point correlation functions which are related to \(\left<Q_k\right>_q,\) and gave a formula for them involving derivatives of a theta function. We will use a special case of this result in equation (7) of Sect. 4.
Zagier revisited this work in [11], giving a significantly shorter proof of the Bloch–Okounkov Theorem and studying additional properties of the q-bracket.
In Sect. 2, we will define a normalization \(\mathcal {Q}_k\) of \(\langle Q_k \rangle _q\) and a regularization \(\mathcal {Q}_k^{(p)}\) of \(\mathcal {Q}_k\) at the prime \(p \ge 5\) with the property that
We will show the following about these q-series.
Theorem 1.1
Let \(p \ge 5\) be prime.
-
(a)
If \(k_1, k_2 \not \equiv 0 \pmod {p - 1}\), then \(\mathcal {Q}_{k_1}^{(p)} \equiv \mathcal {Q}_{k_2}^{(p)} \pmod {p^r}\) whenever \(k_1 \equiv k_2 \pmod {\phi (p^r)}.\)
-
(b)
If \(k \not \equiv 0 \pmod {p - 1}\), then \(\mathcal {Q}_{k}^{(p)}\) is a p-adic modular form.
-
(c)
If \(p > k\), then the modulo p filtration of \(\mathcal {Q}_k^{(p)}\) (and \(\mathcal {Q}_k\)) is \(k(p + 1)/2\).
-
(d)
The q-series \(\mathcal {Q}_k^{(p)}\) is a quasimodular form of weight k on \(\Gamma _0(p^2)\).
-
(e)
We have that \(\mathcal {Q}_k^{(p)}(\tau ) = \mathcal {Q}_k(\tau ) - p^{k - 1}\mathcal {Q}_k(p^2 \tau ) - p^{k - 1}f_k^{(p)},\) where \(f_k^{(p)}\) is given explicitly in Sect. 4. In particular, \(f_k^{(p)}\) is supported on \(q^N\) with \(\genfrac(){}{}{2}{p} = \genfrac(){}{}{N}{p}\).
Remark
In [8], Lopez studied the functions \(\left<Q_{3}^{2n}\right>_q\) and showed that they also satisfy parts (a) and (b) of our theorem. It seems likely that other products of the \(Q_k\) yield quasimodular forms which satisfy similar p-adic properties.
Example
Consider the case where \(p = 5\). We have that the normalized q-bracket \(\mathcal {Q}_2\) and its regularization \(\mathcal {Q}_2^{(5)}\) are
Here, we have marked the terms above whose coefficients disagree; in accordance with part (e) of Theorem 1.1, we see that this occurs only when \(\genfrac(){}{}{N}{5} = 0, -1\).
Since \(2 \equiv 22 \pmod {\phi (25)}\), we also give the weight 22 forms, which part (e) guarantees must differ from each other on the same powers of q:
Notice that in accordance with part (a) of Theorem 1.1 and (2), we have that
In Sect. 2, we will explicitly define the functions \(Q_k:\mathcal {P}\rightarrow \mathbb {Q},\) as well as \(\mathcal {Q}_{k}^{(p)}\) and various other functions. In Sect. 3, we will prove parts (a)–(c) of Theorem 1.1. In Sect. 4, we will make a connection to the theory of Jacobi forms in order to prove parts (d) and (e) of Theorem 1.1.
2 Preliminary definitions
2.1 Definitions of \(P_k(\lambda ), Q_k(\lambda )\), and \(\mathcal {Q}_k(\tau )\)
First, we must define the functions \(Q_k:\mathcal {P}\rightarrow \mathbb {Q}\) of Bloch and Okounkov (as described by Zagier in [11]). For a partition \(\lambda \in \mathcal {P},\) we first consider the Frobenius coordinates of \(\lambda \), which are given by
where r is the length of the longest diagonal in the Young diagram of \(\lambda \) (i.e., r is the size of the Durfee square of \(\lambda \)) and \(a_1, \ldots a_r\) (resp., \(b_1, \ldots , b_r\)) are the arm-lengths (resp., leg-lengths) of the cells on this diagonal. For example, the partition \(\lambda = (4, 3, 1)\) has Frobenius coordinates (2; 3, 1; 2, 0) as seen in the Young diagram below.
