THE SCATTERING PHASE: SEEN AT LAST

Jeffrey Galkowski; Pierre Marchand; Jian Wang; Maciej Zworski

doi:10.1137/23M1547147

THE SCATTERING PHASE: SEEN AT LAST

Jeffrey Galkowski, Pierre Marchand, Jian Wang, Maciej Zworski

Research output: Contribution to journal › Article › peer-review

Abstract

The scattering phase, defined as log det S(\lambda)/2\pii where S(\lambda) is the (unitary) scattering matrix, is the analogue of the counting function for eigenvalues when dealing with exterior domains and is closely related to Kre\u{\i}n's spectral shift function. We revisit classical results on asymptotics of the scattering phase and point out that it is never monotone in the case of strong trapping of waves. Perhaps more importantly, we provide the first numerical calculations of scattering phases for nonradial scatterers. They show that the asymptotic Weyl law is accurate even at low frequencies and reveal effects of trapping such as lack of monotonicity. This is achieved by using the recent high level multiphysics finite element software FreeFEM.

Original language	English
Pages (from-to)	246-261
Number of pages	16
Journal	SIAM Journal on Applied Mathematics
Volume	84
Issue number	1
DOIs	https://doi.org/10.1137/23M1547147
Publication status	Published - 1 Jan 2024

Keywords

Weyl law
finite element
obstacle scattering
scattering phase
trapping

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10.1137/23M1547147

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title = "THE SCATTERING PHASE: SEEN AT LAST",

abstract = "The scattering phase, defined as log det S(\textbackslash{}lambda)/2\textbackslash{}pii where S(\textbackslash{}lambda) is the (unitary) scattering matrix, is the analogue of the counting function for eigenvalues when dealing with exterior domains and is closely related to Kre\textbackslash{}u\{\textbackslash{}i\}n's spectral shift function. We revisit classical results on asymptotics of the scattering phase and point out that it is never monotone in the case of strong trapping of waves. Perhaps more importantly, we provide the first numerical calculations of scattering phases for nonradial scatterers. They show that the asymptotic Weyl law is accurate even at low frequencies and reveal effects of trapping such as lack of monotonicity. This is achieved by using the recent high level multiphysics finite element software FreeFEM.",

keywords = "Weyl law, finite element, obstacle scattering, scattering phase, trapping",

author = "Jeffrey Galkowski and Pierre Marchand and Jian Wang and Maciej Zworski",

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T2 - SEEN AT LAST

AU - Galkowski, Jeffrey

AU - Marchand, Pierre

AU - Wang, Jian

AU - Zworski, Maciej

PY - 2024/1/1

Y1 - 2024/1/1

N2 - The scattering phase, defined as log det S(\lambda)/2\pii where S(\lambda) is the (unitary) scattering matrix, is the analogue of the counting function for eigenvalues when dealing with exterior domains and is closely related to Kre\u{\i}n's spectral shift function. We revisit classical results on asymptotics of the scattering phase and point out that it is never monotone in the case of strong trapping of waves. Perhaps more importantly, we provide the first numerical calculations of scattering phases for nonradial scatterers. They show that the asymptotic Weyl law is accurate even at low frequencies and reveal effects of trapping such as lack of monotonicity. This is achieved by using the recent high level multiphysics finite element software FreeFEM.

AB - The scattering phase, defined as log det S(\lambda)/2\pii where S(\lambda) is the (unitary) scattering matrix, is the analogue of the counting function for eigenvalues when dealing with exterior domains and is closely related to Kre\u{\i}n's spectral shift function. We revisit classical results on asymptotics of the scattering phase and point out that it is never monotone in the case of strong trapping of waves. Perhaps more importantly, we provide the first numerical calculations of scattering phases for nonradial scatterers. They show that the asymptotic Weyl law is accurate even at low frequencies and reveal effects of trapping such as lack of monotonicity. This is achieved by using the recent high level multiphysics finite element software FreeFEM.

KW - Weyl law

KW - finite element

KW - obstacle scattering

KW - scattering phase

KW - trapping

U2 - 10.1137/23M1547147

DO - 10.1137/23M1547147

M3 - Article

AN - SCOPUS:85187194349

SN - 0036-1399

VL - 84

SP - 246

EP - 261

JO - SIAM Journal on Applied Mathematics

JF - SIAM Journal on Applied Mathematics

IS - 1

ER -

THE SCATTERING PHASE: SEEN AT LAST

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