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Subelliptic operators on Lie groups: regularity

Part of: Abstract harmonic analysis Lie groups Approximations and expansions

Published online by Cambridge University Press:  09 April 2009

A. F. M. Ter Elst  and
Derek W. Robinson
A. F. M. Ter Elst
Affiliation:
Centre for Mathematics and its Applications, School of Mathematical Sciences, Australian National University, ACT 0200, Australia
Derek W. Robinson
Affiliation:
Centre for Mathematics and its Applications, School of Mathematical Sciences, Australian National University, ACT 0200, Australia
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Abstract

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Let (ℋ, G, U) be a continuous representation of the Lie group G by bounded operators gU(g) on the Banach space ℋ and let (ℋ, g, dU) denote the representation of the Lie algebra g obtained by differentiation. If a1,…, ad′ is a Lie algebra basis of g and Ai = dU(ai) then we examine elliptic regularity properties of the subelliptic operators where (cij) is a real-valued strictly positive-definite matrix and c0, c1,…, cd′ ∈ C. We first introduce a family of Lipschitz subspaces ℋγ, γ > 0, of ℋ which interpolate between the Cn-subspaces of the representation and for which the parameter γ is a continuous measure of differentiability. Secondly, we give a variety of characterizations of the spaces in terms of the semigroup generated by the closure of H and the group representation. Thirdly, for sufficiently large values of Re c0 the fractional powers of the closure of H are defined, and we prove that D()γγ′, for γ′ < 2γ/r where r is the rank of the basis. Further we establish that 2γ/r is the optimal regularity value and it is attained for unitary representations or for the representations obtained by restricting U to ℋγ. Many other regularity properties are obtained.

MSC classification

Secondary: 43A65: Representations of groups, semigroups, etc. 41A05: Interpolation 22E45: Representations of Lie and linear algebraic groups over real fields
Type
Research Article
Information
Journal of the Australian Mathematical Society , Volume 57 , Issue 2 , October 1994 , pp. 179 - 229
Copyright
Copyright © Australian Mathematical Society 1994

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