We then define the set
and for each integer \(k\ge 0,\) define \(P_k(\lambda )\in \mathbb {Z}[\frac{1}{2}]\) by
Finally, we define the \(Q_k(\lambda )\in \mathbb {Q}\) by \(Q_0(\lambda ) := 1\) and for all \(k>0,\)
where \(\beta _k\) is defined by \(\frac{z/2}{\sinh (z/2)} = \sum _{n = 0}^\infty \beta _nz^n\) (or equivalently, \(\beta _k = \frac{-B_k(2^{k-1}-1)}{2^{k-1}k!}\) for all k).
The aforementioned theorem of Bloch and Okounkov [3] implies that the q-bracket (as defined in 1) of \(Q_k\) is a quasimodular form for all non-negative integers k. We will work with
which is normalized so that all of the coefficients of the q-series besides the constant term are integral.
2.2 Definitions of \(P_k^{(p)}(\lambda ), Q_k^{(p)}(\lambda ),\) and \(\mathcal {Q}_k^{(p)}(\tau )\)
For primes \(p\ge 2,\) we follow Serre and define the regularizations
where \(\beta _k^{(p)} := \beta _k(1 - p^{k - 1})\). Analogously to our normalization \(\mathcal {Q}_k\) of \(\left<Q_k\right>_q\), we define
Remark
By matching up conjugate partitions, we can see that \(\mathcal {Q}_k(\tau )\) and \(\mathcal {Q}_k^{(p)}(\tau )\) equal zero for odd k.
3 Congruences and p-adic modular forms
3.1 Congruences
Now we will show that our regularizations \(\mathcal {Q}_k^{(p)}(\tau )\) satisfy congruences analogous to those which are known for the Eisenstein series, proving parts (a) and (b) of Theorem 1.1. We focus on weights k that are not multiples of \(p - 1\), as that is when the constant term of \(\mathcal {Q}_k^{(p)}\) is p-integral. Note that this implies that \(p \ge 5\).
Theorem
(part (a) of Theorem 1.1) Let \(k_1, k_2 \not \equiv 0 \pmod {p - 1}\). Then we have that
whenever \(k_1 \equiv k_2 \pmod {\phi (p^r)}\).
Proof
By Euler’s Theorem, we get that
Since
and
the Kummer congruences imply that
These congruences carry over to
\(\square \)
3.2 p-adic modular forms
Now, we will use these congruence results to show that our regularizations \(\mathcal {Q}_k^{(p)}\) are p-adic modular forms. As before, we focus on weights k that are not multiples of \(p - 1\). First, we define a p-adic modular form.
Definition 1
We say that \(f = \sum a_n q^n \in \mathbb {Q}_p[[q]]\) is a p-adic modular form if there exists \(f_i \in M_{k_i}\) with rational coefficients which converge uniformly to the coefficients of f in \(\mathbb {Q}_p\). In this situation, we write \(f_i \rightarrow f\).
Remark
If \(f_i \rightarrow f\), it can be shown that the weights \(k_i\) converge in the weight space X. For \(p > 2\), we have that
Remark
Every level \(p^n\) modular form is a level 1 p-adic modular form of the same weight. This includes for instance the regularized Eisenstein series \(G_k^{(p)}\) for \(p \ge 5, k \not \equiv 0 \pmod {p - 1}\). In this case, we can see that \(G_{k + \phi (p^i)} \rightarrow G_k^{(p)}\).
Note that since \(E_2, E_4, E_6\) are p-adic modular forms, all quasimodular forms are too. Thus, since we will show that the \(\mathcal {Q}_k^{(p)}\)’s are quasimodular in Sect. 4, we will have that they are p-adic modular forms as well. However, we can also show this using the above congruences, which give them as p-adic limits of the \(\mathcal {Q}_k\)’s.
