Pentagonal number recurrence relations for p(n)
Abstract
We revisit Euler's partition function recurrence, which asserts, for integers n≥ 1, that p(n)=p(n-1)+p(n-2)-p(n-5)-p(n-7)+… = Σk∈ Z \0\ (-1)k+1 p(n-ω(k)), where ω(m):=(3m2+m)/2 is the mth pentagonal number. We prove that this classical result is the =0 case of an infinite family of ``pentagonal number'' recurrences. For each ≥ 0, we prove for positive n that p(n)=1g(n,0)(α· σ2-1(n)+ Tr2(n) +Σk∈ Z \0\ (-1)k+1 g(n,k)· p(n-ω(k))), where σ2-1(n) is a divisor function, Tr2(n) is the nth weight 2 Hecke trace of values of special twisted quadratic Dirichlet series, and each g(n,k) is a polynomial in n and k. The =6 case can be viewed as a partition theoretic formula for Ramanujan's tau-function, as we have Tr12(n)=-33108590592691· τ(n).
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