2008
DOI: 10.1088/0951-7715/21/10/003
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Eigenfunctions of the Laplacian and associated Ruelle operator

Abstract: Let Γ be a co-compact Fuchsian group of isometries on the Poincaré disk D and ∆ the corresponding hyperbolic Laplace operator. Any smooth eigenfunction f of ∆, equivariant by Γ with real eigenvalue λ = −s(1 − s), where s = 1 2 + it, admits an integral representation by a distribution D f,s (the Helgason distribution) which is equivariant by Γ and supported at infinity ∂D = S 1 . The geodesic flow on the compact surface D/Γ is conjugate to a suspension over a natural extension of a piecewise analytic map T : S … Show more

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Cited by 6 publications
(8 citation statements)
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“…Note that in [18], [20] and [14], where similar results are obtained for a specific family of Markov maps of the circle, it was possible to prove directly that the analogue of the Φ W map is injective thanks to the smooth structure on the circle which gives additional regularity to the eigendistributions. This is not the case in our symbolic setting, so we must resort to a dimension argument.…”
Section: Ruelle Operator Dualitymentioning
confidence: 57%
See 1 more Smart Citation
“…Note that in [18], [20] and [14], where similar results are obtained for a specific family of Markov maps of the circle, it was possible to prove directly that the analogue of the Φ W map is injective thanks to the smooth structure on the circle which gives additional regularity to the eigendistributions. This is not the case in our symbolic setting, so we must resort to a dimension argument.…”
Section: Ruelle Operator Dualitymentioning
confidence: 57%
“…Distributions related to eigenfunctions and the involution kernel appeared in [18], [19], [20] and [14] (plus, in a non rigorous form, in [8] and [9]). Moreover, distributions have been intensively studied, starting with [3], through anisotropic 1 We will use the two notations y → M e A ⋆ (ya) ϕ(ya)da and M e A ⋆ (·a) ϕ(·a)da indistinctly to indicate the needed function.…”
Section: Introduction and Main Resultsmentioning
confidence: 99%
“…The reverse implication is the easiest, and is actually the generalization to the finite covolume case of proposition 7 from [LT08]. Let f ∈ E b s(1−s) (Γ) and ν = D f,s .…”
Section: Invariant Relations For the Bowen-series Transform 119mentioning
confidence: 97%
“…Proposition 4 from [LT08] tells us how we can express the γ-invariance of f in terms of its Helgason boundary value.…”
Section: Invariant Relations For the Bowen-series Transform 119mentioning
confidence: 99%
“…In this section we will present the involution kernel which is a concept that is sometimes useful for understanding problems of different areas: large deviations ( [12]), issues of differentiability of the main eigenfunction and piecewise differentiability of the subaction [111] [110], optimal transport (see [49] [106], [99], [100]), etc... It is also related to the Gromov distance on hyperbolic spaces (see [101]).…”
Section: Introduction and Main Definitionsmentioning
confidence: 99%