1. Introduction
1.1. Mathematical setup and summary of major findings
The purpose of the paper is twofold. We are concerned with the spectral geometry of transmission eigenfunctions and the geometrical inverse scattering problem of recovering the shape of an anomalous scatterer, independent of its medium content, by a single far-field measurement. We first introduce the mathematical setup of our study.
Let
$\Omega$
be a bounded Lipschitz domain in
$\mathbb{R}^n$
,
$n=2,3$
, with a connected complement
$\mathbb{R}^n\backslash \overline{\Omega }$
. Let
$V\in L^\infty (\Omega )$
and
$\eta \in L^\infty (\partial \Omega )$
be complex-valued functions. Consider the following conductive transmission eigenvalue problem associated with
$k\in \mathbb R_+$
and
$(w,v)\in H^{1}(\Omega )\times H^1(\Omega )$
:
\begin{equation} \begin{cases} \ \ \Delta w+k^{2}(1+V)w=0 &\quad \mbox{$\mathrm{in}\ \ \Omega $},\\[5pt] \ \ \Delta v+k^{2}v=0 &\quad \mbox{$\mathrm{in}\ \ \Omega $},\\[5pt] \ \ w=v,\ \partial _{\nu }w=\partial _{\nu }v+\eta v &\quad \mbox{$\mathrm{on}\ \ \partial \Omega $}, \end{cases} \end{equation}
where and also in what follows,
$\nu \in \mathbb{S}^{n-1}$
signifies the exterior unit normal vector to
$\partial \Omega$
. Clearly,
$(w, v)=(0, 0)$
is a trivial solution to (1.1). If there exists a non-trivial pair of solutions to (1.1),
$k$
is referred to as a conductive transmission eigenvalue and
$(u, v)$
is the corresponding pair of conductive transmission eigenfunctions.
$\eta$
is called the boundary impedance or conductive parameter. If
$\eta \equiv 0$
, then (1.1) is reduced to the standard transmission eigenvalue problem. Hence, the conductive transmission eigenvalue problem (1.1) is a generalized formulation of the transmission eigenvalue problem. Nevertheless, it has its own physical background when
$\eta \equiv \!\!\!\!\backslash \;\, 0$
as shall be discussed in what follows. The existence and discreteness of the conductive transmission eigenvalues can be found in [Reference Bondarenko, Harris and Kleefeld14].
One of the main purposes of this paper is to quantitatively characterize the geometric property of the conductive transmission eigenfunctions (assuming their existence). The major findings can be briefly summarized as follows. If there is a polyhedral or conic corner on
$\partial \Omega$
, then under certain regularity conditions the eigenfunctions must vanish at the corner. The regularity conditions are characterized by the Hölder continuity of the parameters
$q\;:\!=\;1+V$
and
$\eta$
locally around the corner as well as a certain Herglotz extension property of the eigenfunction
$v$
, which is weaker than the Hölder continuity. The results extend the relevant ones in [Reference Diao, Cao and Liu26] in two directions: first, we consider a more general geometric setup where both polyhedral and conic corners are investigated, whereas in [Reference Diao, Cao and Liu26] only polygonal and edge corners are concerned; second, we significantly relax the regularity assumptions in [Reference Diao, Cao and Liu26] which is particularly useful for the geometrical inverse problem discussed in what follows. We develop novel technical strategies to achieve those new results. More detailed discussion shall be given in the next subsection.
The other focus of our study is the inverse scattering problem from a conductive medium scatterer. Let
$V$
be extended by setting
$V=0$
in
$\mathbb{R}^n\backslash \overline{\Omega }$
. Throughout, we set
$q=1+V$
. Let
$u^i({\mathbf{x}})$
be a time-harmonic incident wave which is an entire solution to
\begin{align} \Delta u^i({\mathbf{x}})+k^2 u^i({\mathbf{x}})=0,\quad \quad {\mathbf{x}}\in \mathbb R^n, \end{align}
where
$k\in \mathbb R_+$
signifies the wave number. Let
$(\Omega, q, \eta )$
denote a conductive medium scatterer with
$\Omega$
signifying its shape and
$q, \eta$
being its medium parameters. The impingement of
$u^i$
on
$(\Omega, q, \eta )$
generates wave scattering and it is described by the following system:
\begin{equation} \begin{cases} \Delta u^-+k^2qu^-=0, &\quad \mbox{in}\quad \Omega,\\[5pt] \Delta u^++k^2u^+=0, &\quad \mbox{in}\quad \mathbb R^n\setminus \overline{\Omega },\\[5pt] u^+=u^-,\quad \partial _\nu u^++\eta u^+=\partial _\nu u^-, &\quad \mbox{on}\quad \partial \Omega,\\[5pt] u^+=u^i+u^s, &\quad \mbox{in}\quad \mathbb R^n\backslash \overline{\Omega },\\[5pt] \lim _{r\to \infty }r^{(n-1)/2}(\partial _ru^s-\mathrm{i}ku^s)=0, &\quad r=\vert {\mathbf{x}}\vert, \end{cases} \end{equation}
where
$\mathrm{i}\;:\!=\;\sqrt{-1}$
and the last limit in (1.3) is known as the Sommerfeld radiation condition that characterizes the outward radiating of the scattered wave field
$u^s$
. The well-posedness of the direct problem (1.3) can be found in [Reference Bondarenko13] for the unique existence of
$u\;:\!=\;u^-\chi _\Omega +u^+\chi _{\mathbb{R}^n\backslash \overline{\Omega }} \in H^1_{\mathrm{loc}}(\mathbb R^n)$
. Moreover, the scattered field admits the following asymptotic expansion:
\begin{equation*} u^s({\mathbf{x}})=\frac{e^{ik\vert {\mathbf{x}}\vert }}{\vert {\mathbf{x}}\vert ^{(n-1)/2} }\left (u^\infty (\hat{{\mathbf{x}}})+\mathcal{O}\left (\frac{1}{\vert {\mathbf{x}}\vert ^{(n-1)/2}}\right )\right ), \quad \vert {\mathbf{x}}\vert \to \infty, \end{equation*}
which holds uniformly in all directions
$\hat{{\mathbf{x}}}\;:\!=\;{{\mathbf{x}}}/\vert {\mathbf{x}}\vert \in \mathbb{S}^{n-1}$
. The function
$u^\infty$
defined on the unit sphere
$\mathbb S^{n-1}$
is known as the far-field pattern of
$u^s$
. Associated with (1.3), we are concerned with the following geometrical inverse problem:
\begin{equation} u^\infty (\hat{{\mathbf{x}}};\; u^i),\ u^i\ \mbox{fixed}\longrightarrow \Omega \quad \mbox{independent of $q$ and $\eta $.} \end{equation}
That is, we intend to recover the geometrical shape of the conductive scatterer independent of its physical content by the associated far-field pattern generated by a single incident wave (which is usually referred to as a single far-field measurement in the literature).
Determining the shape of a scatterer from a single far-field measurement constitutes a longstanding problem in the inverse scattering theory [Reference Colton and Kress21, Reference Colton and Kress22, Reference Liu39]. In this paper, based on the spectral geometric results discussed earlier, we derive several new unique identifiability results for the inverse problem (1.4). In brief, we establish local unique recovery results by showing that if two conductive scatterers possess the same far-field pattern, then their difference cannot possess a polyhedral or conic corner. If we further imposed a certain a priori global convexity on the scatterer, then one can establish the global uniqueness result. Moreover, we can show that the boundary impedance parameter
$\eta$
can also be uniquely recovered. It is emphasized that all of the results established in this paper hold equally for the case
$\eta \equiv 0$
. If
$\eta \equiv 0$
, (1.3) describes the scattering from a regular medium scatterer
$(\Omega, q)$
. In the case
$\eta \neq 0$
,
$(\Omega, q, \eta )$
(effectively) characterizes a regular medium scatterer
$(\Omega, q)$
by a thin layer of highly loss medium [Reference Angell and Kirsch1, Reference Bondarenko13], and in two dimensions (1.3) describes the corresponding transverse electromagnetic scattering, whereas in three dimensions (1.3) describes the corresponding acoustic scattering. In addition to its physical significance, introducing a boundary parameter
$\eta$
makes our study more general which includes
$\eta \equiv 0$
as a special case. Hence, in what follows, we also call
$(v, w)$
to (1.1) as generalized transmission eigenfunctions.
1.2. Connection to existing studies and discussions
Before discussing the relevant existing studies, we note one intriguing connection between the scattering problem (1.3) and the spectral problem (1.1). If
$u_\infty \equiv 0$
, which by Rellich’s theorem implies that
$u^+=u^i$
in
$\mathbb{R}^n\backslash \overline{\Omega }$
, one can show that
$(v, w)=(u^i|_{\Omega }, u^-|_{\Omega })$
fulfils the spectral system (1.1). In the case of
$u_\infty \equiv 0$
, no scattering pattern can be observed outside
$\Omega$
, and hence, the scatterer
$(\Omega, q, \eta )$
is invisible/transparent with respect to the exterior observation under the wave interrogation by
$u^i$
. On the other hand, if
$(w, v)$
is a pair of transmission eigenfunctions to (1.1), then by the Herglotz extension
$v$
can give rise to an incident wave whose impingement on
$(\Omega, q, \eta )$
is (nearly) no scattering, i.e.,
$(\Omega, q, \eta )$
is (nearly) invisible/transparent.
Recently, there has been considerable interest in quantitatively characterizing the singularities of scattering waves induced by the geometric singularities on the shape of the underlying scatterer as well as its implications to invisibility and geometrical inverse problems. There are two perspectives in the literature. The first one is mainly concerned with occurrence or non-occurrence of non-scattering phenomenon, namely whether invisibility can occur or not. The main rationale is that if the scatterer possesses a geometric singularity (in a proper sense) on its shape, then it scatters a generic incident wave nontrivially, namely invisibility cannot occur. Here, the generic condition is usually characterized by a non-vanishing property of the incident wave at the geometrically singular place. It first started from the study in [Reference Blåsten, Päivärinta and Sylvester12] for acoustic scattering with many subsequent developments in different physical contexts [Reference Blåsten4–Reference Blåsten and Liu8, Reference Blåsten, Liu and Xiao10, Reference Cakoni and Vogelius18, Reference Cakoni and Xiao19, Reference Liu and Xiao42, Reference Päivärinta, Salo and Vesalainen45–Reference Vogelius and Xiao47].
The other one is a spectral perspective which is mainly concerned with the spectral geometry of transmission eigenfunctions. According to the connection mentioned above, the spectral geometric results characterize the patterns of the wave propagation inside a (nearly) invisible/transparent scatterer. It was first discovered in [Reference Blåsten and Liu9] that transmission eigenfunctions are generically vanishing around a corner point and such a local geometric property was further extended to conductive transmission eigenfunctions in [Reference Diao, Cao and Liu26], elastic transmission eigenfunctions in [Reference Blåsten and Lin5, Reference Diao, Liu and Sun33] and electromagnetic transmission eigenfunctions in [Reference Blåsten, Liu and Xiao10]. Though the two perspectives share some similarities, especially about the vanishing of the wave fields around the geometrically singular places, there are subtle and technical differences. In fact, it is numerically observed in [Reference Blåsten, Li, Liu and Wang11] that there exist transmission eigenfunctions which do not vanish, instead localize, around geometrically singular places. An unobjectionable reason to account for such (locally) localizing behaviour of the transmission eigenfunctions is the regularity of the eigenfunctions at the geometrically singular places. In general, if the transmission eigenfunctions are Hölder continuous, they locally vanish around the singular places. Nevertheless, it is shown in [Reference Liu and Tsou41] that under a certain Herglotz extension property, the locally vanishing property still holds. It is shown in [Reference Liu and Tsou41] that the aforementioned regularity criterion in terms of the Herglotz extension is weaker than the Hölder regularity. In addition to the local geometric pattern, the spectral geometric perspective also leads to the discovery of certain global geometric patterns of the transmission eigenfunctions. Indeed, it is discovered in [Reference Chow, Deng, He, Liu and Wang20, Reference Deng, Jiang, Liu and Zhang24, Reference Deng, Liu, Wang and Wu25] that the transmission eigenfunctions tend to (globally) localize on
$\partial \Omega$
with many subtle structures. Those spectral geometric results have been proposed to produce a variety of interesting applications, including super-resolution imaging [Reference Chow, Deng, He, Liu and Wang20], wave field boundary localization [Reference Diao, Li, Liu and Tang29], artificial mirage [Reference Deng, Liu, Wang and Wu25] and pseudo plasmon resonance [Reference Ammari, Chow and Liu2, Reference Ammari, Chow, Liu and Sunkula3]. We also refer to [Reference Liu39] for more related results in different physical contexts.
In this paper, we adopt the second perspective to study the (local) geometric properties of the conductive transmission eigenfunctions as well as consider the application to address the unique identifiability issue for the geometrical inverse scattering problem. As discussed in the previous subsection, our results derived in this paper extend the relevant ones in [Reference Diao, Cao and Liu26] in terms of the geometric setup as well as the regularity requirements. To achieve these new results, we develop novel technical strategies. In principle, we adopt microlocal tools to quantitatively characterize the singularities of the eigenfunctions induced by the corner or conic singularities. Nevertheless, we utilize CGO (Complex Geometric Optics) solutions of the PDO (partial differential operator)
$\Delta +(1+V)$
in our quantitative analysis, whereas in [Reference Diao, Cao and Liu26], the analysis made use of certain CGO solutions to
$\Delta$
. This induces various subtle and technical quantitative estimates and asymptotic analysis. Finally, as also discussed in the previous subsection, we apply the newly derived spectral geometric results to establish several novel unique identifiability results for the geometric inverse problem (1.4). We would also like to mention in passing some recent results on determining the shape of a scattering object by a single or at most a few far-field measurements in different physical contexts [Reference Blåsten4, Reference Blåsten and Liu6, Reference Blåsten and Liu7, Reference Blåsten, Liu and Xiao10, Reference Diao, Liu and Tao30–Reference Diao, Liu and Wang32, Reference Liu, Petrini, Rondi and Xiao40, Reference Liu and Zou43]. Recent developments of uniqueness and stability analysis for inverse scattering using spectral geometry can be found in [Reference Diao and Liu28].
The rest of the paper is organized as follows. In Section 2, we collect some preliminary results which are needed in the subsequent analysis. In Section 3, we show that the conductive transmission eigenfunctions to (1.1) near a convex sectorial corner in
$\mathbb R^2$
must vanish. In Section 4, we study the vanishing of conductive transmission eigenfunctions to (1.1) near a convex conic or polyhedral corner in
$\mathbb R^3$
. In Section 5, we discuss the visibility of a scatterer associated with (1.3). Furthermore, the unique recovery for the shape determination
$\Omega$
associated with the corresponding conductive scattering problem (1.3) is investigated.
2. Preliminaries
In this section, we present some preliminary results which shall be frequently used in our subsequent analysis.
Given
$s\in \mathbb{R}$
and
$p\geq 1$
, the Bessel potential space is defined by
\begin{equation} H^{s,p}\;:\!=\;\{f\in L^{p}(\mathbb{R}^{n});\;\, \mathcal{F}^{-1}[(1+\vert \xi \vert ^{2})^{\frac{s}{2}}\mathcal{F}f]\in L^{p}(\mathbb{R}^{n}) \}, \end{equation}
where
$\mathcal{F}$
and
$\mathcal{F}^{-1}$
denote the Fourier transform and its inverse, respectively.
We introduce a complex geometrical optics (CGO) solution
$u_0$
defined by (2.2) in Lemma 2.1.
Lemma 2.1. [Reference Cakoni and Xiao19] Given the space dimensions
$n=2,3$
, let
$q\in H^{1,1+\varepsilon _0},\varepsilon _0\in (0,1)$
and
\begin{equation} u_{0}({\mathbf{x}})=(1+\psi ({\mathbf{x}}))e^{\rho \cdot {\mathbf{x}}},\ {\mathbf{x}}\in \mathbb R^n \end{equation}
where
\begin{equation} \rho =-\tau ({\mathbf{d}}+\mathrm{i} {\mathbf{d}}^{\perp }), \end{equation}
with
${\mathbf{d}},\ {\mathbf{d}}^{\perp } \in \mathbb{S}^{n-1}$
satisfying
${\mathbf{d}}\perp {\mathbf{d}}^{\perp }$
and
$\tau \in \mathbb{R}_+$
. For sufficient large
$\tau$
, we have
\begin{equation} \Delta u_0 +k^2qu_0=0\quad \mbox{in} \quad \mathbb R^n, \end{equation}
and
$\psi ({\mathbf{x}})$
fulfils that
\begin{equation} \vert \vert \psi ({\mathbf{x}})\vert \vert _{H^{1,p}}=\mathcal{O}\left (\tau ^{n(\frac{1}{\tilde p}-\frac{1}{p})-2}\right ), \end{equation}
where
$(\widetilde p, p, \varepsilon _0 )=(24/19,8,1/2)$
for
$n=2$
and
$(\widetilde p, p, \varepsilon _0 )=(120/79,8,7/8)$
for
$n=3$
.
By Laplace transform and the exponential function of negative order analysis, we can readily have the following proposition.
Proposition 2.1. For any given
$\alpha \gt 0$
and
$0\lt \epsilon \lt e$
, we have the following estimates
\begin{align} & \left \vert \int _{\epsilon }^{\infty } r^{\alpha }e^{-\mu r}\mathrm{d}r \right \vert \leq \frac{2}{\Re \mu }e^{\frac{\epsilon }{2}\Re{\mu }}, \end{align}
\begin{align} & \int _{0}^{\epsilon }r^{\alpha }e^{-\mu r}\mathrm{d}r = \frac{\Gamma (\alpha +1)}{\mu ^{\alpha +1}} +\mathcal{O}\left ( \frac{2}{\Re{\mu }}e^{-\frac{\epsilon }{2}\Re{\mu }}\right ), \end{align}
as
$\Re (\mu )\rightarrow \infty$
, where
$\Gamma (s)$
stands for the Gamma function.
Lemma 2.2. [Reference Costabel23] Let
$\Omega \subset \mathbb R^n$
be a bounded Lipschitz domain. For any
$f, g\in H^{1,{\Delta }}\;:\!=\;\{f\in H^{1}(\Omega )\,|\,\Delta f\in L^{2}(\Omega )\}$
, then the following Green formula holds
\begin{equation} \int _{\Omega }(g\Delta f-f\Delta g)\mathrm{d}{\mathbf{x}}=\int _{\partial \Omega }(g\partial _{\nu }f-f\partial _\nu g) \mathrm{d}\sigma, \end{equation}
where
$\partial _\nu f$
is the exterior normal derivative of
$f$
to
$\partial \Omega$
.
3. Vanishing of transmission eigenfunctions near a convex planar corner
In this section, we consider the vanishing property of conductive transmission eigenfunctions to (1.1) near corners in
$\mathbb R^2$
. Firstly, let us introduce some notations for the subsequent use. Let
$(r,\theta )$
be the polar coordinates in
$\mathbb{R}^{2}$
; that is
${\mathbf{x}}=(x_{1},x_{2})=(r\cos \theta, r\sin \theta )\in \mathbb{R}^{2}$
. For
${\mathbf{x}}\in \mathbb{R}^{2}$
,
$B_{h}({\mathbf{x}})$
denotes an open ball of radius
$h \in \mathbb{R}_{+}$
and centred at
$ {\mathbf{x}}$
. For simplicity, we denote
$B_{h}\ \;:\!=\;B_{h}({\mathbf{0}})$
. Consider an open sector in
$\mathbb{R}^{2}$
with the boundary
$\Gamma ^{\pm }$
as follows,
\begin{equation} \mathcal{K}=\{ {\mathbf{x}} \in \mathbb{R}^{2}\,|\,\theta _{m}\lt \arg (x_{1}+\mathrm{i}x_{2})\lt \theta _{M} \}, \end{equation}
where
$-\pi \lt \theta _{m}\lt \theta _{M}\lt \pi, \mathrm{i}\;:\!=\;\sqrt{-1}$
and the two boundaries
$\Gamma ^{\pm }$
of
$\mathcal{K}$
correspond to
$(r,\theta _{m})$
and
$(r,\theta _{M})$
with
$r\gt 0$
, respectively . Set
\begin{equation} S_{h}=\mathcal{K}\cap B_{h},\ \Gamma _{h}^{\pm }=\Gamma ^{\pm }\cap B_{h},\ \Lambda _{h}=\mathcal{K}\cap \partial B_{h}. \end{equation}
Let the Herglotz wave function be defined by
\begin{align} u({\mathbf{x}})=\int _{\mathbb S^{1}} e^{\mathrm{i}k\xi \cdot {\mathbf{x}}}g (\xi )\mathrm{d}\xi,\ \xi \in \mathbb S^{n-1},\ {\mathbf{x}} \in \mathbb{R}^n,\ g \in L^{2}(\mathbb S^{n-1}), \quad n= 2 \mbox{ or }3, \end{align}
which is an entire solution of
\begin{equation*} (\Delta +k^2)u(\textbf {x})=0\quad \mbox { in } \quad \mathbb R^n,\quad n=2 \mbox { or }3. \end{equation*}
By [Reference Weck48, Theorem 2 and Remark 2], we know that the set of the Herglotz wave function is dense with respect to
$H^1$
norm in the set of the solution to
\begin{equation*} (\Delta +k^2 ) v(\textbf {x})=0 \quad \mbox { in } \quad D, \quad D\subset \mathbb R^n,\quad n=2 \mbox { or }3, \end{equation*}
where
$D$
is a bounded Lipschitz domain with a connected complement.
