Sharp Resolvent Estimates Outside of the Uniform Boundedness Range

Schippa

2021

Ann. Henri Poincaré

We solve time-harmonic Maxwell’s equations in anisotropic, spatially homogeneous media in intersections of $$L^p$$ L p -spaces. The material laws are time-independent. The analysis requires Fourier restriction–extension estimates for perturbations of Fresnel’s wave surface. This surface can be decomposed into finitely many components of the following three types: smooth surfaces with non-vanishing Gaussian curvature, smooth surfaces with Gaussian curvature vanishing along one-dimensional submanifolds but without flat points, and surfaces with conical singularities. Our estimates are based on new Bochner–Riesz estimates with negative index for non-elliptic surfaces.

Section: Introductionmentioning

confidence: 57%

“…The body of literature concerned with Bochner-Riesz estimates with negative index is huge, see, e.g., [5,10,24,33,41]. In Sect.…”

Section: Introductionmentioning

confidence: 99%

Time-Harmonic Solutions for Maxwell’s Equations in Anisotropic Media and Bochner–Riesz Estimates with Negative Index for Non-elliptic Surfaces

Schippa

2021

Ann. Henri Poincaré

“…For any fixed ζ ∈ C \ R ≥0 , however, the estimate (11) actually holds for a larger range of exponents, which is due to the improved properties of the Fourier symbol 1/(|ξ| 2 − ζ) and related Bessel potential estimates. We refer to [24] for more details about sharp L p − L q resolvent estimates of the form (11). Theorem 6 extends in an obvious way to the system case that we shall need in the following.…”

Section: The Lap For Helmholtz Systems -Proof Of Theoremmentioning

confidence: 89%

A limiting absorption principle for Helmholtz systems and time-harmonic isotropic Maxwell's equations

Cossetti

Journal of Functional Analysis

2021

In this work we investigate the L p − L q -mapping properties of the resolvent associated with the time-harmonic isotropic Maxwell operator. As spectral parameters close to the spectrum are also covered by our analysis, we obtain an L p − L q -type Limiting Absorption Principle for this operator. Our analysis relies on new results for Helmholtz systems with zero order non-Hermitian perturbations. Moreover, we provide an improved version of the Limiting Absorption Principle for Hermitian (self-adjoint) Helmholtz systems.

“…Here, the last equality comes from the fact that the third number inside the bracket of the second last line lies between the fourth and the fifth number. Combining this with (32) gives the desired bound.…”

Section: Proof Of Theoremmentioning

confidence: 94%

“…Another reference for this result and for the optimality of the asserted range can be found in [32,Theorem 2.14]. We will also need several Fourier restriction theorems for the Fourier transforms F n , F n−1 restricted to spheres in R n−1 respectively R n .…”

Section: The Representation Formulamentioning

confidence: 99%

An annulus multiplier and applications to the limiting absorption principle for Helmholtz equations with a step potential

Scheider

2020

Math. Ann.

We consider the Helmholtz equation −∆u + V u − λ u = f on R n where the potential V : R n → R is constant on each of the half-spaces R n−1 ×(−∞, 0) and R n−1 ×(0, ∞). We prove an L p − L q-Limiting Absorption Principle for frequencies λ > max V with the aid of Fourier Restriction Theory and derive the existence of nontrivial solutions of linear and nonlinear Helmholtz equations. As a main analytical tool we develop new L p − L q estimates for a singular Fourier multiplier supported in an annulus.