Theorem
(part (b) of Theorem 1.1) Let \(p \ge 5\) and \(k \not \equiv 0 \pmod {p - 1}\). Then we have that \(\mathcal {Q}_k^{(p)}\) is a p-adic modular form of weight k, with
Proof
For \(i \ge 1\), we have that
and so \(g_i \rightarrow \mathcal {Q}_k^{(p)}\) p-adically. Since the \(g_i\) are quasimodular, they are p-adic modular forms, and hence the \(\mathcal {Q}_k^{(p)}\) are too. \(\square \)
Remark
If \(k \equiv 0 \pmod {p - 1}\), then \(B_k^{(p)}\) is not p-integral and hence we do not get congruences for the constant term of \(\mathcal {Q}_k^{(p)}\). However, just as with the Eisenstein series, we can renormalize so that the constant term is one. Kummer’s congruences for the Bernoulli numbers imply that the resulting functions will also converge p-adically. In the special case \(k=0,\) the result converges p-adically to 1.
3.3 Filtration
In addition to studying p-adic modular forms, we can also study modulo-p modular forms. One of the most important properties of modulo-p modular forms are their filtration. See [10] for more details.
Definition 2
Let \(p \ge 5\). The filtration of \(f \in \mathbb {F}_p[[q]]\) is denoted as w(f) and is defined to be the smallest integer k such that f is the modulo p reduction of a modular form of weight k and level 1 with coefficients in \(\mathbb {Q}\cap \mathbb {Z}_p\).
Theorem
(part (c) of Theorem 1.1) If \(p > k\) then the modulo p filtration of \(\mathcal {Q}_k^{(p)} (\)and \(\mathcal {Q}_k\)) is \(k(p + 1)/2\).
Proof
First, note that \(\mathcal {Q}_k \equiv \mathcal {Q}_k^{(p)} \pmod {p}\) since they only differ modulo higher powers of p. Thus they must have the same filtration.
We may write \(\mathcal {Q}_k\) as a polynomial of degree k / 2 in \(G_2,\) and Theorem 2 of [11] gives us the leading coefficient:
where \((k-1)!! = 1\times 3 \times \cdots \times (k-1)\). Note that since \(p>k,\) the leading coefficient \(\frac{(k - 1)!!\; 8^{k/2 - 1}}{k/2}\) must be nonzero modulo p. Also, it is well-known that \(w(G_2^i) = iw(G_2) = i(p + 1)\) for all \(i \ge 1\). Thus the filtration of \(\frac{(k - 1)!!\; 8^{k/2 - 1}}{k/2} G_2^{k/2}\) is \(k(p+1)/2,\) and the filtrations of the “lower degree terms” are strictly smaller. It follows that the filtration of \(\mathcal {Q}_k\) is \(k(p+1)/2\), as desired. \(\square \)
4 Jacobi forms and the quasimodularity of \(\mathcal {Q}_k^{(p)}\)
In this section, we will show that \(\mathcal {Q}_k^{(p)}(\tau )\) is quasimodular for every prime p and non-negative integer k. We define certain auxiliary functions \(F(z,\tau )\) and \(F^{(p)}(z,\tau )\) which are generating functions for the q-brackets \(\mathcal {Q}_k(\tau )\) and \(\mathcal {Q}_k^{(p)}(\tau )\), and we show these functions are Jacobi forms. We then make use of the theory of Jacobi forms to prove our quasimodularity result.
4.1 Definitions of \(F(z,\tau )\) and \(F^{(p)}(z,\tau )\)
In order to better understand \(\mathcal {Q}_k^{(p)}(\tau )\), we first define the function \(F:\mathbb {C}\times \mathbb {H}\rightarrow \mathbb {C}\) and its regularization \(F^{(p)}\) by
where we set \(q=e^{2\pi i\tau }\) and \(\zeta =e^{2\pi iz}.\)
We can describe the function \(F^{(p)}(z,\tau )\) in terms of \(F(z,\tau )\) as follows.
Proposition 4.1
Using the notation given above, we have that
Proof
First we claim that
Equation (5) follows by differentiating and evaluating at \(z=0;\) for all integers \(k\ge 1\) we have
Using the equation \(\frac{4\pi iz}{\zeta -\zeta ^{-1}} = \sum _{n=0}^\infty \beta _n(4\pi iz)^n,\) we see that
Together these imply that
Equation (6) holds by a similar argument.