Consider the transmission eigenvalue problem (1.1) defined in a bounded Lipschitz domain
$\Omega$
with a connected complement. Since
$\Delta$
is invariant under rigid motions, without loss of generality, we always assume that
$ {\mathbf{0}} \in \partial \Omega$
throughoutthe rest of this paper. In Theorem 3.1, we establish the vanishing property of the transmission eigenfunctions near a convex planar corner under
$H^1$
regularity with certain Herglotz wave approximation assumptions in the underlying corner. We postpone the proof of Theorem 3.1 in the subsection 3.1. Compared with the assumptions in [Reference Diao, Cao and Liu26, Theorem 2.1], we remove the technical condition
$qw\in C^{\alpha }(\overline{S}_h )$
, which is critical for the analysis in [Reference Diao, Cao and Liu26].
Theorem 3.1.
Consider a pair of transmission eigenfunctions
$v\in H^{1}(\Omega )$
and
$w\in H^{1}(\Omega )$
to (
1.1
) associated with
$k\in \mathbb R_+$
, where
$\Omega$
is a bounded Lipschitz domain with a connected complement. Suppose that
${\mathbf{0}}\in \Gamma \subset \partial \Omega$
such that
$\Omega \cap B_h=\mathcal{K} \cap B_h=S_h$
, where the sector
$\mathcal{K}$
is defined by (
3.1
) and
$h\in \mathbb R_+$
is sufficiently small such that
$q\in H^2(\overline{S}_h)$
and
$\eta \in C^{\alpha }(\overline{\Gamma _h^\pm } )$
, where
$\alpha \in (0,1)$
. If the following conditions are fulfilled:
-
(a) for any given positive constants
$\beta$
and
$\gamma$
satisfying
(3.4)the transmission eigenfunction
\begin{equation} \gamma \lt \alpha \beta, \end{equation}
$v$
can be approximated in
$H^{1}(S_h)$
by the Herglotz wave functions
with the kernels
\begin{equation*} v_j=\int _{\mathbb S^{1}} e^{\textrm {i}k\xi \cdot \textbf {x}}g_j (\xi )\mathrm{d}\xi,j=1,2,\cdots, \end{equation*}
$g_j$
satisfying the approximation property
(3.5)
\begin{equation} \|v-v_{j}\|_{H^{1}}\leq j^{-\beta },\quad \|g_{j}\|_{L^{2}(\mathbb S^{1})}\leq j^{\gamma }; \end{equation}
-
(b)
$\eta$
does not vanish at
${\mathbf{0}}$
, where
${\mathbf{0}}$
is the vertex of
$S_h$
; -
(c) the open angle of
$S_h$
satisfies
\begin{equation*} -\pi \lt \theta _m\lt \theta _M\lt \pi \ and \ 0\lt \theta _M-\theta _m \lt \pi ; \end{equation*}
then one has
\begin{equation} \lim _{\lambda \to +0}\frac{1}{m(B({\mathbf{0}},\lambda )\cap \Omega )}\int _{B({\mathbf{0}},\lambda )\cap \Omega }\vert v({\mathbf{x}})\vert \mathrm{d}{\mathbf{x}}=0, \end{equation}
where
$m(B({\mathbf{0}},\lambda )\cap \Omega )$
is the area of
$B({\mathbf{0}},\lambda )\cap \Omega$
.
It is remarked that the Herglotz approximation property in (3.5) characterizes a regularity lower than Hölder continuity (cf. [Reference Liu and Tsou41]). In the following theorem, if the stronger Hölder regularity imposed on the transmission eigenfunction
$v$
near the corner is satisfied, we can prove that
$v$
vanishes near the corner point. The proof of Theorem 3.2 is a slight modification of the corresponding proof of Theorem 3.1. We only give a sketched proof of Theorem 3.2 at the end of Subsection 3.1.
Theorem 3.2.
Consider a pair of transmission eigenfunctions
$v\in H^{1}(\Omega )$
and
$w\in H^{1}(\Omega )$
to (
1.1
) associated with
$k\in \mathbb R_+$
, where
$\Omega$
is a bounded Lipschitz domain with a connected complement. Suppose that
${\mathbf{0}}\in \Gamma \subset \partial \Omega$
such that
$\Omega \cap B_h=\mathcal{K} \cap B_h=S_h$
, where the sector
$\mathcal{K}$
is defined by (
3.1
) and
$h\in \mathbb R_+$
. If the following conditions are fulfilled:
-
(a)
$q\in H^2(\overline{S}_h)$
,
$v\in C^\alpha (\overline{S}_h)$
and
$\eta \in C^{\alpha }(\overline{\Gamma _h^\pm } )$
, where
$0\lt \alpha \lt 1$
; -
(b) the function
$\eta$
does not vanish at the vertex
${\mathbf{0}}$
, where
${\mathbf{0}}$
is the vertex of
$S_h$
, i.e.,
(3.7)
\begin{equation} \eta ({\mathbf{0}})\not =0; \end{equation}
-
(c) the open angels of
$S_h$
satisfies
\begin{equation*}-\pi \lt \theta _m\lt \theta _M\lt \pi,\ and\ 0\lt \theta _M-\theta _m\lt \pi ;\end{equation*}
then one has
\begin{equation} v({\mathbf{0}}) =0. \end{equation}
Recall that
$\Omega$
is a bounded Lipschitz domain and
$\Gamma$
is an open subset of
$\partial \Omega$
. Consider the classical transmission eigenvalue problem:
\begin{equation} \begin{cases} &\Delta w+k^{2}qw=0 \quad \, \mbox{$\mathrm{in}\ \Omega $},\\[5pt] &\Delta v+k^{2}v=0 \quad \,\,\mbox{$\mathrm{in}\ \Omega $},\\[5pt] &w=v,\ \partial _{\nu }w=\partial _{\nu }v \,\,\mbox{$\mathrm{on}\ \partial \Omega $}, \end{cases} \end{equation}
which can be formulated from (1.1) by setting
$\eta \equiv 0$
. (3.9) is referred to as interior transmission eigenvalue problem, which has a colourful history in inverse scattering theory (cf. [Reference Cakoni, Colton and Haddar16, Reference Cakoni and Haddar17, Reference Liu39] and references therein). It was revealed that in [Reference Blåsten4, Theorem 1.2], the transmission eigenfunction
$v$
and
$w$
to (3.9) must vanish near a planar corner of
$\partial \Omega$
if
$v$
or
$ w$
is
$H^2$
-smooth near the underlying corner and
$q$
is Hölder continuous at the corner point. In the following Corollary 3.3, we shall establish the vanishing characterization of transmission eigenfunctions to (3.9) near a convex planar corner under two regularity criteria on the underlying transmission eigenfunctions near the corner. We should emphasize that we remove the
$H^2$
-smooth near the corner assumption on
$v$
and
$w$
as stated in [Reference Blåsten4, Theorem 1.2], where we only require that
$v$
is Hölder continuous at the corner point or holds a certain regularity condition in terms of Herglotz wave approximations (which is weaker than Hölder continuity as remarked earlier). The proof of Corollary 3.3 is postponed to Subsection 3.2.
Corollary 3.3.
Consider a pair of transmission eigenfunctions
$v\in H^{1}(\Omega )$
and
$w\in H^{1}(\Omega )$
to (3.9) associated with
$k\in \mathbb R_+$
, where
$\Omega$
is a bounded Lipschitz domain with a connected complement. Suppose that
${\mathbf{0}}\in \partial \Omega$
such that
$\Omega \cap B_h=\mathcal{K} \cap B_h=S_h$
, where the sector
$\mathcal{K}$
is defined by (
3.1
) and
$h\in \mathbb R_+$
is sufficient small such that
$q\in H^2(\overline S_h)$
and
$q({\mathbf{0}})\neq 1$
. The following two statements are valid.
-
(a) For any given positive constants
$\beta$
and
$\gamma$
satisfying
$\gamma \lt \beta$
, if the transmission eigenfunction
$v$
and Herglotz wave functions
$v_j$
with the kernel
$g_j$
satisfying the approximation property (3.5), then we have the vanishing property of
$v$
near
$S_h$
in the sense of (3.6). -
(b) If
$v\in C^\alpha (\overline{S_h})$
with
$\alpha \in (0,1)$
, then it holds that
$v({\mathbf{0}})=0$
.
3.1. Proof of Theorem 3.1
Given a convex sector
$\mathcal{K}$
defined by (3.1) and a positive constant
$\zeta$
, we define
$\mathcal{K}_{\zeta }$
as the open set of
$\mathbb{S}^{1}$
which is composed of all directions
${\mathbf{d}}\in \mathbb{S}^{1}$
satisfying that
\begin{equation} {\mathbf{d}}\cdot \hat{{\mathbf{x}}}\gt \zeta \gt 0, \quad for\ all\ \hat{{\mathbf{x}}} \in \mathcal{K} \cap \mathbb S^1 . \end{equation}
Throughout the present section, we always assume that the unit vector
$ {\mathbf{d}}$
in the form of the CGO solution
$u_0$
given by (2.2) fulfils (3.10).
Proposition 3.1.
Let
$S_{h}$
and
$\rho$
be defined in (
3.2
) and (
2.3
), respectively, where
$ {\mathbf{d}}$
satisfies (3.10). Then, we have
\begin{equation} \left \vert \int _{\Gamma _h^{\pm }}e^{\rho \cdot {\mathbf{x}}}\mathrm{d} {\mathbf{x}}\right \vert \geq \frac{C_{S_h }}{\tau }-\mathcal{O}\left (\frac{1}{\tau }e^{-\frac{1}{2}\zeta h \tau }\right ), \end{equation}
for sufficiently large
$\tau$
, where
$C_{S_h}$
is a positive number only depending on the opening angle
$\theta _M-\theta _m$
of
$\mathcal{K}$
and
$\zeta$
.
Proof. Using polar coordinates transformation and Proposition 2.1, we have
\begin{equation*} \begin{aligned} \int _{\Gamma _h^{\pm }}e^{\rho \cdot {\mathbf{x}}}\mathrm{d} \sigma &=\frac{\Gamma (1)}{\tau }\frac{1}{({\mathbf{d}}+\mathrm{i}{\mathbf{d}}^{\perp })\cdot \hat{{\mathbf{x}}_{{\mathbf{1}}}}}-I_{R_1}+\frac{\Gamma (1)}{\tau }\frac{1}{({\mathbf{d}}+\mathrm{i}{\mathbf{d}}^{\perp })\cdot \hat{{\mathbf{x}}_{{\mathbf{2}}}}}-I_{R_2}, \end{aligned} \end{equation*}
where
$\hat{{\mathbf{x}}_{{\mathbf{1}}}}$
and
$\hat{{\mathbf{x}}_{{\mathbf{2}}}}$
are unit vector of
${\mathbf{x}}$
on
$\Gamma ^-$
and
$\Gamma ^+$
, and
\begin{equation*} I_{R_1}=\int _{\Gamma ^-\setminus \Gamma ^-_h}e^{-\tau ({\mathbf{d}}+\mathrm{i}{\mathbf{d}}^\perp )}\mathrm{d}\sigma,\quad I_{R_2}=\int _{\Gamma ^+\setminus \Gamma ^+_h}e^{-\tau ({\mathbf{d}}+\mathrm{i}{\mathbf{d}}^\perp )}\mathrm{d}\sigma . \end{equation*}
Hence, with the help of Proposition 2.1, for sufficiently large
$\tau$
, we have the following integral inequality
\begin{equation} \begin{aligned} \left \vert \int _{\Gamma _h^{\pm }}e^{\rho \cdot {\mathbf{x}}}\mathrm{d} \sigma \right \vert &\geq \frac{1}{\tau }\left \vert \frac{1}{({\mathbf{d}}+\mathrm{i}{\mathbf{d}}^{\perp })\cdot \hat{{\mathbf{x}}_{{\mathbf{1}}}}} + \frac{1}{({\mathbf{d}}+\mathrm{i}{\mathbf{d}}^{\perp })\cdot \hat{{\mathbf{x}}_{{\mathbf{2}}}}} \right \vert -\vert I_{R_1}\vert -\vert I_{R_2} \vert \\[5pt] &\geq \frac{C_h}{\tau }-O\left (\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ) \end{aligned} \end{equation}
by using (3.10).
The following proposition can be directly derived by using (3.10) and Proposition 2.1.
Proposition 3.2.
For any given
$t\gt 0$
, we let
$S_h$
and
$\Gamma _h^\pm$
be defined by (3.2). Then, one has
\begin{equation} \vert \vert e^{\rho \cdot {\mathbf{x}}} \vert \vert _{L^t(S_h)}\leq C \left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-\frac{t}{2}\zeta h\tau }\right )^{\frac{1}{t}}, \end{equation}
\begin{equation} \vert \vert e^{\rho \cdot {\mathbf{x}}} \vert \vert _{L^t(\Gamma _h^{\pm })}\leq C \left (\frac{1}{\tau }+\frac{1}{\tau }e^{-\frac{t}{2}\zeta h\tau }\right )^{\frac{1}{t}}. \end{equation}
as
$\tau \rightarrow \infty$
, where
$\vert \vert e^{\rho \cdot {\mathbf{x}}} \vert \vert _{L^t(S_h)}=\left (\int _{S_h} |e^{\rho \cdot {\mathbf{x}}} |^t{\mathrm{d}}x\right )^{1/t}$
,
$\rho$
is defined in (
2.3
) and
$C$
is a positive constant only depending on
$t,\zeta$
.
Lemma 3.1.
Under the same setup of Theorem
3.1
, let the CGO solution
$u_0$
be defined by (2.2). Denote
$u=w-v$
, where
$(v,w)$
is a pair of transmission eigenfunctions of (1.1) associated with
$k$
. Then, it holds that
\begin{equation} \left\{\begin{array}{l@{\quad}l} \Delta u_0 +k^2qu_0=0& \mbox{in}\quad S_h,\\[5pt] \Delta u +k^2qu=k^2(1-q)v & \mbox{in}\quad S_h,\\[5pt] u=0,\quad \partial _\nu u=\eta v & \mbox{on}\quad \Gamma _h^\pm, \end{array} \right.\end{equation}
and
\begin{equation} \vert \vert \psi ({\mathbf{x}}) \vert \vert _{H^{1,8}}=\mathcal{O}(\tau ^{-\frac{2}{3}}), \end{equation}
where
$\psi$
and
$\tau$
are defined in (2.2).
Proof. Since
$q \in H^2(\overline{ S}_h)$
, let
$\widetilde q$
be the Sobolev extension of
$q$
such that
$\widetilde q \in H^2$
, then by this we have
$\tilde q\in H^{1,1+\varepsilon _0},\varepsilon _0\in (0,1)$
. Then by Lemma 2.1, one readily has (3.16).
Lemma 3.2. [Reference Gagliardo34, Reference Geymonat35, Reference Mikhailov44] Let
$\Omega$
be a Lipschitz bounded and connected subset of
$\mathbb R^n,n=2,3$
whose bounded and orientable boundary is denote by
$\Gamma$
. Let the restriction
$\gamma _0(u)=u|_\Gamma$
, then the operator
$\gamma _0$
is linear and continuous from
$H^{1,p}(\Omega )$
onto
$H^{1-\frac{1}{p},p}(\Gamma )$
for
$1\leq p\lt \infty$
.
Lemma 3.3.
Let
$\Gamma _h^\pm$
be defined in (3.2),
$e^{\rho \cdot {\mathbf{x}}}$
and
$\psi$
be given by (2.2) and (2.3). For sufficiently large
$\tau$
, it holds that
\begin{equation} \left \vert \int _{\Gamma _h^\pm } e^{\rho \cdot {\mathbf{x}}}\psi ({\mathbf{x}})\mathrm{d}\sigma \right \vert \lesssim \tau ^{-\frac{17}{12}}. \end{equation}
Throughout the rest of this paper,
$\lesssim$
means that we only give the leading asymptotic analysis by neglecting a generic positive constant
$C$
with respect to
$\tau \rightarrow \infty$
, where
$C$
is not a function of
$\tau$
.
Proof. Taking
$\textbf{y}=\tau {\mathbf{x}}$
, then using Hölder inequality and Lemma 3.2, one has
\begin{align} \int _{\Gamma _h^\pm }\vert e^{\rho \cdot {\mathbf{x}}}\vert &\vert \psi ({\mathbf{x}})\vert \mathrm{d}\sigma \lesssim \frac{1}{\tau }\|e^{-{\mathbf{d}}\cdot \textbf{y}}\|_{L^{\frac{8}{7}}(\Gamma _{\tau h}^\pm )}\left \|\psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{L^8(\Gamma _{\tau h}^\pm )} \\[5pt] & \lesssim \frac{1}{\tau }\|e^{-{\mathbf{d}}\cdot \textbf{y}}\|_{L^{\frac{8}{7}}(\Gamma ^\pm )}\left \|\psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{H^{1,8}(S_{\tau h})} \lesssim \frac{1}{\tau }\|e^{-{\mathbf{d}}\cdot \textbf{y}}\|_{L^{\frac{8}{7}}(\Gamma ^\pm )}\left \|\psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{H^{1,8}(\mathcal{K})},\nonumber \end{align}
for sufficiently large
$\tau$
. We have
$\frac{1}{\tau }\lt 1$
, and it holds that
\begin{align} \left \|\psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{H^{1,8}(\mathcal{K})} &\leq \tau ^{\frac{1}{4}}\left \|\psi ({\mathbf{x}})\right \|_{H^{1,8}(\mathcal{K})}=\mathcal{O}(\tau ^{-\frac{5}{12}}),\quad \mbox{as $\tau \rightarrow \infty $. } \end{align}
Furthermore,
\begin{equation} \|e^{-{\mathbf{d}}\cdot \textbf{y}}\|_{L^{\frac{8}{7}}(\Gamma ^\pm )} \leq \left (\int _{\Gamma ^\pm }e^{-\frac{8}{7}\zeta \vert \textbf{y}\vert }\mathrm{d}\sigma \right )^{\frac{7}{8}} =2\left ( \frac{7}{8}\frac{1}{\zeta }\right )^{\frac{7}{8}}, \end{equation}
where
$\zeta$
is defined in (3.10). Hence,
$\|e^{-{\mathbf{d}}\cdot \textbf{y}}\|_{L^{\frac{8}{7}}(\Gamma ^\pm )}$
is a positive constant which only depends on
$\zeta$
. Combining (3.19) and (3.20) with (3.18), we can prove Lemma 3.3.
Lemma 3.4.
Let
$\Lambda _h,\ S_h$
be defined in (3.2) and
$u_0({\mathbf{x}})$
be given by (2.2). Then,
$u_0({\mathbf{x}})\in H^1(S_h)$
and it holds that
\begin{align} \|u_0({\mathbf{x}})\|_{L^2(\Lambda _h)}&\lesssim \left (1+\tau ^{-\frac{2}{3}}\right )e^{-\zeta h\tau }, \end{align}
\begin{align} \|\nabla u_0({\mathbf{x}})\|_{L^2(\Lambda _h)}&\lesssim (1+\tau ) \left (1+\tau ^{-\frac{2}{3}}\right )e^{-\zeta h\tau }, \end{align}
\begin{align} \int _{S_h}\vert {\mathbf{x}}\vert ^{\alpha }\vert u_0({\mathbf{x}})\vert \mathrm{d}{\mathbf{x}} &\lesssim \tau ^{-(\alpha +\frac{29}{12})}+\left (\frac{1}{\tau ^{\alpha +2}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ) \end{align}
as
$\tau \rightarrow \infty$
, where
$\zeta$
is defined in (3.10) and
$\alpha \in (0,1)$
.
