English

Computations associated with the resonance arrangement

Combinatorics 2021-06-30 v2

Abstract

The resonance arrangement An\mathcal{A}_n is the arrangement of hyperplanes in Rn\mathbb{R}^n given by all hyperplanes of the form iIxi=0\sum_{i \in I} x_i = 0, where II is a nonempty subset of {1,,n}\{1,\dots,n\}. We consider the characteristic polynomial χ(An;t)\chi(\mathcal{A}_n; t) of the resonance arrangement, whose value RnR_n at 1-1 is of particular interest, and corresponds to counts of generalized retarded functions in quantum field theory, among other things. No formula is known for either the characteristic polynomial or RnR_n, though RnR_n has been computed up to n=8n=8. By exploiting symmetry and using computational methods, we compute the characteristic polynomial of A9\mathcal{A}_9, and thus obtain R9R_9. The coefficients of the characteristic polynomial are also equal to the so-called Betti numbers of the complexified hyperplane arrangement; that is, the coefficient of tnit^{n-i} is denoted by the Betti number bi(An)b_i(\mathcal{A}_n). Explicit formulas are known for the Betti numbers up to b3(An)b_3(\mathcal{A}_n). Using computational methods, we also obtain an explicit formula for b4(An)b_4(\mathcal{A}_n), which gives the tn4t^{n-4} coefficient of the characteristic polynomial.

Keywords

Cite

@article{arxiv.2106.09940,
  title  = {Computations associated with the resonance arrangement},
  author = {Zachary Chroman and Mihir Singhal},
  journal= {arXiv preprint arXiv:2106.09940},
  year   = {2021}
}
R2 v1 2026-06-24T03:20:51.115Z