A direct calculation using (5) shows that
\(\square \)
4.2 Jacobi forms
It turns out that \(F(z;\tau )\) and \(F^{(p)}(z;\tau )\) are meromorphic Jacobi forms. In order to define Jacobi forms, we begin by defining the Petersson slash operator for Jacobi forms. Given a matrix \(\gamma =\begin{pmatrix}a&{}\quad b\\ c&{}\quad d\end{pmatrix}\in \mathrm {SL}_2(\mathbb {Z})\) and a function \(\phi (z;\tau ):\mathbb {C}\times \mathbb {H}\rightarrow \mathbb {C},\) define the weight k index m slash operator by
where \(e(\alpha ) := e^{2\pi i\alpha }\).
Jacobi forms are invariant under the action of matrices with respect to the slash operator and elliptic transformations.
Definition 3
If k and m are integers, a holomorphic Jacobi form of weight k and index m for some subgroup \(\Gamma \) of \(\mathrm {SL}_2(\mathbb {Z})\) is a holomorphic function
which satisfies the following properties:
-
1.
for every \(\gamma \in \Gamma ,\)
$$\begin{aligned} \left( \phi |_{k,m}\gamma \right) (z; t)=\phi (z;\tau ), \end{aligned}$$ -
2.
for every pair of integers a and b,
$$\begin{aligned} \phi \left( z+a\tau +b;\tau \right) =e(-m(a^2\tau +2az))\phi (z;\tau ), \end{aligned}$$ -
3.
and the function \(\phi (z;\tau )\) has a Fourier expansion of the form
$$\begin{aligned} \phi (z;\tau )=\sum _{\begin{array}{c} n,r\in \mathbb {Z}\\ n\ge \frac{r^2}{4m} \end{array}}c(n,r)q^n\zeta ^r. \end{aligned}$$
We refer to the variable z in the definition above as the elliptic variable and to \(\tau \) as the modular variable.
A meromorphic Jacobi form is a function which satisfies properties (1), (2), and (3) in the definition above, but is required only to be meromorphic in the elliptic variable and weakly holomorphic in the modular variable—that is for fixed z, the function \(\tau \mapsto \phi (z;\tau )\) is holomorphic on \(\mathbb {H}\) and meromorphic at the cusps of \(\mathbb {H}/\Gamma \). For more details on Jacobi forms, see [6].
Proposition 4.2
The functions \(F(z;\tau )\) and \(F^{(p)}(z;\tau )\) are meromorphic Jacobi forms of weight 1 and index \(-2\) for \(\mathrm {SL}_2(\mathbb {Z})\) and \(\Gamma _0(p^2)\), respectively, with simple poles at the points \(z\in \frac{1}{2}\mathbb {Z}\oplus \frac{\tau }{2}\mathbb {Z}\), and \(z\in \frac{1}{2p}\mathbb {Z}\oplus \frac{\tau }{2}\mathbb {Z}\), respectively.
Proof
In Section 6 of [3], Bloch and Okounkov prove that
where \(\theta _1(z;\tau )\) is the standard theta function
Although the definition given above only allows for Jacobi forms of integer weight and index, it can be modified to allow Jacobi forms of half integer weight and index, although care must be taken with the square root. The function \(\theta _1\) defined above is a holomorphic function with simple zeros at the points \(z\in \mathbb {Z}\oplus \tau \mathbb {Z}\), and transforms like a Jacobi form of weight 1 / 2 and index 1 / 2 for \(\mathrm {SL}_2(\mathbb {Z})\) with a multiplier. In particular, we have that
Taking into account the change of variable, these facts together imply the proposition for \(F(z;\tau )\).
To prove the proposition for \(F^{(p)}(z;\tau ),\) we use Proposition 4.1 and consider the individual components \(F(z+j/p;\tau )\). Using the Jacobi form transformation laws we find that if \(\begin{pmatrix}a&{}\quad b\\ c&{}\quad d\end{pmatrix}\in \Gamma _0(p^2),\) then
Since \(p^2\) divides c, the action of the matrix simply permutes these terms, leaving only the expected automorphy factor, \((c\tau +d) \ e\left( -2c\frac{z^2}{c\tau +d}\right) .\) \(\square \)
4.3 Showing quasimodularity
In this section, we will prove the following.