Proof. Using polar coordinates transformation, (2.6a) and (3.10), we can obtain that
\begin{equation} \|e^{\rho \cdot {\mathbf{x}}}\|_{ L^{t}(\Lambda _{h})} \lesssim e^{-\zeta h\tau }. \end{equation}
where
$\rho$
is defined in (2.3) and
$t$
is a positive constant.
According to (3.16) and Lemma 3.2, for sufficient large
$\tau$
, one can show that
\begin{align} \|\psi ({\mathbf{x}})\|_{L^{4}(\Lambda _{h})} \leq C \| \psi ({\mathbf{x}})\|_{H^{1,8}(S_h)}=O(\tau ^{-\frac{2}{3}}), \end{align}
where
$C$
is a positive constant, which is not a function of
$\tau$
.
By virtue of (3.23) and Hölder inequality, it can be directly verified that
\begin{equation} \begin{aligned} \|u_{0}\|_{ L^{2}(\Lambda _h)} &\leq \|e^{\rho \cdot {\mathbf{x}}}\|_{ L^{2}(\Lambda _{h})}+\|e^{\rho \cdot {\mathbf{x}}}\|_{ L^{4}(\Lambda _{h})}\|\psi ({\mathbf{x}})\|_{ L^{4}(\Lambda _{h})}\\[5pt] &\lesssim \left (1+\tau ^{-\frac{2}{3}}\right )e^{-\zeta h\tau },\quad \mbox{as $\tau \rightarrow \infty $. } \end{aligned} \end{equation}
Similarly, using Cauchy-Schwarz inequality, (3.21a) and Proposition 2.1, we have
\begin{equation} \begin{aligned} \|\nabla u_{0}({\mathbf{x}})\|_{L^{2}(\Lambda _h)} &\leq \sqrt{2}\tau \|u_{0}\|_{ L^{2}(\Lambda _h)}+\|e^{\rho \cdot {\mathbf{x}}}\|_{ L^{4}(\Lambda _h)} \|\nabla \psi ({\mathbf{x}})\|_{ L^{4}(\Lambda _h)}\\[5pt] &\lesssim (1+\tau )(1+\tau ^{-\frac{2}{3}})e^{-\zeta h\tau },\quad \mbox{as $\tau \rightarrow \infty $. } \end{aligned} \end{equation}
Moreover, by using Cauchy-Schwarz inequality, we know that
\begin{equation} \begin{aligned} \int _{S_{h}}\vert {\mathbf{x}}\vert ^{\alpha }\vert u_{0} \vert \mathrm{d}{\mathbf{x}} &\leq \int _{S_{h}}\vert {\mathbf{x}}\vert ^{\alpha }\vert e^{\rho \cdot {\mathbf{x}}} \vert \mathrm{d}{\mathbf{x}}+\int _{S_{h}}\vert {\mathbf{x}}\vert ^{\alpha }\vert e^{\rho \cdot {\mathbf{x}}}\vert \vert \psi ({\mathbf{x}})\vert \mathrm{d}{\mathbf{x}}.\\[5pt] \end{aligned} \end{equation}
Using polar coordinates transformation and Proposition 2.1, we can deduce that
\begin{equation} \int _{S_{h}}\vert {\mathbf{x}}\vert ^{\alpha }\vert e^{\rho \cdot {\mathbf{x}}} \vert \mathrm{d}{\mathbf{x}} \lesssim \left (\frac{1}{\tau ^{\alpha +2}}+\frac{1}{\tau }\right )e^{-\frac{1}{2}\zeta h\tau },\quad \mbox{as $\tau \rightarrow \infty $. } \end{equation}
Next, by letting
$\textbf{y}=\tau {\mathbf{x}}$
and Hölder inequality, it can be calculated that
\begin{equation} \begin{aligned} \int _{S_{h}}\vert {\mathbf{x}}\vert ^{\alpha }\vert e^{\rho \cdot {\mathbf{x}}}\vert \vert \psi ({\mathbf{x}})\vert \mathrm{d}{\mathbf{x}} &\leq \frac{1}{\tau ^{\alpha +2}}\int _{\mathcal{K}}\vert \textbf{y}\vert ^{\alpha }\vert e^{-{\mathbf{d}}\cdot \textbf{y}}\vert \left \vert \psi \left (\frac{\textbf{y}}{\tau }\right )\right \vert \mathrm{d}{\mathbf{x}}\\[5pt] &\leq \frac{1}{\tau ^{\alpha +2}}\|\vert \textbf{y}\vert ^{\alpha }\vert e^{-{\mathbf{d}}\cdot \textbf{y}}\vert \|_{L^{\frac{8}{7}}(\mathcal{K})}\left \|\psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{L^{8}(\mathcal{K})}. \end{aligned} \end{equation}
With the help of variable substitution and (3.16), we can calculate that
\begin{equation} \left \|\psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{L^8(\mathcal{K})}=\tau ^{\frac{1}{4}}\|\psi \!\left ({\mathbf{x}}\right )\|_{L^8(\mathcal{K})}=\mathcal{O}(\tau ^{-\frac{5}{12}}),\quad \mbox{as $\tau \rightarrow \infty $. } \end{equation}
Similar to (3.20), by using polar coordinates transformation, we have
$ \|{\vert \textbf{y}\vert }^\alpha \vert e^{-{\mathbf{d}}\cdot \textbf{y}}\vert \|_{L^{\frac{8}{7}}(\mathcal{K})}$
is a positive constant and not a function of
$\tau$
. Therefore, combining (3.29), (3.28) and (3.27) with (3.26), we have (3.21c).
The proof is complete.
Now we are in a position to prove Theorem 3.1.
Proof of Theorem 3.1 . By Green’s formula (2.7) and (3.15), the following integral equality holds
\begin{equation} \begin{aligned} \int _{\Lambda _{h}}(w-v)\partial _{\nu }u_{0}-u_{0}\partial _{\nu }(w-v)\mathrm{d}\sigma -\int _{\Gamma _h^{\pm }}\eta u_0v\mathrm{d}\sigma &=k^{2}\int _{S_{h}}(q-1)vu_{0}\mathrm{d}{\mathbf{x}}. \end{aligned} \end{equation}
Denote
\begin{equation*} f_{j}=(q-1)v_{j}. \end{equation*}
Since
$q\in H^2(\overline S_h)$
, by Sobolev embedding property, one has
$q\in C^{\alpha }(\overline S_h)$
where
$\alpha \in (0,1]$
. Clearly,
$v_{j}\in C^{\alpha }(\overline S_h)$
, hence
$f_{j}\in C^{\alpha }(\overline S_h)$
. According
$v_j\in C^{\alpha },\ \eta \in C^{\alpha }$
, we have the expansion
\begin{equation} \begin{aligned} f_{j}&=f_{j}({\mathbf{0}})+\delta f_{j},\ \vert \delta f_{j}\vert \leq \| f_{j}\|_{C^{\alpha }({\overline S}_h)}\vert {\mathbf{x}} \vert ^{\alpha },\\[5pt] v_j&=v_j({\mathbf{0}})+\delta v_j,\ \vert \delta v_j\vert \leq \|v_j\|_{C^{\alpha }(\overline S_h)}\vert {\mathbf{x}}\vert ^{\alpha },\\[5pt] \eta &=\eta ({\mathbf{0}})+\delta \eta,\ \vert \delta \eta \vert \leq \|\eta \|_{C^{\alpha }(\overline{ \Gamma _h^\pm } )}\vert {\mathbf{x}}\vert ^{\alpha }. \end{aligned} \end{equation}
By virtue of (3.31) and (2.2), it yields that
\begin{equation} \begin{aligned} &k^2\int _{S_{h}}(q-1)vu_0\mathrm{d}{\mathbf{x}} =-\sum _{m=1}^3 I_{m},\quad \int _{\Gamma _h^{\pm }}\eta u_0v\mathrm{d}\sigma =I-\sum _{m=4}^9I_m, \end{aligned} \end{equation}
where
\begin{align*} I_{1}&=-k^{2}\int _{S_{h}}(q-1)(v-v_{j})u_{0}\mathrm{d}{\mathbf{x}},\quad I_{2}=-\int _{S_{h}}\delta f_{j}u_{0}\mathrm{d}{\mathbf{x}},\quad \\[5pt] I_{3}&=-f_{j}({\mathbf{0}})\int _{S_{h}}u_0\mathrm{d}{\mathbf{x}},\quad I_4=-\eta ({\mathbf{0}})\int _{\Gamma _h^{\pm }}(v-v_j)u_0\mathrm{d}\sigma,\\[5pt] I_5&=-\int _{\Gamma _h^{\pm }}\delta \eta (v-v_j)u_0\mathrm{d}\sigma,\quad I_6=-\eta ({\mathbf{0}})v_j({\mathbf{0}})\int _{\Gamma _h^{\pm }}e^{\rho \cdot {\mathbf{x}}}\psi ({\mathbf{x}})\mathrm{d}\sigma,\\[5pt] I_{7}&=-\eta ({\mathbf{0}})\int _{\Gamma _h^{\pm }}\delta v_ju_0\mathrm{d}\sigma,\quad I_8=-v_j({\mathbf{0}}) \int _{\Gamma _h^{\pm }}\delta \eta u_0\mathrm{d}\sigma,\\[5pt] I_9&=-\int _{\Gamma _h^{\pm }}\delta \eta \delta v_j u_0\mathrm{d}\sigma,\quad I=\eta ({\mathbf{0}})v_j({\mathbf{0}})\int _{\Gamma _h^{\pm }}e^{\rho \cdot {\mathbf{x}}}\mathrm{d}\sigma . \end{align*}
Substituting (3.32) into (3.30), we have the following integral identity
\begin{align*} I=\sum _{m=1}^9I_m+J_1+J_2, \end{align*}
where
\begin{equation} \begin{aligned} J_{1}&=\int _{\Lambda _{h}}(w-v)\partial _{\nu }u_{0}\mathrm{d}\sigma,\quad J_{2}=-\int _{\Lambda _{h}} u_{0}\partial _{\nu }(w-v)\mathrm{d}\sigma . \end{aligned} \end{equation}
Therefore, it yields that
\begin{equation} \vert I\vert \leq \sum _{m=1}^9\vert I_m\vert +\vert J_1\vert +\vert J_2\vert . \end{equation}
In the following, we give detailed asymptotic estimates of
$I_m,m=1,\cdots,9$
and
$J_j,\ j=1,2$
as
$\tau \to \infty$
, separately. With the help of Proposition 3.2, Hölder inequality and (3.16), it arrives at
\begin{equation} \begin{aligned} \vert I_{1} \vert &\lesssim \|v-v_j\|_{L^2(S_h)}\left (\|e^{\rho \cdot {\mathbf{x}}}\|_{L^2(S_h)}+\| e^{\rho \cdot {\mathbf{x}}}\psi ({\mathbf{x}})\|_{L^2(S_h)}\right )\\[5pt] &\lesssim \|v-v_j\|_{L^2(S_h)}\left (\|e^{\rho \cdot {\mathbf{x}}}\|_{L^2(S_h)}+\| e^{\rho \cdot {\mathbf{x}}}\|_{L^4(S_h)}\|\psi ({\mathbf{x}})\|_{L^4(S_h)}\right )\\[5pt] &\lesssim j^{-\beta }\left [\left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-2\zeta h\tau }\right )^{\frac{1}{4}}\tau ^{-\frac{2}{3}} \right ] \end{aligned} \end{equation}
as
$\tau \rightarrow \infty$
.
By virtue of (3.31), it yields that
\begin{equation} \vert I_{2} \vert \leq \|f_{j} \|_{C^{\alpha }( \overline S_h)}\int _{S_{h}}\vert {\mathbf{x}}\vert ^{\alpha }\vert u_{0} \vert \mathrm{d}{\mathbf{x}}, \end{equation}
where
\begin{equation} \begin{aligned} \|f_{j}\|_{C^{\alpha } (S_h)}& \leq k^2\left (\|q\|_{C^{\alpha }(\overline S_h)}\sup _{S_h}\vert v_{j} \vert +\|v_{j}\|_{C^{\alpha }( \overline S_h)}\sup _{S_h}\vert q-1\vert \right ). \end{aligned} \end{equation}
Using the property of compact embedding of Hölder spaces, we can derive that
\begin{equation} \| v_{j}\|_{C^{\alpha }}\leq{\mathrm{diam} }\left (S_{h}\right )^{1-\alpha }\|v_{j}\|_{C^{1}(S_h)}, \end{equation}
where diam
$\left (S_{h}\right )$
is the diameter of
$S_{h}$
. By direct computations, we obtain
\begin{equation} \|v_{j}\|_{C^{1}}\leq \sqrt{2\pi }(1+k)\|g\|_{L^{2}(\mathbb S^{1})}. \end{equation}
Furthermore, by Cauchy-Schwarz inequality, we also can deduce that
\begin{equation} \vert v_{j}\vert \leq \sqrt{2\pi }\|g\|_{L^{2}(\mathbb S^{1})}. \end{equation}
Due to (3.5), by using the fact that
$q\in C^{\alpha }(\overline S_h)$
, substituting (3.38), (3.39) and (3.40) into (3.37), we have
\begin{equation} \|f_{j}\|_{C^{\alpha }(\overline S_h)}\lesssim j^{\gamma },\quad \|v_j\|_{C^\alpha (\overline S_h)}\lesssim j^{\gamma }, \end{equation}
where
$\gamma$
is a given positive constant defined in (3.5). Substituting (3.21c) and (3.41) into (3.36), we can deduce that
\begin{equation} \vert I_{2} \vert \lesssim j^{\gamma }\left [\tau ^{-(\alpha +\frac{29}{12})}+\left (\frac{1}{\tau ^{\alpha +2}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )\right ] \end{equation}
as
$\tau \rightarrow \infty$
.
Using Cauchy-Schwarz inequality, it can be easily calculated that
\begin{equation} \vert I_{3} \vert \lesssim \int _{S_h}\vert e^{\rho \cdot {\mathbf{x}}}\vert \mathrm{d}{\mathbf{x}}+\int _{S_h}\vert e^{\rho \cdot {\mathbf{x}}}\psi ({\mathbf{x}})\vert \mathrm{d}{\mathbf{x}}\lesssim \int _{S_h}\vert e^{\rho \cdot {\mathbf{x}}}\vert \mathrm{d}{\mathbf{x}}+\int _{\mathcal{K}}\vert e^{\rho \cdot {\mathbf{x}}}\psi ({\mathbf{x}})\vert \mathrm{d}{\mathbf{x}}. \end{equation}
By integral substitution and using (3.29), we obtain that
\begin{equation} \begin{aligned} \int _{\mathcal{K}}\vert e^{\rho \cdot {\mathbf{x}}}\psi ({\mathbf{x}})\vert \mathrm{d}{\mathbf{x}}&=\frac{1}{\tau ^2}\int _{\mathcal{K}}e^{-{\mathbf{d}}\cdot \textbf{y}}\left \vert \psi \left (\frac{\textbf{y}}{\tau }\right )\right \vert \mathrm{d}\textbf{y} \leq \frac{1}{\tau ^2} \|e^{-{\mathbf{d}}\cdot \textbf{y}}\|_{L^{\frac{8}{7}}(\mathcal{K})}\|\psi \left (\frac{\textbf{y}}{\tau }\right )\|_{L^{8}(\mathcal{K})}\\[5pt] &\lesssim \tau ^{-\frac{29}{12}},\quad \mbox{as $\tau \rightarrow \infty $. } \end{aligned} \end{equation}
With the help of Proposition 3.1, substituting (3.44) into (3.43), we can derive that
\begin{equation} \vert I_{3} \vert \lesssim \tau ^{-\frac{29}{12}}+\left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ), \mbox{as $\tau \rightarrow \infty $. } \end{equation}
Using Cauchy-Schwarz inequality, the trace theorem and Hölder inequality, we have
\begin{equation} \begin{aligned} \vert I_4\vert &\lesssim \|v-v_j\|_{L^2(\Gamma _h^{\pm })}(\|e^{\rho \cdot {\mathbf{x}}}\|_{L^2(\Gamma _h^{\pm })}+\|e^{\rho \cdot {\mathbf{x}}}\|_{L^4(\Gamma _h^{\pm })}\|\psi ({\mathbf{x}})\|_{L^4(\Gamma _h^{\pm })})\\[5pt] &\lesssim j^{-\beta }\left [\left (\frac{1}{\tau }+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau }+\frac{1}{\tau }e^{-2\zeta h\tau }\right )^{\frac{1}{4}}\tau ^{-\frac{2}{3}}\right ], \end{aligned} \end{equation}
as
$\tau \rightarrow \infty$
. Similarly, by virtue of Cauchy-Schwarz inequality, the trace theorem and Hölder inequality, it can be calculated that
\begin{equation*} \begin{aligned} \vert I_5\vert &\lesssim \|v-v_j\|_{H^1(S_h)}\left (\|e^{\rho \cdot {\mathbf{x}}}\vert \textbf x\vert ^{\alpha }\|_{L^2(\Gamma _h^{\pm })}+\|e^{\rho \cdot {\mathbf{x}}}\vert \textbf x\vert ^{\alpha }\|_{L^4(\Gamma _h^{\pm })}\|\psi ({\mathbf{x}})\|_{L^4(\Gamma _h^{\pm })}\right )\\[5pt] &\lesssim j^{-\beta }\left [ \left (\frac{1}{\tau ^{(2\alpha +1)}}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau ^{(4\alpha +1)}}+\frac{1}{\tau }e^{-2\zeta h\tau } \right )^{\frac{1}{4}}\tau ^{-\frac{2}{3}}\right ], \end{aligned} \end{equation*}
as
$\tau \rightarrow \infty$
. By using Lemma 3.3, one can show that
\begin{equation} \begin{aligned} I_6&\lesssim \int _{\Gamma _h^\pm }\vert e^{\rho \cdot {\mathbf{x}}}\psi ({\mathbf{x}})\vert \mathrm{d}{\mathbf{x}}\lesssim \tau ^{-\frac{17}{12}}, \quad \mbox{as $\tau \rightarrow \infty $. } \end{aligned} \end{equation}
Using (3.31), (3.41) and Proposition 2.1, we have the following inequality
\begin{align} \vert I_7\vert &\lesssim j^{\gamma }\left [\int _{\Gamma _{h}^{\pm }}\vert {\mathbf{x}}\vert ^{\alpha }\vert e^{\rho \cdot {\mathbf{x}}}\vert \mathrm{d}\sigma +\|\vert {\mathbf{x}}\|^{\alpha }\vert e^{\rho \cdot {\mathbf{x}}}\vert \|_{L^2(\Gamma _h^{\pm })}\|\psi ({\mathbf{x}})\|_{L^2(\Gamma _h^{\pm })} \right ] \nonumber \\[5pt] &\lesssim j^{\gamma }\left [\left (\frac{1}{\tau ^{\alpha +1}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )+\left (\frac{1}{\tau ^{2\alpha +1}}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}\tau ^{-\frac{2}{3}}\right ], \end{align}
as
$\tau \rightarrow \infty$
. According to (3.48), we can derive that
\begin{align} & \vert I_8\vert \lesssim \left (\frac{1}{\tau ^{\alpha +1}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )+\left (\frac{1}{\tau ^{2\alpha +1}}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}\tau ^{-\frac{2}{3}}, \end{align}
\begin{align} & \vert I_9\vert \lesssim j^{\gamma }\left [\left (\frac{1}{\tau ^{2\alpha +1}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )+\left (\frac{1}{\tau ^{4\alpha +1}}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}\tau ^{-\frac{2}{3}}\right ], \end{align}
as
$\tau \rightarrow \infty$
. By the Cauchy-Schwarz inequality and the trace theorem, we deduce that
\begin{align} \vert J_1\vert & \leq C\|u_{0}\|_{H^{1}(\Lambda _{h})} \|w-v\|_{H^{1}(\Lambda _{h})} \\[5pt] &\lesssim \|u_{0}\|_{H^{1}(\Lambda _{h})} \nonumber \end{align}
as
$\tau \rightarrow \infty$
, where
$C$
is a positive constant arising from the trace theorem. Hence, by virtue of (3.21a) and (3.21b), from (3.50), it is readily known that
\begin{equation} \begin{aligned} \vert J_1 \vert \lesssim (1+\tau )(1+\tau ^{-\frac{2}{3}})e^{-\zeta h\tau } \end{aligned} \end{equation}
as
$\tau \rightarrow \infty$
, where
$\zeta$
is a positive constant given in (3.10).
