Resolvent estimates for the Lamé operator and failure of Carleman estimates

Abstract: In this paper, we consider the Lamé operator −∆ * and study resolvent estimate, uniform Sobolev estimate, and Carlman estimate for −∆ * . First, we obtain sharp L p -L q resolvent estimates for −∆ * for admissible p, q. This extends the particular case q = p p−1 due to Cossetti [6]. Secondly, we show failure of uniform Sobolev estimate and Carlman estimate for −∆ * . Our approach is different from that in [6] which relies heavily on the Helmholtz decomposition. Instead, we directly analyze the Fourier multipli… Show more

“…So, the two are more or less equivalent. However, three of the authors [22] recently proved that if is replaced by the (d-dimensional) Lamé operator ∆ * R d in the above ((1.8) and (1.9)), then the uniform Sobolev inequality (1.8) and Carleman inequality (1.9) fail, while the uniform (and even non-uniform sharp) resolvent estimates are available in the general context of [21] (also, see [2,7]). This shows a fundamental difference between ∆ * and ∆.…”

“…See Corollary 6.1 in Section 6. In view of [22], if the first order spatial derivatives ∇ x is involved in the right side of (1.10), it seems that any uniform estimate cannot hold true. However, we do not pursue this issue here.…”

Strichartz and uniform Sobolev inequalities for the elastic wave equation

“…So, the two are more or less equivalent. However, three of the authors [22] recently proved that if is replaced by the (d-dimensional) Lamé operator ∆ * R d in the above ((1.8) and (1.9)), then the uniform Sobolev inequality (1.8) and Carleman inequality (1.9) fail, while the uniform (and even non-uniform sharp) resolvent estimates are available in the general context of [21] (also, see [2,7]). This shows a fundamental difference between ∆ * and ∆.…”

“…See Corollary 6.1 in Section 6. In view of [22], if the first order spatial derivatives ∇ x is involved in the right side of (1.10), it seems that any uniform estimate cannot hold true. However, we do not pursue this issue here.…”

Strichartz and uniform Sobolev inequalities for the elastic wave equation

“…Instead we choose to diagonalize the Fourier multiplier to get into the position to use resolvent estimates for the fractional Laplacian. Kwon-Lee-Seo [16] previously used a diagonalization to prove resolvent estimates for the Lamé operator. In three spatial dimensions we consider µ > 0 and ε = diag(ε 1 , ε 2 , ε 3 ).…”

“…The short argument is standard by now (cf. [15,16]), but contained for the sake of completeness. Let u ∈ L q 0 (R d ) be an eigenfunction of P + V with eigenvalue E ∈ C\R and suppose that E ∈ Z p,q (ℓ).…”

“…We refer to the works [3,12] for context. Finally, it would be interesting to investigate L p -L q -Carleman estimates, which were shown to fail for the Lamé operator in [16].…”

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