Modular Equalities for Complex Reflection Arrangements
We compute the combinatorial Aomoto--Betti numbers $\betap(\A)$ of a complex reflection arrangement. When $\A$ has rank at least 3, we find that $\betap(\A)\le 2$, for all primes $p$. Moreover, $\betap(\A)=0$ if $p>3$, and $\beta2(\A)\ne 0$ if and only if $\A$ is the Hesse arrangement. We deduce that the multiplicity $ed(\A)$ of an order $d$ eigenvalue of the monodromy action on the first rational homology of the Milnor fiber is equal to the corresponding Aomoto--Betti number, when $d$ is prime. We give a uniform combinatorial characterization of the property $ed(\A)\ne 0$, for $2\le d\le 4$. We completely describe the monodromy action for full monomial arrangements of rank 3 and 4. We relate $ed(\A)$ and $\betap(\A)$ to multinets, on an arbitrary arrangement.
2010 Mathematics Subject Classification: Primary 14F35, 32S55; Secondary 20F55, 52C35, 55N25.
Keywords and Phrases: Milnor fibration, algebraic monodromy, hyperplane arrangement, complex reflection group, resonance variety, characteristic variety, modular bounds.
Full text: dvi.gz 44 k, dvi 178 k, ps.gz 160 k, pdf 247 k.
Home Page of DOCUMENTA MATHEMATICA