Similarly, using Cauchy-Schwarz inequality, the trace theorem and (3.21b), we can obtain that
\begin{align} \vert J_2 \vert & \leq \|\partial _{\nu } u_0\|_{ L^{2}(\Lambda _h)} \|w-v\|_{ L^{2}(\Lambda _h)} \leq C \|\partial _{\nu } u_0\|_{ L^{2}(\Lambda _h)} \|w-v\|_{ H^{1}(S_{h})} \nonumber\\[5pt] &\lesssim \|\nabla u_{0}\|_{ L^{2}(\Lambda _h)} \lesssim (1+\tau )(1+\tau ^{-\frac{2}{3}})e^{-\zeta h\tau }. \end{align}
Substituting (3.35), (3.42), (3.45), (3.51) and (3.52) into (3.34), by virtue of (3.11), we derive that
\begin{align} \left (\frac{C_{S_h}}{\tau }-\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )&\vert \eta ({\mathbf{0}})v_j({\mathbf{0}})\vert \lesssim j^{-\beta }\left [\left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-2\zeta h\tau }\right )^{\frac{1}{4}}\tau ^{-\frac{2}{3}} \right ] \nonumber \\[5pt] & + j^{\gamma }\left [\tau ^{-(\alpha +\frac{29}{12})}+\left (\frac{1}{\tau ^{\alpha +2}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )\right ] \nonumber \\[5pt] &+j^{-\beta }\left [\left (\frac{1}{\tau }+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau }+\frac{1}{\tau }e^{-2\zeta h\tau }\right )^{\frac{1}{4}}\tau ^{-\frac{2}{3}}\right ] \\[5pt] &+j^{-\beta }\left [ \left (\frac{1}{\tau ^{(2\alpha +1)}}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau ^{(4\alpha +1)}}+\frac{1}{\tau }e^{-2\zeta h\tau } \right )^{\frac{1}{4}}\tau ^{-\frac{2}{3}}\right ] \nonumber \\[5pt] &+(j^{\gamma }+1)\left [\left (\frac{1}{\tau ^{\alpha +1}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )+\left (\frac{1}{\tau ^{2\alpha +1}}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}\tau ^{-\frac{2}{3}}\right ] \nonumber \\[5pt] &+j^{\gamma }\left [\left (\frac{1}{\tau ^{2\alpha +1}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )+\left (\frac{1}{\tau ^{4\alpha +1}}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}\tau ^{-\frac{2}{3}}\right ] \nonumber \\[5pt] &+(1+\tau )(1+\tau ^{-\frac{2}{3}})e^{-\zeta h\tau }+ \tau ^{-\frac{29}{12}}+\left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )+\tau ^{-\frac{17}{12}}\nonumber \end{align}
as
$\tau \rightarrow \infty$
, where
$C_{S_h}$
is a positive constant given in (3.11). Multiplying
$\tau$
on both sides of (3.53) and letting
$\tau =j^s$
, where
$s\gt 0$
, it can be derived that
\begin{equation} \begin{aligned} \left (C_h-e^{-\frac{1}{2}\zeta hj^s}\right )\vert \eta ({\mathbf{0}})v_j({\mathbf{0}})\vert &\lesssim j^{-\beta +s}+j^{\gamma -(\alpha +1)s}+j^{-\beta +\frac{1}{2}s}+j^{-\beta +(-\alpha +\frac{1}{2})s}\\[5pt] &+j^{\gamma -\alpha s}+j^{-\frac{13}{24}s}+j^{-\frac{17}{12}s}, \end{aligned} \end{equation}
as
$\tau \rightarrow \infty$
. Under the assumption (3.4), we can choose
$s \in (\gamma/ \alpha, \beta )$
. Hence in (3.54), let
$j\rightarrow \infty$
it is readily to know that
\begin{equation*} \lim _{j \rightarrow \infty } \left \vert \eta (\textbf {0})v_j(\textbf {0})\right \vert =0.\end{equation*}
Since
$\eta ({\mathbf{0}})\not = 0$
, one has
$\lim _{j \rightarrow \infty }\vert v_j({\mathbf{0}})\vert =0$
. Using (3.5) and the integral mean value theorem, we can obtain (3.6).
The proof is complete.
Proof of Theorem
3.2
. Due to
$q\in H^2(\overline S_h)$
, using the Sobolev embedding property, we know that
$q\in C^\alpha (\overline{S_h})$
with
$\alpha \in (0,1]$
. Under the assumption
$v\in C^\alpha (\overline S_h)$
(
$\alpha \in (0,1]$
), it readily has
$f({\mathbf{x}})\;:\!=\;(q({\mathbf{x}})-1)v({\mathbf{x}}) \in C^{\alpha } (\overline{S_h})$
. Hence, we have the expansion of
$f({\mathbf{x}}),\ \eta$
and
$v({\mathbf{x}})$
near the origin as follows
\begin{equation} \begin{aligned} f({\mathbf{x}})&= f({\mathbf{0}})+\delta f,\quad \vert \delta f\vert \leq \|f\|_{C^\alpha }\vert {\mathbf{x}} \vert ^\alpha \\[5pt] \eta &= \eta ({\mathbf{0}})+\delta \eta,\quad \vert \delta \eta \vert \leq \|\eta \|_{C^\alpha }\vert {\mathbf{x}}\vert ^\alpha \\[5pt] v({\mathbf{x}})&= v({\mathbf{0}})+\delta v,\quad \vert \delta v\vert \leq \|v\|_{C^\alpha }\vert {\mathbf{x}}\vert ^\alpha \end{aligned} \end{equation}
Plugging (3.55) into the integral identity (3.30), it yields that
\begin{align} \eta ({\mathbf{0}})v({\mathbf{0}})\int _{\Gamma _h^{\pm }}e^{\rho \cdot {\mathbf{x}}}\mathrm{d}\sigma &=f({\mathbf{0}})\int _{S_h}u_0\mathrm{d}{\mathbf{x}}+\int _{S_h}\delta fu_0\mathrm{d}{\mathbf{x}} +\eta ({\mathbf{0}})v({\mathbf{0}})\int _{\Gamma _h^{\pm }}\psi ({\mathbf{x}})e^{\eta \cdot {\mathbf{x}}}\mathrm{d}\sigma \nonumber \\[5pt] &+\eta ({\mathbf{0}})\int _{\Gamma _h^{\pm }}\delta v u_0\mathrm{d}\sigma +v({\mathbf{0}})\int _{\Gamma _h^{\pm }}\delta \eta u_0\mathrm{d}\sigma +\int _{\Gamma _h^\pm }\delta v\delta \eta u_0\mathrm{d}\sigma \nonumber \\[5pt] &-\int _{\Lambda _h}(w-v)\partial _\nu u_0\mathrm{d}\sigma +\int _{\Lambda _h}u_0\partial _\nu (w-v)\mathrm{d}\sigma . \end{align}
By adopting similar asymptotic analysis for each integral in (3.56) with respect to the parameter
$\tau$
as in the proof of Theorem 3.1, and letting
$\tau \rightarrow \infty$
, we can prove Theorem 3.2.
3.2. Proof of Corollary 3.3
Next, we give the proof of Corollary 3.3 regarding the vanishing property of transmission eigenfunctions to (3.9) near a convex planar corner under two regularity conditions described in Corollary 3.3. Since the proof of the statement (b) in Corollary 3.3 can be obtained by using the similar asymptotic analysis for proving Corollary 3.3 (a), we omit it here. In order to prove the statement (a) in Corollary 3.3, we give the following proposition which is obtained by slightly modifying the proof of Proposition 3.1.
Proposition 3.3.
Let
$S_{h}$
and
$\eta$
be defined in (
3.2
) and (
2.3
), respectively, where
$ {\mathbf{d}}$
satisfies (3.10). Then, we have
\begin{equation} \left \vert \int _{S_h}e^{\eta \cdot {\mathbf{x}}}\mathrm{d} {\mathbf{x}}\right \vert \geq \frac{\widetilde{C_{S_h }}}{\tau ^2}-\mathcal{O}\left (\frac{1}{\tau }e^{-\frac{1}{2}\zeta h \tau }\right ), \end{equation}
for sufficiently large
$\tau$
, where
$\widetilde{C_{S_h }}$
is a positive number only depending on the opening angle
$\theta _M-\theta _m$
of
$\mathcal{K}$
and
$\zeta$
.
Proof. Using polar coordinates transformation and (2.6b) in Proposition 2.1, we have
\begin{equation*} \begin{aligned} \int _{S_h} e^{\rho \cdot {\mathbf{x}}}\mathrm{d} {\mathbf{x}} &=\int _{\theta _{m}}^{\theta _M}\left [\frac{\Gamma (2)}{(\tau ({\mathbf{d}}+\mathrm{i} {\mathbf{d}}^\perp )\cdot \hat{\textbf x} )^2}-I_\textsf{R}\right ]\mathrm{d}\theta \\[5pt] &=\frac{\Gamma (2)}{\tau ^2}\int _{\theta _{m}}^{\theta _M}\frac{1}{\left ({\mathbf{d}}\cdot \hat{\textbf x}+\mathrm{i} {\mathbf{d}}^\perp \cdot \hat{\textbf x} \right )^2}\mathrm{d} \theta -\int _{\theta _{m}}^{\theta _M}I_{\textsf{R}}\mathrm{d}\theta, \end{aligned} \end{equation*}
where
$I_\textsf{R}= \int _{h}^{\infty }e^{-\tau ({\mathbf{d}} +\mathrm{i}{\mathbf{d}})\cdot \hat{{\mathbf{x}}}r}r\mathrm{d} r$
. Hence, it can be directly calculated that
\begin{equation*} \int _{\theta _{m}}^{\theta _M}\frac{1}{\left ({\mathbf{d}}\cdot \hat{\textbf x}+\mathrm{i} {\mathbf{d}}^\perp \cdot \hat{\textbf x} \right )^2}\mathrm{d} \theta \geq \frac{\theta _M-\theta _m }{2} \end{equation*}
by using the integral mean value theorem.
With the help of Proposition 2.1, for sufficiently large
$\tau$
, we have the following integral inequality
\begin{equation} \begin{aligned} \left \vert \int _{S_h} e^{\rho \cdot {\mathbf{x}}}\mathrm{d} {\mathbf{x}} \right \vert &\geq \frac{\Gamma (2)(\theta _{M}-\theta _{m})}{\tau ^2} \frac{1}{\left \vert {\mathbf{d}}\cdot {\mathbf{x}}( \theta _{\xi })+ \mathrm{i} {\mathbf{d}}^{\perp} \cdot \hat{{\mathbf{x}}} (\theta _{\xi }) \right \vert ^2}- \left \vert \int _{\theta _{m}}^{\theta _M} I_{\textsf{R}} \mathrm{d}{\theta} \right \vert \\[5pt] &\geq \frac{\Gamma (2)}{(\theta _{M}-\theta _{m})}\frac{1}{\left ({\mathbf{d}}\cdot \hat{{\mathbf{x}}}(\theta _{\xi }) \right )^2+ \left ({\mathbf{d}}^{\perp} \cdot \hat{{\mathbf{x}}}(\theta _{\xi }) \right )^2}-\int _{\theta _{m}}^{\theta _M} \vert I_{\textsf{R}} \vert \mathrm{d}\theta \\[5pt] &\geq \frac{\widetilde{C_{S_h }}}{\tau ^2}-\frac{1}{\tau }e^{-\frac{1}{2}\zeta h \tau }, \end{aligned} \end{equation}
by using (3.10).
Proof of Corollary
3.3
(a)
. Similar to the proof of Theorem 3.1, we have the following integral identity according to (3.30) by noting
$\eta \equiv 0$
on
$\Gamma _h^\pm$
,
\begin{equation} k^2f_j(0)\int _{S_h}e^{\rho \cdot {\mathbf{x}}}\mathrm{d} {\mathbf{x}}=I_1+I_2+I_3+J_1+J_2, \end{equation}
where
\begin{align*} I_1&=-k^2\int _{S_h}(q-1)(v-v_j)u_0\mathrm{d} {\mathbf{x}},\quad I_2=-k^2\int _{S_h}\delta f_ju_0\mathrm{d}{\mathbf{x}}, \\[5pt] I_3&=-k^2f_j({\mathbf{0}})\int _{S_h}e^{\rho \cdot {\mathbf{x}}}\psi ({\mathbf{x}})\mathrm{d}{\mathbf{x}}, \end{align*}
and
$J_1$
,
$J_2$
are defined in (3.33), respectively.
By the Sobolev embedding theorem and
$q\in H^2(\overline S_{h})$
, we have
$q\in C^\alpha (\overline S_{h} )$
, where
$\alpha =1$
. Combining (3.59) with (3.35), (3.42) and (3.44), we can deduce that
\begin{equation} \begin{aligned} k^2\left [ \frac{\widetilde{C_{S_h }}}{\tau ^2}-\frac{1}{\tau }e^{-\frac{1}{2}\zeta h \tau }\right ] &\vert f_j({\mathbf{0}})\vert \lesssim j^{-\beta }\left [\left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-2\zeta h\tau }\right )^{\frac{1}{4}}\tau ^{-\frac{2}{3}} \right ]\\[5pt] &+j^{\gamma }\left [\tau ^{-(\alpha +\frac{29}{12})}+\left (\frac{1}{\tau ^{\alpha +2}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )\right ]\\[5pt] &+\tau ^{-\frac{29}{12}} +(1+\tau )(1+\tau ^{-\frac{2}{3}})e^{-\zeta h\tau } \end{aligned} \end{equation}
as
$\tau \to \infty$
. Multiplying
$\tau ^2$
on the both sides of (3.60), using the assumption (3.5), by letting
$\tau =j^s$
, it is easy to see that
\begin{equation} k^2\widetilde{C_{S_h }}\vert f_j({\mathbf{0}})\vert \lesssim j^{-\beta +s}+j^{\gamma - \alpha s}. \end{equation}
And under the assumptions
$\gamma/\alpha \lt \beta$
, we choose
$s\in (\gamma/\alpha,\beta )$
. Letting
$j\to \infty$
in (3.61), we obtain that
\begin{equation*}\vert f_j(\textbf {0})\vert =0.\end{equation*}
Since
$q({\mathbf{0}})\not =1$
, we finish the proof of this corollary.
4. Vanishing of transmission eigenfunctions near a convex conic corner or polyhedral corner
In this section, we study the vanishing of eigenfunctions near a corner in
$\mathbb R^3$
, respectively, where the corner in
$\mathbb R^3$
could be a convex conic corner or polyhedral corner. Let us first introduce the corresponding geometrical setup for our study. For a given point
${\mathbf{x}}_0\in \mathbb{R}^3$
, let
$\textbf{v}_0=\textbf{y}_0-{\mathbf{x}}_0$
where
$\textbf{y}_0\in \mathbb{R}^3$
is fixed. Hence,
\begin{equation} {\mathcal{C}}={\mathcal{C}}_{{\mathbf{x}}_0,\textbf{v}_0,\theta _0}\;:\!=\; \left \{\textbf{y} \in \mathbb R^3 \,|\,0\leqslant \angle (\textbf{y}-{\mathbf{x}}_0,\textbf{v}_0)\leqslant \theta _0\right \}\ (\theta _0 \in (0,\pi/2)) \end{equation}
is a strictly convex conic cone with the apex
${\mathbf{x}}_0$
and an opening angle
$2\theta _0 \in (0,\pi )$
in
$\mathbb R^3$
. Here,
$\textbf v_0$
is referred to be the axis of
$\mathcal{C}_{{\mathbf{x}}_0,\theta _0}$
. Specifically, when
${\mathbf{x}}_0={\mathbf{0}}$
,
$\textbf{v}_0=(0,0,1)^\top$
, we write
$\mathcal{C}_{{\mathbf{x}}_0,\theta _0 }$
as
$\mathcal{C}_{\theta _0}$
. Define the truncated conic cone
$\mathcal{C}^{h}\;:\!=\;\mathcal{C}^{h} _{ {\mathbf{0}}}$
as
\begin{equation} \mathcal{C}^{h}\;:\!=\;\mathcal{C}_{\theta _0}\cap B_{h},\quad \Gamma _h=\partial \mathcal{C}\cap B_h,\quad \Lambda _h=\mathcal{C} \cap \partial B_h, \end{equation}
where
$B_{h}$
is an open ball centred at
${\mathbf{0}}$
with the radius
$h\in \mathbb R_+$
.
Assume that
$\mathcal{K}_{{\mathbf{x}}_0;\textbf e_1,\ldots, \textbf e_\ell }$
is a polyhedral cone with the apex
${\mathbf{x}}_0$
and edges
$\textbf e_j$
(
$j=1,\ldots, \ell$
,
$\ell \geq 3$
. Throughout of this paper, we always suppose that
$ \mathcal{K}_{{\mathbf{x}}_0;\textbf e_1,\ldots, \textbf e_\ell }$
is strictly convex, which implies that it can be fitted into a conic cone
$\mathcal{C}_{{\mathbf{x}}_0, \theta _0}$
with the opening angle
$\theta _0\in (0,\pi/2)$
, where
$\mathcal{C}_{{\mathbf{x}}_0, \theta _0}$
is defined in (4.1). Without loss of generality, we assume that the axis of
$\mathcal{C}_{{\mathbf{x}}_0, \theta _0}$
coincides with
$x_3^+$
and
${\mathbf{x}}_0={\mathbf{0}}$
. Given a constant
$h\in \mathbb R_+$
, we define the truncated polyhedral corner
$\mathcal{K}_{{\mathbf{x}}_0}^{h}$
as
\begin{equation} \mathcal{K}_{{\mathbf{x}}_{0}^{h}}=\mathcal{K}_{{\mathbf{x}}_{0};{\textbf{e}_{1}},\ldots{\textbf{e}_{\ell} }}\cap B_{h}. \end{equation}
For convenience, we have a similar geometry setup with (4.2) as
\begin{equation} \mathcal{K}^h=\mathcal{K}_{{\mathbf{0}}}^h,\ \Gamma _h=\partial \mathcal{K}\cap B_h, \ \Lambda _h=\mathcal{K}\cap \partial B_h. \end{equation}
The following theorem states that the transmission eigenfunctions to (1.1) must vanish at a conic corner if they have
$H^1$
regularity and
$v$
can be approximated by a sequence of Herglotz wave functions near the underlying conic corner with certain properties, where the detailed proof is postponed to Subsection 4.1.
Theorem 4.1.
Let
$\Omega$
be a bounded Lipschitz domain with a connected complement and
$v,w\in H^1(\Omega )$
be a pair of transmission eigenfunctions to (
1.1
) associated with
$k\in \mathbb R_+$
. Assume that
${\mathbf{0}}\in \Gamma \subset \partial \Omega$
such that
$\Omega \cap B_h=\mathcal{C}\cap B_h=\mathcal{C}^h$
, where
$\mathcal{C}$
is defined by (
4.1
) and
$h\in \mathbb R_+$
is sufficient small such that
$q\in H^2( \overline{\mathcal{C}^h})$
and
$\eta \in C^{\alpha _1} (\overline{\Gamma _h})$
, where
$\alpha _1\in (0,1)$
. If the following conditions are fulfilled:
-
(a) for any given positive constants
$\beta$
and
$\gamma$
satisfying
(4.5)the transmission eigenfunction
\begin{equation} \gamma \lt \frac{10}{11 }\alpha \beta,\quad \alpha =\min \{\alpha _1,1/2 \}, \end{equation}
$v$
can be approximated in
$H^1(\mathcal{C}^h)$
by Herglotz functions
(4.6)with the kernels
\begin{equation} v_j=\int _{\mathbb S^2}e^{\mathrm{i}k\xi \cdot {\mathbf{x}}}g_j(\xi )\mathrm{d}\xi,\quad \xi \in \mathbb S^2, j=1,2,\cdots, \end{equation}
$g_j$
satisfying the approximation property
(4.7)
\begin{equation} \|v-v_j\|_{H^1(\mathcal{C}^h)}\leq j^{-\beta },\quad \|g_j\|_{L^2(\mathcal{C}^h)}\leq j^\gamma ; \end{equation}
-
(b) the function
$\eta$
does not vanish at the apex
${\mathbf{0}}$
of
$\mathcal{C}^h$
;
then one has
\begin{equation} \lim _{\lambda \to \infty }\frac{1}{m(B({\mathbf{0}},\lambda )\cap \Omega )}\int _{B({\mathbf{0}},\lambda )\cap \Omega }\vert v({\mathbf{x}})\vert \mathrm{d} {\mathbf{x}}=0, \end{equation}
where
$m(B({\mathbf{0}},\lambda )\cap \Omega )$
is the area of
$B({\mathbf{0}},\lambda )\cap \Omega$
.
