Generalisations of Capparelli's and Primc's identities, I: coloured Frobenius partitions and combinatorial proofs

Abstract: In these two companion papers, we give infinite families of partition identities which generalise Primc's and Capparelli's identities, and study their consequences on the theory of crystal bases of the affine Lie algebra $A_{n-1}^{(1)}.$ In this first paper, we focus on combinatorial aspects. We give a $n^2$-coloured generalisation of Primc's identity by constructing a $n^2 \times n^2$ matrix of difference conditions, Primc's original identities corresponding to $n=2$ and $n=3$. While most coloured partition identities in the literature connect partitions with difference conditions to partitions with congruence conditions, in our case, the natural way to generalise these identities is to relate partitions with difference conditions to coloured Frobenius partitions. This gives a very simple expression for the generating function. With a particular specialisation of the colour variables, our generalisation also yields a partition identity with congruence conditions. Then, using a bijection from our new generalisation of Primc's identity, we deduce a multi-parameter family of identities on $(n^2-1)$-coloured partitions which generalise Capparelli's identity, also in terms of coloured Frobenius partitions. The particular case $n=2$ is Capparelli's identity and the case $n=3$ recovers an identity of Meurman and Primc. In the second paper, we will focus on crystal theoretic aspects. We will show that the difference conditions we defined in our $n^2$-coloured generalisation of Primc's identity are actually energy functions for certain $A_{n-1}^{(1)}$ crystals. We will then use this result to retrieve the Kac-Peterson character formula and derive a new character formula as a sum of infinite products for all the irreducible highest weight $A_{n-1}^{(1)}$-modules of level $1$.