Almost disjoint families and the geometry of nonseparable spheres
Abstract
We consider uncountable almost disjoint families of subsets of N, the Johnson-Lindenstrauss Banach spaces ( X A, \|\ \|∞) induced by them, and their natural equivalent renormings ( X A, \|\ \|∞, 2). We introduce a partial order P A and characterize some geometric properties of the spheres of ( X A, \|\ \|∞) and of ( X A, \|\ \|∞, 2) in terms of combinatorial properties of P A. Exploiting the extreme behavior of some known and some new almost disjoint families among others we show the existence of Banach spaces where the unit spheres display surprising geometry: 1) There is a Banach space of density continuum whose unit sphere is the union of countably many sets of diameters strictly less than 1. 2) It is consistent that for every >0 there is a nonseparable Banach space, where for every δ>0 there is >0 such that every uncountable (1-)-separated set of elements of the unit sphere contains two elements distant by less than 1 and two elements distant at least by 2--δ. It should be noted that for every >0 every nonseparable Banach space has a plenty of uncountable (1-)-separated sets by the Riesz Lemma. We also obtain a consistent dichotomy for the spaces of the form ( X A, \|\ \|∞, 2): The Open Coloring Axiom implies that the unit sphere of every Banach space of the form ( X A, \|\ \|∞, 2) either is the union of countably many sets of diameter strictly less than 1 or it contains an uncountable (2-)-separated set for every >0.
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