As remarked earlier, the Herglotz approximation property in (4.7) characterizes a regularity of
$v$
weaker than the Hölder continuity (cf. [Reference Liu and Tsou41]). In the following theorem, if a stronger Hölder regularity condition near a conic corner on the transmission eigenfunction
$v$
to (1.1) is satisfied, we also have the vanishing characterization of the corresponding transmission eigenfunction
$v$
. Namely, when
$v$
is Hölder continuous near the underlying circular corner, we show that it must vanish at the apex of the conic corner. The proof can be obtained by modifying the corresponding proof of Theorem 4.1 directly as for the two-dimensional case, which is omitted.
Theorem 4.2.
Let
$v\in H^1(\Omega )$
and
$w\in H^{1}(\Omega )$
be a pair of transmission eigenfunctions to (1.1) associated with
$k\in \mathbb R_+$
. Assume that the Lipschitz domain
$\Omega \subset \mathbb R^3$
with
${\mathbf{0}} \in \partial \Omega$
contains a conic corner
$\Omega \cap B_h=\mathcal{C}\cap B_h=\mathcal{C}^h$
, such that
$v\in C^{\alpha }(\overline{\mathcal{C}^h})$
,
$q\in H^2(\overline{\mathcal{C}^h})$
and
$\eta \in C^\alpha (\overline{\Gamma _h})$
for
$0\lt \alpha \lt 1$
, where
$B_h,\ \Gamma _h$
and
$\mathcal{C}^h$
are defined in (
4.2
). If
$\eta ({\mathbf{0}})\not =0$
, where
${\mathbf{0}}$
is the apex of
$\mathcal{C}^h$
, then one has
\begin{equation} v({\mathbf{0}})=0. \end{equation}
Consider a cuboid corner
$\mathcal{K}_{{\mathbf{x}}_0;\textbf e_1, \textbf e_2, \textbf e_3}$
defined by (4.3). In Theorem 4.3, we show that the transmission eigenfunctions to (1.1) vanish at the cuboid corner
$\mathcal{K}_{{\mathbf{x}}_0;\textbf e_1, \textbf e_2, \textbf e_3}$
when they are Hölder continuous at the corner point. The proof of Theorem 4.3 can be found in Subsection 4.2. Since
$\Delta$
is invariant under rigid motion, we assume that the apex
${\mathbf{x}}_0$
of
$\mathcal{K}_{{\mathbf{x}}_0;\textbf e_1, \textbf e_2, \textbf e_3}$
coincides with the origin, and the edges of
$\mathcal{K}_{{\mathbf{x}}_0;\textbf e_1, \textbf e_2, \textbf e_3}$
satisfy
$\textbf e_1=(1,0,0)^\top$
,
$\textbf e_2=(0,1,0)^\top$
and
$\textbf e_3=(0,0,1)^\top$
.
Theorem 4.3.
Let
$v\in H^1{(\Omega }),\ w\in H^1{(\Omega )}$
be a pair of transmission eigenfunctions of (1.1) with
$k\gt 0$
. Assume that Lipschitz domain
$\Omega \subset \mathbb R^3$
with
${\mathbf{0}} \in \Gamma \subset \partial \Omega$
contains a cuboid corner
$\Omega \cap B_h =\mathcal{K} \cap B_h =\mathcal{K}^h,$
such that
$v\in C^\alpha (\overline{\mathcal{K}^h})$
,
$q\in H^2(\overline{\mathcal{K}^h})$
and
$\eta \in C^\alpha (\overline{\Gamma _h})$
for
$0\lt \alpha \lt 1$
, where
$\mathcal{K}^h$
and
$\Gamma _h$
are defined in (4.3). If
$\eta ({\mathbf{0}})\not =0$
, then
\begin{equation*}v(\textbf {0})=0.\end{equation*}
Remark 4.1.
Consider the classical transmission eigenvalue problem (3.9) in
$\mathbb R^3$
, namely
$\eta \equiv 0$
on
$\Gamma$
in (1.1), when the underlying domain
$\Omega$
of (3.9) has a cuboid corner
$\mathcal{K}_{{\mathbf{x}}_0;\textbf e_1, \textbf e_2, \textbf e_3}$
, if the corresponding potential
$q$
has
$\alpha$
-Hölder continuity regularity for
$\alpha \gt \frac{1}{4}$
near the cuboid corner (cf. [Reference Blåsten and Liu9
, Definition 2.2 and Theorem 3.2]), then the transmission eigenfunction
$v$
must vanish near the corner. Compared with the results in [Reference Blåsten and Liu9], the vanishing property of transmission eigenfunctions to (1.1) near the underlying cuboid corner holds under a general scenario. Namely, the assumption in Theorem
4.3
only needs
$q$
fulfils
$H^2$
regularity,
$v$
and boundary parameter
$\eta$
are Hölder continuous near
${\mathbf{x}}_0$
, where
$\eta ({\mathbf{x}}_0) \neq 0$
.
In the following two corollaries, we consider the classical transmission eigenvalue problem (3.9), namely
$\eta \equiv 0$
on
$\Gamma$
in (1.1), where the domain
$\Omega$
contains a conic or polyhedral corner. The proof of Corollary 4.4 is postponed in Subsection 4.3.
Corollary 4.4.
Let
$\Omega$
be a bounded Lipschitz domain with a connected complement and
$v,w\in H^1(\Omega )$
be a pair of transmission eigenfunctions to (3.9) associated with
$k\in \mathbb R_+$
. Assume that
${\mathbf{0}}\in \Gamma \subset \partial \Omega$
such that
$\Omega \cap B_h=\mathcal{C}\cap B_h=\mathcal{C}^h$
, where
$\mathcal{C}$
is defined by (
4.1
) and
$h\in \mathbb R_+$
is sufficient small such that
$q\in H^2( \overline{\mathcal{C}^h})$
and
$q({\mathbf{0}})\neq 1$
.
-
(a) For any given positive constants
$\beta$
and
$\gamma$
satisfying
$ \gamma \lt \frac{20}{37}\alpha \beta,$
if the transmission eigenfunction
$v$
can be approximated in
$H^1(\mathcal{C}^h)$
by Herglotz wave functions
$v_j$
defined by (4.6) with the kernels
$g_j$
satisfying the approximation property (4.7), then we have the vanishing of the transmission eigenfunction
$v$
near
$\mathcal{C}^h$
in the sense of (4.8). -
(b) If
$v\in C^\alpha (\overline{\mathcal{C} ^h})$
with
$\alpha \in (0,1)$
, then one has
$v({\mathbf{0}})=0$
.
In the subsequent corollary, we consider the case that
$\Omega$
contains a polyhedral corner
$\mathcal{K}^{h}$
defined by (4.3). When the transmission eigenfunction
$v$
to (3.9) satisfies two regularity assumptions, we can establish the similar geometrical characterization of
$v$
near the polyhedral corner. The proofs are similar to the counterpart of Theorem 4.2 and Corollary 4.4, where we only need to use the asymptotic analysis [Reference Blåsten, Liu and Xiao10, Lemma 2.2] with respect to the parameter in the corresponding CGO solution introduced in the following subsection. Hence, we omit its proof.
Corollary 4.5.
Let
$\Omega$
be a bounded Lipschitz domain with a connected complement and
$v,w\in H^1(\Omega )$
be a pair of transmission eigenfunctions to (3.9) associated with
$k\in \mathbb R_+$
. Assume that
${\mathbf{0}}\in \Gamma \subset \partial \Omega$
such that
$\Omega \cap B_h=\mathcal{K}_{{\mathbf{0}};\textbf e_1,\cdots,\textbf e_{\ell }}\cap B_{h}=\mathcal{K}^{h}$
, where
$\mathcal{K}^{h}$
is defined by (4.3) and
$h\in \mathbb R_+$
is sufficiently small such that
$q\in H^2( \overline{\mathcal{K}^h})$
and
$q({\mathbf{0}})\neq 1$
.
-
(a) For any given positive constants
$\beta$
and
$\gamma$
satisfying
$\gamma \lt \frac{20}{37}\alpha \beta$
, if the transmission eigenfunction
$v$
can be approximated in
$H^1(\mathcal{C}^h)$
by Herglotz wave functions
$v_j$
defined by (4.6) with the kernels
$g_j$
satisfying the approximation property (4.7), then we have the vanishing property of
$v$
near
$\mathcal{K}^{h}$
in the sense of (4.8). -
(b) If
$v\in C^{\alpha }(\overline{ \mathcal{K}^{h}})$
with
$\alpha \in (0,1)$
, then one has
$v({\mathbf{0}})=0$
.
4.1. Proof of Theorem 4.1
Since the conic cone
$\mathcal{C}$
defined by (4.1) is strictly convex, for any given positive constant
$\zeta$
, we define
$\mathcal{C}_\zeta$
as the open set of
$\mathbb S^2$
which is composed by all unit directions
${\mathbf{d}}\in \mathbb S^2$
satisfying that
\begin{equation} {\mathbf{d}}\cdot \hat{{\mathbf{x}}}\gt \zeta \gt 0,\quad for\ all \ \hat{{\mathbf{x}}}\in \mathcal{C}\cap \mathbb S^2. \end{equation}
Throughout this subsection, we always assume that the unit vector
${\mathbf{d}}$
in the form of the CGO solution
$u_0$
given by (2.2) satisfies (4.10). In order to prove Theorem 4.1, we need several key propositions and lemmas in the following.
Proposition 4.1.
Let
$\Gamma _{h}$
and
$\rho$
be defined in (
4.2
) and (
2.3
), respectively. Then, we have
\begin{equation} \left \vert \int _{\Gamma _{h}} e^{\rho \cdot {\mathbf{x}}}\mathrm{d}\sigma \right \vert \geq \frac{C_{\mathcal{C}^h}}{\tau ^2}-\mathcal{O}\left (\frac{1}{\tau }e^{-\frac{1}{2}\zeta h \tau }\right ), \end{equation}
for sufficiently large
$\tau$
, where
$C_{\mathcal{C}^h}$
is a positive number only depending on the opening angle
$\theta _0$
of
$\mathcal{C}$
and
$\zeta$
.
Proof. Using polar coordinates transformation and the mean value theorem for integrals, we have
\begin{equation} \begin{aligned} \int _{\Gamma _h}e^{\rho \cdot {\mathbf{x}}}\mathrm{d}\sigma &=\sin \theta _0\frac{2\pi \Gamma (2)}{\tau ^2}\frac{1}{(({\mathbf{d}}+\mathrm{i}{\mathbf{d}}^{\perp })\cdot \hat{ {\mathbf{x}}}(\theta _0,\varphi _\xi ))^2}-\sin \theta _0\int _{0}^{2\pi }I_{R}\mathrm{d}\varphi, \end{aligned} \end{equation}
where
$I_{R}= \int _{h}^{\infty }e^{-\tau ({\mathbf{d}} +\mathrm{i}{\mathbf{d}})\cdot \hat{{\mathbf{x}}}r}r\mathrm{d} r$
. Furthermore, for sufficiently large
$\tau$
, it is ready to know that
\begin{equation*}\frac {1}{\tau ^2}-\frac {1}{\tau }e^{-\frac {1}{2}\zeta h \tau }\gt 0.\end{equation*}
Hence, by virtue of (4.10) and Proposition 2.1, we have the following integral inequality
\begin{equation*} \begin{aligned} \left \vert \int _{\Gamma _h}e^{\rho \cdot {\mathbf{x}}}\mathrm{d}\sigma \right \vert &\geq \sin \theta _0 \frac{2\pi \Gamma (2)}{\tau ^2}\frac{1}{({\mathbf{d}}\cdot \hat{\textbf x}(\theta _{0},\varphi _{\xi }))^2+({\mathbf{d}}^\perp \cdot \hat{\textbf x}(\theta _{0},\varphi _\xi ))^2}-\sin \theta _0\int _{0}^{2\pi }|I_R|\mathrm{d}\varphi \\[5pt] &\geq \frac{C_{\mathcal{C}^h}}{\tau ^2}-\mathcal{O}(\frac{1}{\tau }e^{-\frac{1}{2}\zeta h \tau }), \end{aligned} \end{equation*}
which completes the proof of this proposition.
Similar to Proposition 3.2, the following proposition can be obtained by direct verifications.
Proposition 4.2.
Let
$\mathcal{C}^h$
be defined by (4.2). For any given
$t\gt 0$
, it yields that
\begin{equation} \begin{aligned} \| e^{\rho \cdot {\mathbf{x}}} \|_{L^t(\mathcal{C}^h)} &\leq C \left (\frac{1}{\tau ^3}+\frac{1}{\tau }e^{-\frac{t}{2}\zeta h\tau }\right )^{\frac{1}{t}},\\[5pt] \| e^{\rho \cdot {\mathbf{x}}} \|_{L^t(\Gamma _h)} &\leq C \left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-\frac{t}{2}\zeta h\tau }\right )^{\frac{1}{t}}, \end{aligned} \end{equation}
as
$\tau \rightarrow \infty$
, where
$\rho$
is defined in (
2.3
) and
$C$
is a positive constant only depending on
$t,\zeta$
.
The proof of the following lemma is similar to 3.1, hence we omit it here.
Lemma 4.1.
Under the same setup of Theorem
4.1
, let the CGO solution
$u_0$
be defined by (
2.2
). We also denote
$u=w-v$
, where
$(v,w)$
is a pair of transmission eigenfunctions of (1.1) associated with
$k \in \mathbb R_+$
. Then, it holds that
\begin{align} \left\{\begin{array}{l@{\quad}l} \Delta u_0 +k^2qu_0=0& \mbox{in}\quad{\mathcal{C}}^h,\\[5pt] \Delta u +k^2qu=k^2(1-q)v & \mbox{in}\quad{\mathcal{C}}^h,\\[5pt] u=0,\quad \partial _{\nu }u=0 & \mbox{on}\quad \Gamma _h, \end{array}\right. \end{align}
where
$\mathcal{C}^h$
and
$\Gamma _h$
are defined by (4.2), and
\begin{equation} \| \psi ({\mathbf{x}}) \|_{H^{1,8}} = \mathcal{O}(\tau ^{-\frac{2}{5}}), \end{equation}
where
$\psi$
and
$\tau$
are defined in (2.2).
Lemma 4.2.
Let
$\Lambda _h$
and
$\mathcal{C}^h$
be defined in (
4.2
). Recall that
$u_0({\mathbf{x}})$
is given by (
2.2
). Then,
$u_0({\mathbf{x}})\in H^1({\mathcal{C}}^h)$
, and it holds that
\begin{align} \|u_0({\mathbf{x}})\|_{L^2(\Lambda _h)}&\lesssim \left (1+\tau ^{-\frac{2}{5}}\right )e^{-\zeta h\tau }, \end{align}
\begin{align} \|\nabla u_0({\mathbf{x}})\|_{L^2(\Lambda _h)}&\lesssim (1+\tau ) \left (1+\tau ^{-\frac{2}{5}}\right )e^{-\zeta h\tau }, \end{align}
\begin{align} \int _{\mathcal{C}^h}\vert {\mathbf{x}}\vert ^{\alpha }\vert u_0({\mathbf{x}})\vert \mathrm{d}{\mathbf{x}} &\lesssim \tau ^{-(\alpha +\frac{121}{40})}+\left (\frac{1}{\tau ^{\alpha +3}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ), \end{align}
\begin{align} \int _{\Gamma _h} \vert {\mathbf{x}}\vert ^\alpha \vert u_0({\mathbf{x}})\vert \mathrm{d} \sigma &\lesssim \tau ^{-(\alpha +\frac{43}{20})}+\left (\frac{1}{\tau ^{\alpha +2}} +\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ) \end{align}
as
$\tau \rightarrow \infty$
, where
$\zeta$
is defined in (3.10) and
$\alpha \in (0,1)$
.
Proof. Using (4.15) and Lemma 3.2 about the trace theorem, it yields that
\begin{equation*} \|\psi ({\mathbf{x}})\|_{L^{4}(\Lambda _h)} \leq C \|\psi ({\mathbf{x}})\|_{H^{\frac{7}{8},8}(\Lambda _h)}\leq C\|\psi ({\mathbf{x}})\|_{H^{1,8}(\mathcal{C}^h)}= O(\tau ^{-\frac{2}{5}}), \end{equation*}
as
$\tau \rightarrow \infty$
. By using polar coordinates transformation, (2.6a) and (4.10), one can derive that
\begin{equation} \|e^{\rho \cdot {\mathbf{x}}}\|_{L^t(\Lambda _h)}\lesssim e^{-\zeta h\tau }, \end{equation}
where
$\rho$
is defined in (2.3) and
$t$
is a positive constant.
Due to polar coordinates transformation, (4.17), (4.15) and Hölder inequality, it can be calculated that
\begin{equation} \begin{aligned} \|u_{0}\|_{ L^{2}(\Lambda _{h})} &\leq \|e^{\rho \cdot {\mathbf{x}}}\|_{ L^{2}(\Lambda _{h})}+\|e^{\rho \cdot {\mathbf{x}}}\|_{ L^{4}(\Lambda _{h})}\|\psi ({\mathbf{x}})\|_{ L^{4}(\Lambda _{h})}\\[5pt] &\lesssim \left (1+\tau ^{-\frac{2}{5}}\right )e^{-\zeta h\tau }, \quad \mbox{as } \tau \rightarrow \infty . \end{aligned} \end{equation}
By virtue of Cauchy-Schwarz inequality, (4.16a) and Proposition 2.1, we can deduce that
\begin{equation} \begin{aligned} \|\nabla u_{0}\|_{L^{2}(\Lambda _{h})} &\leq \sqrt{2}\tau \|u_{0}\|_{ L^{2}(\Lambda _{h})}+\|e^{\rho \cdot {\mathbf{x}}}\|_{ L^{4}(\Lambda _{h})} \|\nabla \psi ({\mathbf{x}})\|_{ L^{4}(\Lambda _{h})}\\[5pt] &\lesssim (1+\tau )(1+\tau ^{-\frac{2}{5}})e^{-\zeta h\tau },\quad \mbox{as $\tau \rightarrow \infty $. } \end{aligned} \end{equation}
It is clear that we can get the following integral inequality,
\begin{equation} \begin{aligned} \int _{\mathcal{C}^h}\vert {\mathbf{x}}\vert ^{\alpha }\vert u_{0} \vert \mathrm{d}{\mathbf{x}} &\leq \int _{\mathcal{C}^h}\vert {\mathbf{x}}\vert ^{\alpha }\vert e^{\rho \cdot {\mathbf{x}}} \vert \mathrm{d}{\mathbf{x}}+\int _{\mathcal{C}^h}(\vert {\mathbf{x}}\vert ^{\alpha }\vert e^{\rho \cdot {\mathbf{x}}}\vert )(\vert \psi ({\mathbf{x}})\vert )\mathrm{d}{\mathbf{x}}. \end{aligned} \end{equation}
By virtue of polar coordinates transformation and Proposition 2.1, it reveals that
\begin{equation} \begin{aligned} \int _{\mathcal{C}^h}\vert {\mathbf{x}}\vert ^{\alpha }e^{-\zeta \tau \vert {\mathbf{x}}\vert }\mathrm{d}{\mathbf{x}} \lesssim \frac{1}{\tau ^{\alpha +3}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }, \end{aligned} \end{equation}
as
$\tau \rightarrow \infty$
. Next, letting
$\textbf{y}=\tau {\mathbf{x}}$
, using Cauchy-Schwarz inequality and H
$\ddot{\mathrm{o}}$
lder inequality, it arrives that
\begin{align} \int _{\mathcal{C}^h}(\vert {\mathbf{x}}\vert ^{\alpha }\vert e^{\rho \cdot {\mathbf{x}}}\vert )(\vert \psi ({\mathbf{x}})\vert )\mathrm{d}{\mathbf{x}} &\leq \frac{1}{\tau ^{\alpha +3}}\int _{\mathcal{C}}\vert \textbf{y}\vert ^\alpha \vert e^{-{\mathbf{d}}\cdot \textbf{y}}\vert \left \vert \psi \left (\frac{\textbf{y}}{\tau }\right )\right \vert \mathrm{d}\textbf{y}\nonumber \\[5pt] &\leq \frac{1}{\tau ^{\alpha +3}}\|\vert \textbf{y}\vert ^\alpha \vert e^{-{\mathbf{d}}\cdot \textbf{y}}\vert \|_{L^{\frac{8}{7}}(\mathcal{C})}\left \|\psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{L^{8}(\mathcal{C})}, \end{align}
as
$\tau \rightarrow \infty$
, using variable substitution and (4.15), it arrives that
\begin{equation} \left \|\psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{L^8(\mathcal{C})} =\tau ^{\frac{3}{8}}\|\psi ({\mathbf{x}})\|_{L^8(\mathcal{C})}\leq \tau ^{\frac{3}{8}}\|\psi ({\mathbf{x}})\|_{H^{1,8}(\mathcal{C})} =\mathcal{O}(\tau ^{-\frac{1}{40}}), \end{equation}
as
$\tau \rightarrow \infty$
. Furthermore, one has
\begin{equation} \|\vert \textbf{y}\vert ^\alpha \vert e^{\rho \cdot {\mathbf{x}}}\vert \|_{L^{\frac{8}{7}}(\mathcal{C})} =\left ( \int _{\mathcal{C}}\vert \textbf{y}\vert ^{\frac{8}{7}\alpha }e^{-\frac{8}{7}{\mathbf{d}}\cdot \textbf{y}}\mathrm{d}\textbf{y}\right )^{\frac{7}{8}} \leq \left ( \int _{\mathcal{C}}\vert \textbf{y}\vert ^{\frac{8}{7}\alpha }e^{-\frac{8}{7}\zeta \vert \textbf{y}\vert }\mathrm{d}\textbf{y} \right )^{\frac{7}{8}}\leq \frac{C}{\zeta ^{3+\frac{8}{7}\alpha }}, \end{equation}
where
$C=2\pi \theta _0 \Gamma (3+\frac{8}{7}\alpha )(\frac{7}{8})^{3+\frac{8}{7}\alpha }$
. Hence,
$\|\vert \textbf{y}\vert ^\alpha \vert e^{\rho \cdot {\mathbf{x}}}\vert \|_{L^{\frac{8}{7}}(\mathcal{C})}$
is a positive constant which only depends on
$\theta _0$
,
$\zeta$
and
$\alpha$
. Combining (4.23), (4.22) and (4.21) with (4.20), one has (4.16c).