Theorem
(part (d) of Theorem 1.1) Let \(p \ge 5\) be prime. Then we have that \(\mathcal {Q}_k^{(p)} \in \widetilde{M}_k(p^2)\).
We have defined the functions F and \(F^{(p)}\) so that the q-brackets and regularized q-brackets arise from derivatives of these functions. Although derivatives of Jacobi forms are not generally Jacobi forms themselves, there is a certain differential operator \(Y_{m}\) which preserves the modularity properties, but sacrifices holomorphicity. Let \(Y_{m}\) be the Jacobi raising operator defined as follows (see [2], pg.43], or [5], Def.2.5]):
for all meromorphic \(\phi (z;\tau ):\mathbb {C}\times \mathbb {H}\rightarrow \mathbb {C}.\)
Proposition 4.3
(Berndt, Schmidt) The operator \(Y_{m}\) commutes with the action of the slash operator but increases the weight by 1, so that if \(\gamma =\begin{pmatrix}a&{}\quad b\\ c&{}\quad d\end{pmatrix}\in \mathrm {SL}_2(\mathbb {Z}),\) and \(\phi (z;\tau )\) is any real-analytic function \(\phi (z;\tau ):\mathbb {C}\times \mathbb {H}\rightarrow \mathbb {C},\) then
Therefore, if \(\phi \) transforms like a Jacobi form of weight k and index m, then \(Y_{m} (\phi )\) transforms like a Jacobi form of weight \(k+1\) and index m.
Proof
Let \(\phi '(z;\tau ):=\frac{1}{2\pi i}\frac{\partial }{\partial z}\phi (z;\tau ).\) Using the definitions above we have
A short (but slightly messy) calculation shows that
which allows us to turn the above equation into
as desired. \(\square \)
Eichler and Zagier show that the Taylor coefficients with respect to the elliptic variable of holomorphic Jacobi forms are quasimodular forms [6]. The idea is as follows: suppose \(\phi (z;\tau )\) is any function which is invariant under the slash operator \(|_{k,m}.\) If \(\phi (0,\tau )\) is defined, than the transformation laws imply this function in \(\tau \) transforms like a weight k modular form. Thus, if \(\Phi (z;\tau )\) is a holomorphic Jacobi form of index m, then \(Y^n_m(\Phi )(0;\tau )\) transforms like a modular form. It is not difficult then to see that the holomorphic component \(\left( \frac{1}{2\pi i}\frac{\partial }{\partial z}\right) ^n(\Phi )(0;\tau )\) must be quasimodular.
Unfortunately, F and \(F^{(p)}\) both have poles at \(z=0.\) We can work around this problem by taking a residue at \(z=0\); however, we must be careful how we do this. The following procedure is similar to that followed by other authors, including Bringmann and Folsom [4], Section3] and Olivetto [9]. Suppose G(z) is any function which is real-analytic near \(z=0\) with a singularity of at most finite order at 0 (i.e., there is some positive integer j such that \(|z|^{2j} G(z)\) is real-analytic in a neighborhood of 0). Then G(z) can be written as a Laurant series in z and \(\overline{z},\) or in polar coordinates by setting \(z=r~e^{2 \pi i \theta }\) and \(\overline{z}=r~e^{-2 \pi i \theta }.\) Then we define \(\mathop {\mathrm{Res}}\limits _{z=0}\frac{1}{z}G(z)\) to be the limit of the integral
whenever this limit exists. This limit will converge so long as no term in the Laurant series expansion for G(z) at 0 is a negative power of \(z\overline{z}.\) In our case, the denominators will only have powers of the holomorphic variable.
Proposition 4.4
Suppose \(\phi (z;\tau ):\mathbb {C}\times \mathbb {H}\rightarrow \mathbb {C}\) is a function which is real-analytic in z near \(z=0\) with at most a singularity of finite order at \(z=0\) and which transforms like a weight k index m Jacobi form on \(\Gamma \). If the residue
exists, then it transforms in \(\tau \) like a modular form of weight k for \(\Gamma \).
