Boolean Walsh Eta Units and Eisenstein Bases For Squarefree Levels

Abstract

Let M>1 be squarefree and let D(M) be its Boolean divisor cube. To each Boolean character χT we attach the eta-quotient \[ RT(M)(τ)=Πd Mη(dτ)χT(d), χT(d)=(-1)|T(d)|. \] At squarefree level, the finite Fourier transform on the divisor cube simultaneously diagonalizes the squarefree Ligozat cusp-order matrix, Fricke complementation, Atkin--Lehner action on cusp labels, and the constant-term map for logarithmic Eisenstein series. In particular, for T, \[ 1/cRT(M) =ΛT(M)24χT(c), ΛT(M)= Πp∈ T(p-1) Πp M\\ p T(p+1), \] and the forms D RT(M) form a Walsh basis of the Eisenstein subspace of M2(Γ0(M)). The structural theorem also determines explicit Fricke constants, Atkin--Lehner eigenvalues, good-prime Hecke eigenvalues, local Up triangular blocks, a simultaneous bad-prime eigenbasis, and the indices of two explicit principal cuspidal divisor sublattices inside the formal degree-zero cusp-divisor lattice. As an application we specialize to the Heegner prime product \[ N=2·3·7·11·19·43·67·163. \] The first Boolean boundary gives the eta-normalized Heegner-coloured partition product, while the top Walsh character gives the Möbius eta-unit identity \[ D R P(N)(τ)=40415760- Σn1σ1(n)qn. \] The same application gives algebraic modular-unit relations for the reciprocal partition product and exact Fricke-fixed logarithmic derivative identities for 1/π, interpreted through the modular completion of E2 and through accelerated paired products.

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