A scalar c0-approximation criterion and gap-coordinate preduals for Lipschitz-free spaces

Abstract

We recover a scalar c0-approximation criterion for Banach spaces canonically embedded into ∞ by a countable norming family. It identifies the dual of the associated c0-subspace with the prescribed atomic predual precisely when bounded coordinatewise approximation by c0-elements is available. The formulation is a self-contained scalar version of the atomic predual and two-stars framework of D'Onofrio--Greco--Perfekt--Sbordone--Schiattarella. We then apply the criterion to Lipschitz-free spaces. The weak-star density of Lipschitz functions with bounded support is due to Aliaga--Pernecká--Petitjean--Procházka; in proper spaces this yields a canonical quotient from the bidual of the norm-closed span of compactly supported Lipschitz functions onto 0(M). The main concrete application concerns countable proper subsets K⊂ [0,∞) with the Euclidean metric. The connected components (aj,bj) of the complement of K give gap coordinates \[ Δj f=f(bj)-f(aj)bj-aj. \] We prove that, in the infinite case, these coordinates identify 0(K) with ∞, that the corresponding c0-subspace coincides with Dalet's predual S(K), and hence that \[ S(K)* (K), S(K)** 0(K) \] canonically and isometrically. This gives a coordinate c0 realization, for a non-discrete class with accumulation points, of the preduality covered abstractly by Dalet's theorem for countable proper metric spaces. No new proof of Dalet's theorem in full generality is claimed.