Proof
We begin by noting that the function \(\Phi (z;\tau ):= e\left( mz\frac{\mathrm {im}z}{\mathrm {im}\tau }\right) \phi (z;\tau )\) has a particularly clean transformation law:
This follows from the identity
As above, set \(z=re^{2\pi i \theta },\) and let
Then if we let \(z'=z(c\tau +d)=r'e^{2\pi i \theta '}\), we have that
\(\square \)
We are now ready to prove part (d) of Theorem 1.1.
Proof of Theorem1.1(d)
Let \(\widetilde{\mathcal {Q}}_k(\tau )\) and \(\widetilde{\mathcal {Q}}^{(p)}_k(\tau )\) be the results of applying Proposition 4.4 to the functions \(Y_{-2}^{k-1}F(z;\tau )\) and \(Y_{-2}^{k-1}F^{(p)}(z;\tau )\), respectively. The definition of \(Y_{-2}\) implies that \(\widetilde{\mathcal {Q}}_k(\tau )\) is a function of \(y:=\mathrm {im}\tau \) and \(\tau \), and can be written in the form
as a polynomial in 1 / y whose coefficients, \(f_m,\) are holomorphic q-series. In fact we see that \(f_0=2^{k-1}\mathcal {Q}_k(\tau ),\) and each of the remaining \(f_m\) can be written in terms derivatives of brackets \(\mathcal {Q}_\ell (\tau )\) with \(\ell <k.\) Since \(\widetilde{\mathcal {Q}}_k(\tau )\) transforms like a modular form, it follows that \(\mathcal {Q}_k(\tau ) \in \widetilde{M}_{k}\). A nearly identical argument holds for \(\widetilde{\mathcal {Q}}_k^{(p)}(\tau );\) since \(\widetilde{\mathcal {Q}}_k^{(p)}(\tau )\) transforms like a modular form for \(\Gamma _0(p^2),\) we must have that \(\mathcal {Q}_k^{(p)}(\tau )\in \widetilde{M}_{k}(p^2)\). This completes the proof of Theorem 1.1(d).
4.4 Finding an explicit expression
Just as we can write \(G_k^{(p)}\) in terms of \(G_k\), we can write \(\mathcal {Q}_k^{(p)}\) in terms of \(\mathcal {Q}_k\). However, there is an extra correction term
Theorem
(part (e) of Theorem 1.1) Let \(p \ge 5\) be prime. We have that
where
Proof
The function \(F(z;\tau )\) is closely related to the partition crank generating function, which is given [1, 12] by
Using this identity, we obtain an alternative expression for F,
Using Proposition 4.1, we have that the difference \(F(z;\tau )-F^{(p)}(z;\tau )\) simply isolates the coefficients of powers of \(\zeta \) divisible by p. When p is an odd prime, we have that \(F(z;\tau )-F^{(p)}(z;\tau )\) is given by
Here we have made the substitution \(2m+1=p(2M+1)\) when p divides \(2m+1.\) If we separate the terms where p divides n, \(F(z;\tau )-F^{(p)}(z;\tau )\) becomes
Let \(\tilde{F}^{(p)}(z;\tau ):=F(z;\tau )-F^{(p)}(z;\tau )-\frac{1}{8p\pi i z},\) so that we have removed the pole at \(z=0.\) Then if k is even, we use Eq. (8) above to find have that
where
Note that since \((n,p)=1,\) then for the exponent \(N=\frac{n^2+np(2M+1)}{2}\) we have that \(\left( \frac{N}{p}\right) =\left( \frac{2}{p}\right) .\) \(\square \)
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Acknowledgements
The authors began jointly discussing this work at the Spring School on Characters of Representations and Modular Forms held at the Max Planck Institute in Bonn, Germany, in March 2015 and are grateful for the good hospitality and excellent conference. The authors would also like to thank Don Zagier for his inspiring work, and Ken Ono and the referee for their helpful comments. The second and third authors thank the National Science Foundation for its support.
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Griffin, M.J., Jameson, M. & Trebat-Leder, S. On p-adic modular forms and the Bloch–Okounkov theorem. Res Math Sci 3, 11 (2016). https://doi.org/10.1186/s40687-016-0055-z
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DOI: https://doi.org/10.1186/s40687-016-0055-z