Furthermore, we have
\begin{equation} \int _{\Gamma _h}\vert {\mathbf{x}}\vert ^\alpha \vert u_0\vert \mathrm{d} \sigma \leq \int _{\Gamma _h}\vert {\mathbf{x}}\vert \vert e^{\rho \cdot {\mathbf{x}}}\vert \mathrm{d}\sigma +\int _{\Gamma _h}\vert {\mathbf{x}}\vert ^\alpha \vert e^{\rho \cdot {\mathbf{x}}}\vert \vert \psi ({\mathbf{x}})\vert \mathrm{d}\sigma, \end{equation}
and we can easily get (4.26) by using polar coordinates transformation and Proposition 2.1,
\begin{equation} \int _{\Gamma _h}\vert {\mathbf{x}}\vert \vert e^{\rho \cdot {\mathbf{x}}}\vert \mathrm{d}\sigma \lesssim \frac{1}{\tau ^{\alpha +2}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }, \end{equation}
as
$\tau \rightarrow \infty$
. Then letting
$\textbf{y}=\tau {\mathbf{x}}$
and utilizing Hölder inequality, it can be obtained that
\begin{align} \int _{\Gamma _h}\vert {\mathbf{x}}\vert ^\alpha \vert e^{\rho \cdot {\mathbf{x}}}\vert \vert \psi ({\mathbf{x}})\vert \mathrm{d}\sigma &\leq \frac{1}{\tau ^{\alpha +2}}\int _{\partial \mathcal{C}}\vert \textbf{y} \vert ^\alpha \vert e^{-{\mathbf{d}} \cdot \textbf{y}}\vert \left \vert \psi \left (\frac{\textbf{y}}{\tau }\right )\right \vert \mathrm{d} \sigma \nonumber \\[5pt] &\leq \frac{1}{\tau ^{\alpha +2}} \|\vert \textbf{y} \vert ^\alpha \vert e^{-{\mathbf{d}}\cdot \textbf{y}}\vert \|_{L^{\frac{8}{7}}(\partial \mathcal{C})}\left \| \psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{L^8(\partial \mathcal{C})}. \end{align}
Similar to (4.24), we know that
$\|\vert \textbf{y} \vert ^\alpha \vert e^{-{\mathbf{d}}\cdot \textbf{y}}\vert \|_{L^{\frac{8}{7}}(\partial \mathcal{C})}$
is a positive constant. By virtue of variable substitution, trace theorem and (4.15), it arrives that
\begin{equation} \left \| \psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{L^8(\partial \mathcal{C})} \lesssim \tau ^{\frac{1}{4}}\|\psi ({\mathbf{x}})\|_{H^{\frac{7}{8},8}(\partial \mathcal{C})}\lesssim \tau ^{\frac{1}{4}}\|\psi ({\mathbf{x}})\|_{H^{1,8}( \mathcal{C})}\lesssim \tau ^{-\frac{3}{20}}, \end{equation}
as
$\tau \rightarrow \infty$
. Combining (4.26), (4.27) and (4.28) with (4.25), one has (4.16d).
Now, we are in the position to prove Theorem 4.1.
Proof of Theorem
4.1
. The proof of this theorem is similar to the counterpart of Theorem 3.1. Recall that
$(v,w)$
is a pair of transmission eigenfunctions to (1.1). Using Green formula (2.7) and boundary conditions in (4.14), the following integral identity holds
\begin{equation} \int _{\mathcal{C}^h}k^2(q-1)vu_0\mathrm{d}{\mathbf{x}}=\int _{\Lambda _h}(w-v)\partial _\nu u_0-u_0\partial (w-v)\mathrm{d}\sigma -\int _{\Gamma _h}\eta u_0v\mathrm{d}\sigma \end{equation}
where
$\mathcal{C}^h$
,
$\Lambda _h$
and
$\Gamma _h$
are defined by (4.2). Let
\begin{equation*} f_{j}=(q-1)v_j. \end{equation*}
Due to
$q\in H^2{(\overline{\mathcal{C}^h})}$
, we know that
$q\in C^{1/2}(\overline{ \mathcal{C}^h})$
by using the property of embedding of Sobolev space. Recall that
$\eta \in C^{\alpha _1}(\overline{ \Gamma _h})$
. Let
$\alpha =\{ \alpha _1,1/2 \}$
. Furthermore, since the Herglotz wave function
$v_j\in C^{\alpha }(\overline{ \mathcal{C}^h})$
, it yields that
$f_j\in C^\alpha (\overline{\mathcal{C}}^h)$
. Hence, one has the expansion
\begin{equation} \begin{aligned} f_{j}&=f_j({\mathbf{0}})+\delta f_j,\ \vert \delta f_{j}\vert \leq \| f_{j}\|_{C^{\alpha }(\overline{\mathcal{C}^h })}\vert {\mathbf{x}} \vert ^{\alpha },\\[5pt] v_{j}&=v_j({\mathbf{0}})+\delta v_j,\ \vert \delta v_j\vert \leq \| v_j\|_{C^\alpha (\overline{\mathcal{C}^h })}\vert {\mathbf{x}}\vert ^\alpha,\\[5pt] \eta &=\eta ({\mathbf{0}})+\delta \eta,\ \vert \delta \eta \vert \leq \|\eta \|_{C^\alpha (\overline{\Gamma _h})}\vert {\mathbf{x}}\vert ^\alpha . \end{aligned} \end{equation}
By virtue of (4.30), we have the following integral identities
\begin{equation} k^2\int _{\mathcal{C}_h}(q-1)vu_0\mathrm{d}{\mathbf{x}}=-\sum _{m=1}^3I_m,\quad \int _{\Gamma _h}\eta u_0v\mathrm{d}\sigma =I-\sum _{m=4}^9I_m, \end{equation}
where
\begin{equation} \begin{aligned} I_1&=-k^2\int _{\mathcal{C}^h}(q-1)(v-v_j)u_0\mathrm{d}{\mathbf{x}},\quad I_2=-\int _{\mathcal{C}^h}\delta f_j u_0\mathrm{d}{\mathbf{x}},\\[5pt] I_3&=-f_j({\mathbf{0}})\int _{\mathcal{C}^h}u_0\mathrm{d}{\mathbf{x}},\quad I_4=-\eta ({\mathbf{0}})\int _{\Gamma _h}(v-v_j)u_0\mathrm{d} \sigma \\[5pt] I_5&=-\int _{\Gamma _h}\delta \eta (v-v_j)u_0\mathrm{d}\sigma,\quad I_6=-\eta ({\mathbf{0}})v_j({\mathbf{0}})\int _{\Gamma _h}e^{\rho \cdot {\mathbf{x}}}\psi ({\mathbf{x}})\mathrm{d}\sigma, \\[5pt] I_7&=\eta ({\mathbf{0}})\int _{\Gamma _h}\delta v_ju_0\mathrm{d}\sigma,\quad I_8=-v_j({\mathbf{0}})\int _{\Gamma _h}\delta \eta u_0\mathrm{d}\sigma,\\[5pt] I_9&= \int _{\Gamma _h}\delta \eta \delta v_ju_0\mathrm{d}\sigma,\quad I=\eta ({\mathbf{0}})v_j({\mathbf{0}})\int _{\Gamma _h}e^{\rho \cdot {\mathbf{x}}}\mathrm{d}\sigma . \end{aligned} \end{equation}
Substituting (4.31) into (4.29), it yields that
\begin{equation*} I=\sum _{m=1}^9I_m+J_1+J_2, \end{equation*}
where
\begin{equation} J_1=\int _{\Lambda _{h}}u_{0}\partial _{\nu }(w-v)\mathrm{d}\sigma,\quad J_2=-\int _{\Lambda _{h}}(w-v)\partial _{\nu }u_{0}\mathrm{d}\sigma . \end{equation}
Hence, it readily yields that
\begin{equation} \vert I\vert \leq \sum _{m=1}^9\vert I_m\vert +\vert J_1\vert +\vert J_2\vert . \end{equation}
In the sequel, we derive the asymptotic estimates of
$I_j$
$(j=1,\ldots,9)$
and
$J_j,\ j=1,2$
with respect to the parameter
$\tau$
in the CGO solution
$u_0$
when
$\tau \rightarrow \infty$
, separately. Using Hölder inequality, Proposition 4.2 and (4.15), it is clear that
\begin{equation} \begin{aligned} \vert I_1\vert &\leq \|v-v_j\|_{L^2(\mathcal{C}^h)}\|e^{\rho \cdot {\mathbf{x}}}\|_{L^2(\mathcal{C}^h)}+\|v-v_j\|_{L^2(\mathcal{C}^h)}\|e^{\rho \cdot {\mathbf{x}}}\psi ({\mathbf{x}})\|_{L^2(\mathcal{C}^h)}\\[5pt] &\lesssim j^{-\beta }\left [\left (\frac{1}{\tau ^3}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau ^3}+\frac{1}{\tau }e^{-2\zeta h\tau }\right )^{\frac{1}{4}}\tau ^{-\frac{2}{5}} \right ], \end{aligned} \end{equation}
as
$\tau \rightarrow \infty$
.
With the help of (4.30), we have
\begin{equation} \vert I_{2} \vert \leq k^{2}\|f_{j} \|_{C^{\alpha }}\int _{\mathcal{C}^h}\vert {\mathbf{x}}\vert ^{\alpha }\vert u_{0} \vert \mathrm{d}{\mathbf{x}}, \end{equation}
and
\begin{equation} \begin{aligned} \|f_{j}\|_{C^{\alpha }(\mathcal{C}^h )}& \leq \|q\|_{C^{\alpha }(\mathcal{C}^h )}\sup _{\mathcal{C}^h }\vert v_{j}\vert +\|v_{j}\|_{C^{\alpha }(\mathcal{C}^h )}\sup _{\mathcal{C}^h }\vert q-1\vert . \end{aligned} \end{equation}
Moreover, due to the property of compact embedding of Hölder spaces, one has
\begin{equation} \| v_{j}\|_{C^{\alpha }(\mathcal{C}^h )}\leq \mathrm{ diam}\left (\mathcal{C}^h\right )^{1-\alpha }\|v_{j}\|_{C^{1}(\mathcal{C}^h )}, \end{equation}
where diam(
$\mathcal{C}^h$
) is the diameter of
$\mathcal{C}^h$
. It can be directly shown that
\begin{equation} \|v_{j}\|_{C^{1}(\mathcal{C}^h )}\leq 4\sqrt{\pi }(1+k)\|g\|_{L^{2}(\mathbb S^{2})}. \end{equation}
On the other hand, we can obtain the following estimate by using the Cauchy-Schwarz inequality,
\begin{equation} \vert v_{j}\vert \leq 4\sqrt{\pi }\|g\|_{L^{2}(\mathbb S^{2})}. \end{equation}
Using (4.7) and
$q\in C^{\alpha }(\overline{\mathcal{C}^h})$
, plugging (4.7), (4.38), (4.39) and (4.40) into (4.37), one can arrive at
\begin{equation} \|f_{j}\|_{C^{\alpha }(\mathcal{C}^h)}\lesssim j^{\gamma }, \end{equation}
where
$\gamma$
is a given positive constant defined in (4.7). Substituting (4.16c) and (4.41) into (4.36), we obtain
\begin{equation} \vert I_{2} \vert \lesssim j^{\gamma }\left [\tau ^{-(\alpha +\frac{121}{40})}+\left (\frac{1}{\tau ^{\alpha +3}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )\right ] \end{equation}
as
$\tau \to \infty$
.
With the help of Cauchy-Schwarz inequality and (4.7), it yields that
\begin{equation} \vert I_{3} \vert \leq \int _{\mathcal{C}^h} \vert e^{\rho \cdot {\mathbf{x}}}\vert \mathrm{d}{\mathbf{x}}+\int _{\mathcal{C}}\vert e^{\rho \cdot {\mathbf{x}}}\vert \vert \psi ({\mathbf{x}})\vert \mathrm{d}{\mathbf{x}}, \end{equation}
Similar to (4.24), we have that
${\|e^{-{\mathbf{d}}\cdot \textbf{y}}\|}_{L^{\frac{8}{7}}(\mathcal{C})}$
is a positive constant depending only on
$\zeta$
and
$\theta _0$
. Letting
$\textbf{y}=\tau {\mathbf{x}}$
and using (4.23), it can be calculated that
\begin{equation} \begin{aligned} \int _{\mathcal{C}}\vert e^{\rho \cdot {\mathbf{x}}}\vert \vert \psi ({\mathbf{x}})\vert \mathrm{d}{\mathbf{x}} \leq \frac{1}{\tau ^3}\|e^{-{\mathbf{d}}\cdot \textbf{y}}\|_{L^{\frac{8}{7}}(\mathcal{C})}\left \|\psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{L^8(\mathcal{C})} \lesssim \tau ^{-\frac{121}{40}}, \end{aligned} \end{equation}
as
$\tau \rightarrow \infty$
. Therefore, with the help of Proposition 4.2, and plugging (4.44) into (4.43), one has
\begin{equation} \vert I_{3} \vert \lesssim \tau ^{-\frac{121}{40}}+\left (\frac{1}{\tau ^3}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ),\quad \mbox{ as } \tau \rightarrow \infty . \end{equation}
By virtue of Cauchy-Schwarz inequality and Lemma 3.2, we can obtain that
\begin{equation} \begin{aligned} \vert I_4 \vert &\lesssim \|v-v_j\|_{L^{2}(\Gamma _h)}\|e^{\rho \cdot {\mathbf{x}}}\|_{L^2(\Gamma _h)}+\|v-v_j\|_{L^2(\Gamma _h)}\|e^{\rho \cdot {\mathbf{x}}}\|_{L^4(\Gamma _h)}\|\psi ({\mathbf{x}} )\|_{L^4(\Gamma _h)}\\[5pt] &\lesssim j^{-\beta }\left [\left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-2\zeta h\tau }\right )^{\frac{1}{4}}\tau ^{-\frac{2}{5}}\right ] \end{aligned} \end{equation}
as
$\tau \to \infty$
.
With the help of Cauchy-Schwarz inequality, Lemma 3.2 and Hölder inequality, one has
\begin{equation} \begin{aligned} \vert I_5\vert &\lesssim \|v-v_j\|_{L^2(\Gamma _h)}(\| \vert e^{\rho \cdot {\mathbf{x}}}\vert \vert {\mathbf{x}}\vert ^\alpha \|_{L^2(\Gamma _h)}+\|\vert e^{\rho \cdot {\mathbf{x}}}\vert \vert {\mathbf{x}}\vert ^\alpha \|_{L^4(\Gamma _h)}\|\psi ({\mathbf{x}})\|_{L^{4}(\Gamma _h)})\\[5pt] &\lesssim j^{-\beta }\left [\left (\frac{1}{\tau ^{(2\alpha +2)}}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau ^{(4\alpha +2)}}+\frac{1}{\tau }e^{-2\zeta h\tau }\right )^{\frac{1}{4}}\tau ^{-\frac{2}{5}}\right ], \end{aligned} \end{equation}
as
$\tau \rightarrow \infty$
.
Similar to (3.19), it can be directly obtained that
\begin{equation} \left \| \psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{H^{1,8}(\mathcal{C})}\leq \tau ^{\frac{3}{8}}\|\psi ({\mathbf{x}})\|_{H^{1,8}(\mathcal{C})}=\mathcal{O}(\tau ^{-\frac{1}{40}}), \end{equation}
as
$\tau \rightarrow \infty$
. Therefore, following the proof of Lemma 3.3 and using Hölder inequality and Lemma 3.2, we have
\begin{equation} \begin{aligned} \vert I_6\vert & \lesssim \frac{1}{\tau ^2}\|e^{-{\mathbf{d}}\cdot \textbf{y}}\|_{L^{\frac{8}{7}}(\Gamma )}\left \|\psi \left (\frac{\textbf{y}}{\tau }\right )\right \|_{L^8(\Gamma )}\\[5pt] &\lesssim \frac{1}{\tau ^2} \|e^{-{\mathbf{d}}\cdot \textbf{y}}\|_{L^{\frac{8}{7}}(\Gamma )} \tau ^{\frac{3}{8}}\|\psi ({\mathbf{x}})\|_{H^{1,8}(\mathcal{C})} \lesssim \tau ^{-\frac{81}{40}}, \quad \mbox{as $\tau \rightarrow \infty $. } \end{aligned} \end{equation}
Moreover, we have the following estimates for
$I_7,\ I_8$
and
$I_9$
by virtue of (4.16d) directly,
\begin{align} \vert I_7\vert &\lesssim \|v_j\|_{C^\alpha (\Gamma _h)}\int _{\Gamma _h}\vert {\mathbf{x}}\vert ^\alpha \vert u_0\vert \mathrm{d}\sigma \lesssim j^\gamma \left [ \tau ^{-(\alpha +\frac{43}{20})}+\left (\frac{1}{\tau ^{\alpha +2}} +\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ) \right ], \nonumber \\[5pt] \vert I_8\vert & \lesssim \tau ^{-(\alpha +\frac{43}{20})}+\left (\frac{1}{\tau ^{\alpha +2}} +\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ),\nonumber \\[5pt] \vert I_9\vert &\lesssim j^\gamma \left [ \tau ^{-(2\alpha +\frac{43}{20})}+\left (\frac{1}{\tau ^{2\alpha +2}} +\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )\right ],\quad \mbox{as $\tau \rightarrow \infty $. } \end{align}
Using Cauchy-Schwarz inequality and Lemma 3.2, we obtain that
\begin{equation} \begin{aligned} \vert J_1 \vert &\leq \|u_{0}\|_{H^{\frac{1}{2}}(\Lambda _{h})} \|\partial _{\nu }(w-v)\|_{H^{-\frac{1}{2}}(\Lambda _{h})} \leq C\|u_{0}\|_{H^{1}(\Lambda _{h})} \|\partial _{\nu }(w-v)\|_{H^{1}(\Lambda _{h})}\\[5pt] &\lesssim \|u_{0}\|_{H^{1}(\Lambda _{h})} \end{aligned} \end{equation}
as
$\tau \to \infty$
, where
$C$
is a positive constant arising from the trace theorem. By virtue of (4.16a) and (4.16b), it can be calculated that
\begin{equation} \begin{aligned} \vert J_1 \vert \lesssim (1+\tau )(1+\tau ^{-\frac{2}{5}})e^{-\zeta h\tau } \end{aligned} \end{equation}
as
$\tau \to \infty$
, where
$\zeta$
is a positive constant given in (4.10). Finally, using Cauchy-Schwarz inequality, the trace theorem and (4.16b), we can obtain that
\begin{equation} \begin{aligned} \vert J_2 \vert &\leq \|\partial _{\nu } u_0\|_{ L^{2}(\Lambda _{h})} \|w-v\|_{ L^{2}(\Lambda _{h})} \leq C\|\partial _{\nu } u_0\|_{ L^{2}(\Lambda _{h})} \|w-v\|_{ H^{1}(\mathcal{C}^h)}\\[5pt] &\lesssim (1+\tau )(1+\tau ^{-\frac{2}{5}})e^{-\zeta h\tau }, \end{aligned} \end{equation}
as
$\tau \rightarrow \infty$
.
