Lattice-ordered algebras admitting a polynomial growth continuous function calculus

Abstract

We characterize the Archimedean lattice-ordered algebras with identity that admit a polynomial growth continuous function calculus. More precisely, for an n-tuple x=(x1,…,xn) in an Archimedean lattice-ordered algebra X with identity 1X, we prove that the existence of a lattice-algebra homomorphism from the algebra PGn of continuous functions on Rn of polynomial growth, sending the coordinate projections to x1,…,xn and the constant function to 1X, is equivalent to the existence of f 1X |x1| ·s |xn| and an f\!-subalgebra Y of X such that 1X,x1,… ,xn ∈ Y and, for every m ∈ N, the norm \|· \|fm is complete on Y Ifm. This result may be viewed as an analogue, for lattice-ordered algebras, of the characterization of positively homogeneous continuous function calculus for Archimedean vector lattices due to Laustsen and Troitsky. As a by-product, we describe the finitely generated free objects in the category of uniformly complete Archimedean f\!-algebras and also show that the existence of a nontrivial polynomial growth continuous function calculus on a vector space forces it to be a commutative f\!-algebra.