Raja's covering index of Lp spaces

Abstract

We study Raja's covering index X(n) for classical Lp-spaces and their non-commutative counterparts. For infinite-dimensional Hilbert spaces we compute the covering index exactly, proving \[ H(n)=n-1/2(n∈ N); \] in particular H(2)=1/2, thus answering a question of Raja about the precise two-piece covering index of . For scalar-valued Lebesgue spaces Lp(μ), 1 p<∞, we construct an explicit block decomposition of the unit ball yielding the upper bound Lp(μ)(n) n-1/p for all n∈N; in particular _p(n) n-1/p. For 1<p<∞, under the corresponding p-AUS renormability hypothesis, this combines with Raja's general lower bound to give the sharp asymptotic estimate Lp(μ)(n) n-1/p. We also obtain uniform upper bounds Lp(μ;E)(n) n-1/p for Bochner spaces Lp(μ;E) over non-atomic σ-finite measure spaces, with constants independent of the Banach space E; this shows that, at the level of power-type upper estimates, the covering index decays at the same rate regardless of the asymptotic geometry of~E and provides a partial negative answer to a problem of Raja. Finally, using non-commutative Clarkson inequalities, we derive power-type lower bounds Lp(M,τ)(n) n-1/r for non-commutative Lp(M,τ) spaces associated with semifinite von Neumann algebras, where r=\p,2\. We do not attempt to optimise the exponent or constants in the non-commutative setting.

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