Substituting (4.35), (4.42), (4.45)
$-$
(4.50), (4.52) and (4.53) into (4.34), we have
\begin{align} \vert \eta ({\mathbf{0}})v_j({\mathbf{0}})\vert &\left (\frac{C_{\mathcal{C}^h}}{\tau ^2}-\frac{1}{\tau }e^{-\frac{1}{2}\zeta h \tau }\right ) \lesssim j^{-\beta }\left [\left (\frac{1}{\tau ^3}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau ^3}+\frac{1}{\tau }e^{-4\zeta h\tau }\right )^{\frac{1}{4}}\tau ^{-\frac{2}{5}} \right ]\nonumber \\[5pt] & +j^{\gamma }\left [\tau ^{-(\alpha +\frac{121}{40})}+\left (\frac{1}{\tau ^{\alpha +3}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )\right ]\nonumber \\[5pt] & +j^{-\beta }\left [\left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau ^2}+\frac{1}{\tau }e^{-2\zeta h\tau }\right )^{\frac{1}{4}}\tau ^{-\frac{2}{5}}\right ]\nonumber \\[5pt] & +j^{-\beta }\left [\left (\frac{1}{\tau ^{(2\alpha +2)}}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau ^{(4\alpha +2)}}+\frac{1}{\tau }e^{-2\zeta h\tau }\right )^{\frac{1}{4}}\tau ^{-\frac{2}{5}}\right ]\nonumber \\[5pt] & +(j^\gamma +1)\left [ \tau ^{-(\alpha +\frac{43}{20})}+\left (\frac{1}{\tau ^{\alpha +2}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ) \right ]\nonumber \\[5pt] & +j^\gamma \left [\tau ^{-(2\alpha +\frac{43}{20})}+\left (\frac{1}{\tau ^{2\alpha +2}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )\right ]\nonumber \\[5pt] & +\tau ^{-\frac{81}{40}}+\tau ^{-\frac{121}{40}}+\left (\frac{1}{\tau ^3}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ) +(1+\tau )(1+\tau ^{-\frac{2}{5}})e^{-\zeta h\tau } \end{align}
as
$\tau \to \infty$
, where
$C_{\mathcal{C}^h}$
is a positive constant given in (4.11). Moreover, for sufficiently large
$\tau$
, we know that
\begin{equation*}\frac {C_{\mathcal {C}^h}}{\tau ^2}-\frac {1}{\tau }e^{-\frac {1}{2}\zeta h \tau }\gt 0.\end{equation*}
Hence, multiplying
$\tau ^2$
on both sides of (4.54) and taking
$\tau =j^s$
and
$s\gt 0$
, we derive that
\begin{equation} \begin{aligned} \left (C_{\mathcal{C}^h}-j^s e^{-\frac{1}{2}\zeta hj^s}\right )\vert \eta ({\mathbf{0}})v_j({\mathbf{0}})\vert &\lesssim j^{-\beta +\frac{17}{20}s}+j^{\gamma -(\alpha +1)s}+j^{-\beta +\frac{11}{10}s}\\[5pt] &+j^{-\beta +(-\alpha +\frac{11}{10})s} +j^{\gamma -\alpha s}+j^{\gamma -2\alpha s} \end{aligned} \end{equation}
as
$\tau \to \infty$
. Recalling that
$\gamma/\alpha \lt \frac{10}{11}\beta$
, we can choose
$s\in (\gamma/\alpha,\frac{10}{11}\beta )$
. Hence in (4.55), by letting
$j\to \infty$
, we prove that
\begin{equation*}\lim _{j\to \infty }\vert \eta (\textbf {0})v_j(\textbf {0})\vert =0.\end{equation*}
Since
$\eta ({\mathbf{0}})\not =0$
, we have
$\lim _{j\to \infty }\vert v_j({\mathbf{0}}) \vert =0$
. Using (4.6) and integral mean value theorem, we can obtain (4.8).
The proof is complete.
4.2. Proof of Theorem 4.3
In order to prove Theorem 4.3, we first give a crucial estimate in the following proposition. It is pointed out that
$\mathcal{K}$
is a cuboid cone in this subsection, where
${\mathbf{0}}$
is the apex of
$\mathcal{K}$
. Denote
$\textsf{cone}(\textbf a, \textbf b)=\{{\mathbf{x}}\in \mathbb R^3\,|\,{\mathbf{x}}=c_1\textbf a+c_2\textbf b,\, \forall c_i\geq 0,\ i=1,2\}$
, where
$\textbf a$
and
$\textbf b$
are fixed vectors. Let
$\textbf e_1=(1,0,0)^\top$
,
$\textbf e_2=(0,1,0)^\top$
and
$\textbf e_3=(0,0,1)^\top$
. Suppose that the faces
$\partial \mathcal{K}=\cup _{i=1}^3\partial \mathcal{K}_i$
, where
$ \mathcal{K}_1=\textsf{cone}(\textbf e_1, \textbf e_3)$
,
$ \mathcal{K}_1=\textsf{cone}(\textbf e_1, \textbf e_2)$
and
$ \mathcal{K}_1={\textsf{cone}}(\textbf e_2, \textbf e_3)$
.
Proposition 4.3.
Let
${\mathbf{d}}=(1,1,1)^\top$
and
${\mathbf{d}}^\perp =(1,-1,0)^\top$
. Denote
$z_j=\rho _1 \cdot \hat{{\mathbf{x}}}_j(\theta _\xi )$
, where
\begin{equation} \hat{{\mathbf{x}}}_1(\theta _\xi )=\begin{bmatrix} 0\\[5pt] \sin \theta _\xi \\[5pt] \cos \theta _\xi \end{bmatrix},\quad \hat{{\mathbf{x}}}_2(\theta _\xi )=\begin{bmatrix} \sin \theta _\xi \\[5pt] 0 \\[5pt] \cos \theta _\xi \end{bmatrix},\quad \hat{{\mathbf{x}}}_3(\theta _\xi )=\begin{bmatrix} \cos \theta _\xi \\[5pt] \sin \theta _\xi \\[5pt] 0 \end{bmatrix} \end{equation}
with a fixed
$\theta _\xi \in (0,\pi/2)$
, and
$\rho _1={\mathbf{d}} +\mathrm{i} {\mathbf{d}}^\perp$
. It holds that
\begin{equation} \left | \sum _{j=1}^3 \frac{1}{z_j^2} \right | \geq \frac{\sin ^3\theta _\xi }{30} \gt 0. \end{equation}
Proof. By direct calculations, we have
\begin{equation} \sum _{j=1}^3 \frac{1}{z_j^2}=\frac{S(\theta _\xi )}{z_1^2},\quad S(\theta _\xi )=1+\left (\frac{z_1}{\bar z_1}\right )^2 +c_1 z_4, \end{equation}
where
\begin{align*} c_1=&\frac{|z_1|^4}{||z_1|^2-\sin \theta _\xi \cos \theta _\xi +\mathrm{i} \cos \theta _\xi (\!\cos \theta _\xi +\sin \theta _\xi )|^4},\\[5pt] z_4=&\left (|z_1|^2-1/2\sin 2\theta _\xi -\mathrm{i} \cos \theta _\xi (\!\cos \theta _\xi +\sin \theta _\xi ) \right )^2. \end{align*}
By noting
$\theta _\xi \in (0,\pi/2)$
, it yields that
$c_1\geq 0.05\sin \theta _\xi$
and
$\Re (z_4) \geq 2 \sin ^2 \theta _\xi$
. Hence according to (4.58), we obtain (4.57).
Proposition 4.4.
Assume that
$\mathcal{K}^h$
is a truncated cuboid. Let
$\Gamma _h=\partial \mathcal{K}^h\cap B_h$
and
$\rho$
be defined in (2.3), where
${\mathbf{d}}=(1,1,1)^\top$
and
${\mathbf{d}}^\perp =(1,-1,0)^\top$
. Then, one has
\begin{equation} \left \vert \int _{\Gamma _h}e^{\rho \cdot {\mathbf{x}}}\mathrm{d} \sigma \right \vert \geq \frac{C^{'}_{\mathcal{K}^h}}{\tau ^2}-\mathcal{O}\!\left(\frac{1}{\tau }e^{-\frac{1}{2}\zeta h \tau }\right), \end{equation}
for sufficiently large
$\tau$
, where
$C^{'}_{\mathcal{K} ^h}$
is a positive number not depending on
$\tau$
.
Proof. Since
$\mathcal{K}$
is a cuboid, by the geometrical setup and notations in this subsection, we have
$\Gamma _h=\Gamma _{h1}\cup \Gamma _{h2}\cup \Gamma _{h3}$
, where
$\Gamma _{h1}\;:\!=\;\partial \mathcal{K}_1\cap B_h,\ \Gamma _{h2}\;:\!=\;\partial \mathcal{K}_2\cap B _h,\ \Gamma _{h3}\;:\!=\;\partial \mathcal{K}_3\cap B_h$
.
According to Proposition 2.1, it can be derived that
\begin{equation*} \begin{aligned} \int _{\Gamma _h}e^{\rho \cdot {\mathbf{x}}} \mathrm{d} \sigma &=\int _{\Gamma _{h1}}e^{\rho \cdot {\mathbf{x}}} \mathrm{d} \sigma +\int _{\Gamma _{h2}}e^{\rho \cdot {\mathbf{x}}} \mathrm{d} \sigma +\int _{\Gamma _{h3}}e^{\rho \cdot {\mathbf{x}}} \mathrm{d} \sigma \\[5pt] &= \frac{1}{2\pi \tau ^2} \sum _{j=1}^3 \frac{1}{(\rho _1\cdot \hat{{\mathbf{x}}}_j(\theta _\xi ))^2} -\mathcal{O}(\frac{1}{\tau }e^{-\frac{1}{2}\zeta h \tau }), \end{aligned} \end{equation*}
where
$\theta _\xi \in (0,\pi/2)$
is fixed. By virtue of Proposition 4.3, we complete the proof.
The proof of Theorem
4.3
. Using the fact that
$f=(q-1)v\in C^\alpha (\overline{\mathcal{K}^h}),\ v\in C^\alpha (\overline{\mathcal{K}^h}),\eta \in C^\alpha (\overline{\Gamma _h})$
, we have the following expansion
\begin{equation} \begin{aligned} f&=f({\mathbf{0}})+\delta f,\quad \vert \delta f \vert \leq \|f\|_{C^\alpha }\vert {\mathbf{x}} \vert ^\alpha,\\[5pt] v&=v({\mathbf{0}})+\delta v,\quad \vert \delta v \vert \leq \|v\|_{C^\alpha }\vert {\mathbf{x}} \vert ^\alpha,\\[5pt] \eta &=\eta ({\mathbf{0}})+\delta \eta, \quad \vert \delta \eta \vert \leq \|\eta \|_{C^\alpha }\vert {\mathbf{x}}\vert ^\alpha . \end{aligned} \end{equation}
Combining the integral identity (4.29) with (4.60), it arrives that
\begin{equation} \eta ({\mathbf{0}})v({\mathbf{0}})\int _{\Gamma _h}e^{\rho \cdot {\mathbf{x}}}\mathrm{d} \sigma =\sum _{i=1}^6 I_i+J_1+J_2, \end{equation}
where
\begin{equation} \begin{aligned} I_1&=f({\mathbf{0}})\int _{\mathcal{K}^h}u_0\mathrm{d}{\mathbf{x}},\quad I_2= \int _{\mathcal{K}^h}\delta f u_0\mathrm{d}{\mathbf{x}},\quad I_3=\eta ({\mathbf{0}})v({\mathbf{0}})\int _{\Gamma _h}\psi ({\mathbf{x}})e^{\rho \cdot {\mathbf{x}}}\mathrm{d}\sigma,\\[5pt] I_4&=\eta ({\mathbf{0}})\int _{\Gamma _h}\delta v u_0\mathrm{d}\sigma,\quad I_5=v({\mathbf{0}})\int _{\Gamma _h}\delta \eta u_0\mathrm{d}\sigma,\quad I_6=\int _{\Gamma _h}\delta \eta \delta v u_0\mathrm{d}\sigma,\\[5pt] J_1&=-\int _{\Lambda _h}(w-v)\partial _{\nu }u_0\mathrm{d}\sigma,\quad J_2=\int _{\Lambda _h}u_0\partial _{\nu }(w-v)\mathrm{d}\sigma . \end{aligned} \end{equation}
There must exist a convex conic cone
$\mathcal{C}$
contains the cuboid cone
$\mathcal{K}$
, namely
$\mathcal{K} \subset \mathcal{C}$
. Hence, by virtue of (4.45) and (4.16d), we have
\begin{equation} \vert I_1\vert \leq \vert f({\mathbf{0}})\vert \int _{\mathcal{K}^h}\vert u_0\vert \mathrm{d}{\mathbf{x}} \leq \vert f({\mathbf{0}})\vert \int _{\mathcal{C}^h}\vert u_0\vert \mathrm{d}{\mathbf{x}} \lesssim \tau ^{-\frac{121}{40}}+\left (\frac{1}{\tau ^3}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ), \end{equation}
and
\begin{equation} \vert I_2\vert \leq \int _{\mathcal{K}^h} \vert \delta f u_0\vert \mathrm{d}{\mathbf{x}} \leq \int _{\mathcal{C}^h} \vert \delta f u_0\vert \mathrm{d}{\mathbf{x}} \lesssim \tau ^{-(\alpha +\frac{43}{20})}+\left (\frac{1}{\tau ^{\alpha +2}} +\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ), \end{equation}
as
$\tau \rightarrow \infty$
.
In view of (4.49), we have
\begin{equation} \vert I_3\vert \lesssim \tau ^{-\frac{81}{40}}. \end{equation}
In addition, by using (4.16d) in Lemma 4.2, we have the following inequalities:
\begin{align} \vert I_4\vert &\lesssim \tau ^{-(\alpha +\frac{43}{20})}+\left (\frac{1}{\tau ^{\alpha +2}} +\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ), \end{align}
\begin{align} \vert I_5 \vert &\lesssim \tau ^{-(\alpha +\frac{43}{20})}+\left (\frac{1}{\tau ^{\alpha +2}} +\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ), \end{align}
\begin{align} \vert I_6\vert &\lesssim \tau ^{-(2\alpha +\frac{43}{20})}+\left (\frac{1}{\tau ^{2\alpha +2}} +\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ), \end{align}
as
$\tau \rightarrow \infty$
. Moreover, by using (4.52) and (4.53), we have
\begin{equation} \vert J_1 \vert \lesssim (1+\tau )(1+\tau ^{-\frac{2}{5}})e^{-\zeta h\tau } \end{equation}
and
\begin{equation} \vert J_2 \vert \lesssim (1+\tau )(1+\tau ^{-\frac{2}{5}})e^{-\zeta h\tau }. \end{equation}
as
$\tau \rightarrow \infty$
. Let
$\rho$
be defined in (2.3) with
${\mathbf{d}}=(1,1,1)^\top$
and
${\mathbf{d}}^\perp =(1,-1,0)^\top$
. By Proposition 4.4, one has (4.59). Plugging (4.63)-(4.70) and (4.59) into (4.61), it arrives that
\begin{equation} \begin{aligned} \vert \eta ({\mathbf{0}}) v({\mathbf{0}})\vert &\left (\frac{C^{'}_{\mathcal{K}^h}}{\tau ^2}-\frac{1}{\tau }e^{-\frac{1}{2}\zeta h \tau }\right ) \lesssim \tau ^{-\frac{121}{40}}+\left (\frac{1}{\tau ^3}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ) +\tau ^{-(\alpha +\frac{43}{20})}\\[5pt] &+\left (\frac{1}{\tau ^{\alpha +2}} +\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ) +\tau ^{-\frac{81}{40}} +\tau ^{-(\alpha +\frac{43}{20})}+\left (\frac{1}{\tau ^{\alpha +2}} +\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )\\[5pt] &+\tau ^{-(2\alpha +\frac{43}{20})}+\left (\frac{1}{\tau ^{2\alpha +2}} +\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )\\[5pt] &+(1+\tau )(1+\tau ^{-\frac{2}{5}})e^{-\zeta h\tau }, \end{aligned} \end{equation}
where the positive constant
$C^{'}_{\mathcal{K}^h}$
not depending on
$\tau$
is defined in (4.59). Multiplying
$\tau ^2$
on both sides of (4.71) and letting
$\tau \to \infty$
, one has
\begin{equation*}\vert \eta (\textbf {0})v(\textbf {0})\vert =0.\end{equation*}
Due to
$\eta ({\mathbf{0}})\not =0$
, we complete the proof of Theorem 4.3.
4.3. Proof of Corollary 4.4
Due to the proof of Corollary 4.4, (b) can be obtained by adopting the similar process as one of Corollary 4.4 (a); hence, we only give the proof of Corollary 4.4 (a). Firstly, we give the following proposition.
Proposition 4.5 (Reference Diao, Fei, Liu and Yang27, Lemma 2.4). Let
$\mathcal{C}^{h}$
and
$\rho$
be defined in (
4.2
) and (
2.3
), respectively. Then, we have
\begin{equation} \left \vert \int _{\mathcal{C}^{h}} e^{\rho \cdot {\mathbf{x}}}\mathrm{d}{\mathbf{x}}\right \vert \geq \frac{\widetilde{C_{\mathcal{C}^h}}}{\tau ^3}-\mathcal{O}\left (\frac{1}{\tau }e^{-\frac{1}{2}\zeta h \tau }\right ), \end{equation}
for sufficiently large
$\tau$
, where
$\widetilde{C_{\mathcal{C}^h}}$
is a positive number only depending on the opening angle
$\theta _0$
of
$\mathcal{C}$
and
$\zeta$
.
Proof of Corollary 4.4 (a). The following integral identity can be obtained according to (4.29):
\begin{equation} k^2f_j({\mathbf{0}})\int _{\mathcal{C}^h}e^{\rho \cdot {\mathbf{x}}}=I_1+I_2+I_3+J_1+J_2, \end{equation}
where
$I_m,\ m=1,2,3$
,
$J_1$
and
$J_2$
defined in (4.32).
