An Elementary Proof Of The Josefson-Nissenzweig Theorem For Banach Spaces C(KxL)
Abstract
In [8] probabilistic methods, in particular a variant of the Weak Law of Large Numbers related to the Bernoulli distribution, have been used to show that for every infinite compact spaces K and L there exists a sequence (μn) of normalized signed measures on K× L with finite supports which converges to 0 with respect to the weak topology of the dual Banach space C(K× L). In this paper, we return to this construction, limiting ourselves only to elementary combinatorial calculus. The main efects of this construction are additional information about the measures μn, this is particularly clearly seen (among the others) in the resulting inequalities 12π1n <A× B⊂ X× Y |μn(A× B)|<2π1n, n∈N, with μn(f) n 0 for every f∈ C(X × Y); where X and Y are arbitrary Tychonoff spaces containing infinite compact subsets, respectively. As an application we explicitly describe for Banach spaces C(X× Y) some complemented subspaces isomorphic to c0. This result generalizes the classical theorem of Cembranos and Freniche, which states that for every infinite compact spaces K and L, the Banach space C(K× L) contains a complemented copy of the Banach space c0.
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