Cyclicity in the Drury-Arveson space and other weighted Besov spaces

Abstract

Let H be a space of analytic functions on the unit ball Bd in Cd with multiplier algebra Mult(H). A function f∈ H is called cyclic if the set [f], the closure of \ f: ∈ Mult(H)\, equals H. For multipliers we also consider a weakened form of the cyclicity concept. Namely for n∈ N0 we consider the classes Cn(H)=\ ∈ Mult( H): 0, [n]=[n+1]\. Many of our results hold for N:th order radially weighted Besov spaces on Bd, but we describe our results only for the Drury-Arveson space H2d here. Letting Cstable[z] denote the stable polynomials for Bd, i.e. the d-variable complex polynomials without zeros in Bd , we show that align* & if d is odd, then Cstable[z]⊂eq Cd-12(H2d), and \\ & if d is even, then Cstable[z]⊂eq Cd2-1(H2d).align* For d=2 and d=4 these inclusions are the best possible, but in general we can only show that if 0 n d4-1, then Cstable[z] Cn(H2d). For functions other than polynomials we show that if f,g∈ H2d such that f/g∈ H∞ and f is cyclic, then g is cyclic. We use this to prove that if f,g∈ H2d extend to be analytic in a neighborhood of Bd , have no zeros in Bd , and their zero sets coincide on the boundary, then f is cyclic if and only if g is cyclic. Furthermore, if for f∈ H2d C( Bd ) the set Z(f) ∂ Bd embeds a cube of real dimension 3, then f is not cyclic in the Drury-Arveson space.