With the help of (4.35), (4.42), (4.45), (4.52) and Proposition 4.5, we have the following integral inequality
\begin{equation} \begin{aligned} k^2\left [\frac{\widetilde{C_{\mathcal{C}^h}}}{\tau ^3}-\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right ]&\vert f_j({\mathbf{0}})\vert \lesssim j^{-\beta }\left [\left (\frac{1}{\tau ^3}+\frac{1}{\tau }e^{-\zeta h\tau }\right )^{\frac{1}{2}}+\left (\frac{1}{\tau ^3}+\frac{1}{\tau }e^{-2\zeta h\tau }\right )^{\frac{1}{4}}\tau ^{-\frac{2}{5}} \right ]\\[5pt] &+j^{\gamma }\left [\tau ^{-(\alpha +\frac{121}{40})}+\left (\frac{1}{\tau ^{\alpha +3}}+\frac{1}{\tau }e^{-\frac{1}{2}\zeta h\tau }\right )\right ]\\[5pt] &+\tau ^{-\frac{121}{40}}+(1+\tau )(1+\tau ^{-\frac{2}{5}})e^{-\zeta h\tau } \end{aligned} \end{equation}
as
$\tau \to \infty$
. For sufficiently large
$\tau$
, we know that
\begin{equation*} \frac {\widetilde {C_{\mathcal {C}^h}}}{\tau ^3}-\frac {1}{\tau }e^{-\frac {1}{2}\zeta h\tau }\gt 0.\end{equation*}
Then, multiplying
$\tau ^3$
in the both sides of (4.74) and letting
$\tau \to \infty$
and
$\tau =j^s$
, one has
\begin{equation} k^2\widetilde{C_{\mathcal{C}^h}}\vert f_j({\mathbf{0}})\vert \lesssim j^{-\beta +\frac{37}{20}s}+j^{\gamma -\alpha s}. \end{equation}
Due to the assumption that
$\gamma \lt \frac{20}{37}\alpha \beta$
, we choose
$s\in (\gamma/\alpha, \frac{20}{37}\beta )$
. By letting
$j\to \infty$
, we have
\begin{equation*}\vert f_j(\textbf {0})\vert =0.\end{equation*}
Since
$q({\mathbf{0}})\neq 1$
, the proof of this corollary is complete.
5. Visibility and unique recovery results for the inverse scattering problem
In this section, we show that when a medium scatter with a conductive transmission boundary condition possesses either one of a convex planar corner, a convex polyhedral corner, or a convex conic corner, it radiates a non-trivial far-field pattern, namely the visibility of this scatterer occurs. Furthermore, when the medium scatter is visible, it can be uniquely determined by a single far-field measurement under generic physical scenarios.
In the following theorem, it indicates that a conductive medium possesses an aforementioned corner under generic physical conditions always scatters.
Theorem 5.1.
Consider the conductive medium scattering problems (1.3). Let
$(\Omega ;\; q,\eta )$
be the medium scatterer associated with (1.3), where
$\Omega$
is a bounded Lipschitz domain with a connected complement in
$\mathbb R^n$
,
$n=2,3$
. If either of the following conditions is fulfilled, namely,
-
(a) when
$\Omega \Subset \mathbb R^2$
, there exists a sufficient small
$h\in \mathbb R_+$
such that
$\Omega \cap B_h=S_h$
, where
$S_h$
is defined by (3.1),
$q\in H^2(\overline{S_h} )$
,
$\eta \in C^\alpha (\overline{\Gamma _h^\pm } )$
satisfying
$\alpha \in (0,1)$
and
$\eta ({\mathbf{0}}) \neq 0$
, and
$\ \Gamma _h^\pm =\partial S_h\setminus \partial B_h$
; -
(b) when
$\Omega \Subset \mathbb R^3$
, there exists a sufficient small
$h\in \mathbb R_+$
such that
$\Omega \cap B_h=\mathcal{K}^h$
, where
$\mathcal{K}^h$
is a cuboid defined by (4.4),
$q\in H^2(\overline{\mathcal{K}^h} )$
,
$\eta \in C^\alpha (\overline{\Gamma _h } )$
satisfying
$\alpha \in (0,1)$
and
$\eta ({\mathbf{0}}) \neq 0$
, and
$\ \Gamma _h =\partial \mathcal{K}^h\setminus \partial B_h$
; -
(c) when
$\Omega \Subset \mathbb R^3$
, there exists a sufficient small
$h\in \mathbb R_+$
such that
$\Omega \cap B_h=\mathcal{K}^h$
, where
$\mathcal{K}^h$
is a polyhedral corner but not a cuboid, then
$q \in H^2(\overline{\mathcal{K}^h})$
satisfying
$q({\mathbf{0}})\not =1$
and
$\eta \equiv 0$
on
$ \partial{\mathcal{K}^h}\setminus \partial B_h$
; -
(d) when
$\Omega \Subset \mathbb R^3$
, there exists a sufficient small
$h\in \mathbb R_+$
such that
$\Omega \cap B_h=\mathcal{C}^h$
, where
$\mathcal{C}^h$
is defined by (4.1),
$q\in H^2(\overline{\mathcal{C}^h} )$
,
$\eta \in C^\alpha (\overline{\Gamma _h } )$
satisfying
$\alpha \in (0,1)$
,
$\eta ({\mathbf{0}}) \neq 0$
and
$\ \Gamma _h =\partial \mathcal{C}^h\setminus \partial B_h$
;
then
$\Omega$
always scatters for any incident wave satisfying (1.2).
Proof. By contradiction, suppose that the mediums scatterer
$\Omega$
possesses either one of a convex planar corner, a convex polyhedral corner and a convex conic corner, where the assumptions (a)-(d) are fulfilled. Assume that
$\Omega$
is non-radiating, namely the far-field pattern
$u^\infty \equiv 0$
. By virtue of Rellich lemma, the total wave field
$u$
and incident wave
$u^i$
satisfies (1.1) associated with the incident wave number
$k$
. It is clear that the incident
$u^i$
is
$\alpha$
-Hölder continuous and non-vanishing near the underlying corner. According to Corollaries 3.3 and 4.5, Theorems 4.2 and 4.3, one has
$u^i$
must vanish at the corresponding corner point, where we get the contradiction.
The proof is complete.
In the following, we shall study the unique recovery for the inverse problem (1.4) associated with the conductive scattering problem (1.3) in
$\mathbb R^3$
. In the field of inverse scattering problems, it is concerned with the shape determination of
$\Omega$
by a minimum far-field measurement (cf. [Reference Colton and Kress22]). We utilize the local geometrical characterization of transmission eigenfunctions near a corner in Section 4 to establish the uniqueness regarding the shape determination of (1.4) by a single measurement under generic physical scenario, where a single far-field measurement means that the underlying far-field pattern is generated only by a single incident wave
$u^i$
. The unique determination results of (1.4) for recovering the material parameters associated with (1.3) by infinitely many far-field measurements with a fixed frequency can be found in [Reference Bondarenko, Harris and Kleefeld14, Reference Bondarenko and Liu15, Reference Harris and Kleefeld36, Reference Harris and Kleefeld37]. We obtain local unique recovery results for the determination of
$\Omega$
without a-prior knowledge on the material parameters
$q$
and
$\eta$
in this section. When
$\Omega$
is a cuboid or a corona shape scatterer with a conductive transmission boundary condition, the corresponding global uniqueness results on the shape determination can be drawn under generic physical scenarios. It is pointed out that when
$\eta \equiv 0$
on
$\partial \Omega$
, namely consider the inverse problem (1.4) associated with the corresponding scattering problem
\begin{equation} \left\{\begin{array}{l@{\quad}l} \Delta u^-+k^2qu^-=0 & \mbox{in}\quad \Omega,\\[5pt] \Delta u^++k^2u^+=0 & \mbox{in}\quad \mathbb R^n\setminus \Omega,\\[5pt] u^+=u^-,\quad \partial _\nu u^+=\partial _\nu u^-, & \mbox{on} \quad \partial \Omega,\\[5pt] u^+=u^i+u^s, & \mbox{in}\quad \mathbb R^n,\\[5pt] \lim _{r\to \infty }r^{(n-1)/2}(\partial _ru^s-iku^s)=0, & r=\vert {\mathbf{x}}\vert, \end{array}\right. \end{equation}
we can establish global unique recovery results for the shape of
$\Omega$
within convex polyhedral or corona geometries by a single far-field measurement, whereas the corresponding single measurement uniqueness result regarding the shape determination of a convex polygonal or cuboid shape associated with (5.1) was studied in [Reference Hu, Salo and Vesalainen38].
In Theorem 5.2, we show the local uniqueness results for (1.4), which aims to recover a scatterer
$(\Omega ;\; q,\eta )$
by knowledge of the far-field pattern
$u^\infty (\hat{{\mathbf{x}}};\; u^i)$
with a single measurement. First, let us introduce the admissible class of the conductive scatterer and the related notations in our study.
Definition 5.1.
Let
$\Omega$
be a bounded Lipschitz domain in
$\mathbb R^3$
with a connected complement and
$(\Omega ;\; k,{\mathbf{d}},q,\eta )$
be a conductive scatterer with the incident plane wave
$u^i=e^{ik{\mathbf{x}}\cdot {\mathbf{d}}}$
, where
${\mathbf{d}}\in \mathbb S^2$
and
$k\in \mathbb R_+$
. Consider the scattering problem (1.3). Denote
$u$
by the total wave field, which is associated with (1.3). The scatterer
$\Omega$
is said to be admissible if the following conditions are fulfilled:
-
(a)
$q\in L^\infty (\Omega )$
and
$\eta \in L^\infty (\partial \Omega )$
. -
(b) After rigid motions, we assume that
${\mathbf{0}}\in \partial \Omega$
. Recall that
$\mathcal{C}^h$
and
$\mathcal{K}^h$
are defined in (4.2) and (4.3) respectively, where
${\mathbf{0}}$
is the apex of the conic corner
$\mathcal{C}^h$
or the convex polyhedral corner
$\mathcal{K}^h$
. If
$\Omega$
possesses a convex conic corner
$\mathcal{C}^h$
(or a cuboid corner
$\mathcal{K}^h$
), then
$q \in H^2(\overline{\mathcal{C}^h})$
(or
$q \in H^2(\overline{\mathcal{K}^h})$
) and
$\eta \in C^\alpha (\overline{\Gamma _h})$
satisfying
$\eta ({\mathbf{0}})\not =0$
and
$\alpha \in (0,1)$
, where
$\Gamma _h= \mathcal{C}^h\cap \partial \Omega$
(or
$\Gamma _h= \mathcal{K}^h\cap \partial \Omega$
). If
$\Omega$
possesses a convex polyhedral corner
$\mathcal{K}^h=B_h\cap \Omega$
, then
$q \in H^2(\overline{\mathcal{K}^h})$
satisfying
$q({\mathbf{0}})\not =1$
and
$\eta \equiv 0$
on
$ \overline{\mathcal{K}^h}\cap \partial \Omega$
. -
(c) The total wave field
$u$
is non-vanishing everywhere in the sense that for any
${\mathbf{x}}\in \mathbb R^3$
,(5.2)where
\begin{equation} \lim _{\lambda \to +0}\frac{1}{m(B({\mathbf{x}},\rho ))}\int _{B({\mathbf{x}},\lambda )}\vert u({\mathbf{x}})\vert \mathrm{d}{\mathbf{x}}\not =0, \end{equation}
$m(B({\mathbf{x}},\lambda ))$
is the measure of
$B({\mathbf{x}},\lambda )$
.
Remark 5.1.
The assumption (5.2) is a technical condition for deriving the unique results, which can be fulfilled under generic physical scenarios. For example, when
$k\cdot \mathrm{diam}(\Omega )\ll 1$
, by the well-posedness of the direct scattering problem (1.3) (cf. [Reference Bondarenko and Liu15
, Theorem 2.4]), the condition (5.2) can be satisfied. The detailed discussion on this point can be found in [Reference Diao, Cao and Liu26
, Page 44]. We believe that (5.2) can be fulfilled under other physical settings, where we choose not to explore this aspect in this paper and shall investigate it in the future.
Theorem 5.2.
Consider the conductive scattering problem (1.3) with two conductive scatterers
$(\Omega _j;\; k,{\mathbf{d}},q_j,\eta _j),j=1,2,$
in
$ \mathbb R^3$
. Let
$u^\infty _{j}(\hat{{\mathbf{x}}};\;u^i)$
be the far-field pattern associated with the scatterers
$(\Omega _j;\;k,{\mathbf{d}},q_j,\eta _j),j=1,2$
and the incident field
$u^i$
. If
$(\Omega _j;\; k,{\mathbf{d}}, q_j,\eta _j)$
are admissible and
\begin{equation} u^\infty _1(\hat{{\mathbf{x}}};\; u^i)=u^\infty _2(\hat{{\mathbf{x}}};\; u^i) \end{equation}
for all
$\hat{{\mathbf{x}}}\in \mathbb S^2$
with a fixed incident
$u^i$
. Then,
\begin{equation} \Omega _1\Delta \Omega _2\;:\!=\;(\Omega _1\setminus \Omega _2)\cup (\Omega _2\setminus \Omega _1) \end{equation}
cannot contain a convex conic corner or a cuboid corner. Furthermore, if
$\Omega _1$
and
$\Omega _2$
are two cuboids, then
$\Omega _1=\Omega _2$
.
Proof. We prove this theorem by contradiction. Suppose that
$\Omega _1\Delta \Omega _2$
contains a convex conic corner. Without loss of generality, we assume that the underlying convex conic corner
$\mathcal{C}^h \subset{\Omega _2}\setminus{\Omega _1 }$
, where
${\mathbf{0}}\in \partial \Omega _2$
and
$\Omega _2\cap B_h=\mathcal{C}^h$
with a sufficient small
$h\in \mathbb R_+$
such that
$B_h\subset \mathbb R^3 \setminus \overline{\Omega _1}$
.
Due to (5.3), with the help of Rellich’s Theorem (cf. [Reference Colton and Kress21]), it holds that
$u_1^s=u_2^s$
in
$\mathbb R^3\setminus (\overline{\Omega }_1\cup \overline{\Omega }_2)$
, we have
\begin{equation} u_1({\mathbf{x}})=u_2({\mathbf{x}}),\ \forall {\mathbf{x}} \in \mathbb R^3\setminus (\overline{\Omega }_1\cup \overline{\Omega }_2). \end{equation}
Since
$\Gamma _h=\partial \mathcal{C}^h\cap \partial \Omega _2$
, by virtue of transmission conditions on
$\partial \Omega _2$
of (1.3) and (5.5), it yields that
\begin{equation} u_2^+=u_2^-=u_1^+,\ \partial u_2^-=\partial u_2^++\eta _2 u_2^+=\partial u_1^+ +\eta _2 u_1^+\ \mathrm{on} \ \Gamma _h. \end{equation}
According to (5.6) and direct scattering problems (1.3) associated with
$(\Omega _j;\; k,{\mathbf{d}},q_j,\eta _j)$
, one has
\begin{equation*} \left\{\begin{array}{l@{\quad}l} \Delta u_2^-+k^{2}q_2u_2^-=0 & \mbox{$\mathrm{in}\ \mathcal{C}^h$},\\[5pt] \Delta u_1^++k^{2}u_1^+=0 & \mbox{$\mathrm{in}\ \mathcal{C}^h$},\\[5pt] u_2^-=u_1^+,\ \partial _{\nu }u_2^-=\partial _{\nu }u_1^++\eta _2 u_1^+ & \mbox{$\mathrm{on}\ \Gamma _h$}. \end{array} \right.\end{equation*}
By the well-posedness of the direct scattering problem (1.3), it yields that
$u_2^-\in H^1( \mathcal{C}^h)$
and
$u_1^+$
is real analytic in
$B_h$
. By virtue of the condition (b) in Definition 5.1, using Theorem 4.2, we know that
$u_1({\mathbf{0}})=0$
, which is contradicted to the admissibility condition (c) in Definition 5.1.
The first conclusion of this theorem concerning a cuboid corner can be proved similarly by using Theorem 4.3. We omit the proof.
Figure 1 Schematic illustration of corona shape scatterers.
By the convexity of two cuboids
$\Omega _1$
and
$\Omega _2$
and the first conclusion of this theorem, it is ready to know that
$\Omega _1=\Omega _2$
.
The proof is complete.
In the following, we introduce an admissible class
$\mathcal{T}$
of corona shape, which shall be used in Theorem 5.3. The schematic illustration of corona shape scatterers can be found in Figure 1.
Definition 5.2.
Let
$D$
be a convex open bounded Lipschitz domain with a connected complement
$\mathbb R^3\setminus \overline{D}$
. If there exist finite many strictly convex conic cones
$\mathcal{C}_{{\mathbf{x}}_j,\textbf{v}_j,\theta _j}(j=1,2,\dots,\ell,\ell \in \mathbb N)$
defined in (4.1) such that
-
(a) the apex
${\mathbf{x}}_j\in \mathbb R^3\setminus \overline{D}$
,
$\mathcal{C}_{{\mathbf{x}}_j,\textbf{v}_j,\theta _j}\cap D\neq \emptyset$
and
$\mathcal{C}_{{\mathbf{x}}_j,\textbf{v}_j,\theta _j}\setminus D$
has two disconnected components, where
$\mathcal{C}_{{\mathbf{x}}_j,\textbf{v}_j, \theta _j}^{\ast }$
is the bounded component of
$\mathcal{C}_{{\mathbf{x}}_j,\textbf{v}_j,\theta _j}\setminus D$
; -
(b)
$\partial \overline{\mathcal{C}_{{\mathbf{x}}_j,\textbf{v}_j, \theta _j}^{\ast }}\setminus \partial \overline{\mathcal{C}_{{\mathbf{x}}_j,\textbf{v}_j,\theta _j}}\subset \partial \overline D$
and
$\cap _{j=1}^\ell \left (\partial \overline{\mathcal{C}_{{\mathbf{x}}_j,\textbf{v}_j,\theta _j}^{\ast }}\setminus \partial \overline{\mathcal{C}_{{\mathbf{x}}_j,\textbf{v}_j,\theta _j}}\right )=\emptyset$
; -
(c)
$\Omega \;:\!=\;\cup _{j=1}^\ell \mathcal{C}_{{\mathbf{x}}_j,\textbf{v}_j,\theta _j}^{\ast } \cup D$
is admissible described by Definition
5.1
;
then
$\Omega$
is said to belong to an admissible class
$\mathcal{T}$
of corona shape.
A global unique recovery for the admissible scatter belonging to
$\mathcal{T}$
of corona shape is shown in Theorem 5.3, which can be proved by using Theorem 5.2 and the assumptions in Theorem 5.3. Indeed, the assumptions (5.7a) and (5.7b) imply that the set difference of two scatters
$\Omega _1$
and
$\Omega _2$
cannot contain a convex conic corner if
$\Omega _j \in \mathcal{T}$
,
$j=1,2$
.
Theorem 5.3.
Suppose that
$\Omega _{m},m=1,2$
belong to the admissible class
$\mathcal{T}$
of corona shape, where
\begin{equation*} \Omega _m=\cup _{j^{(m)}=1}^{\ell ^{(m)}}\mathcal {C}_{\textbf {x}_{j^{(m)}},\textbf {v}_{j^{(m)}}, \theta _{j^{(m)}}}^{\ast }\cup D_m,\quad m=1,2. \end{equation*}
Consider the conductive scattering problem (1.3) associated with the admissible conductive scatterers
$\Omega _{m},m=1,2$
. Let
$u_j^\infty (\hat{{\mathbf{x}}};\; u^i)$
be the far-field pattern associated with the scatterers
$(\Omega _m;\; \mathcal{C}_{{\mathbf{x}}_{j^{(m)}},\textbf{v}_{j^{(m)}}, \theta _{j^{(m)}}}^{\ast } ),m=1,2$
and the incident field
$u^i$
. If the following conditions:
\begin{align} D_1&=D_2, \end{align}
\begin{align} \theta _{i^{(1)}}&=\theta _{j^{(2)}}, \textbf{v}_{i^{(1)}}=\textbf{v}_{j^{(2)}} \ \mbox{for} \ i^{(1)} \in \{1,\ldots,\ell ^{(1)}\}\ \mbox{and} \ j^{(2)}\in \{1,\ldots,\ell ^{(2)} \}\ \mbox{when} \ {\mathbf{x}}_{i^{(1)}}={\mathbf{x}}_{j^{(2)}}, \end{align}
and (5.3) are satisfied, then
$\ell ^{(1)}=\ell ^{(2)},\ {\mathbf{x}}_{j^{(1)}}={\mathbf{x}}_{j^{(2)}}$
and
$\theta _{j^{(1)}}=\theta _{j^{(2)}}$
, where
$j^{(m)}=1,\dots \ell ^{(m)}$
,
$m=1,2$
. Namely, one has
$\Omega _1=\Omega _2$
.
In Theorem 5.4, we first show a local uniqueness result regarding a polyhedral corner by a single measurement, where we can prove this theorem in a similar manner as for Theorem 5.2 by utilizing Corollary 4.5. Hence, the detailed proof of Theorem 5.4 is omitted. We emphasize that an admissible convex polyhedral scatterer
$\Omega$
can be uniquely determined by a single far-field measurement, which a global uniqueness result for (1.4) associated with (1.3) is established.
Theorem 5.4.
Consider the conductive scattering problem (1.3) with conductive scatterers
$(\Omega _j;\;k,{\mathbf{d}},q_j,\eta _j),j=1,2,$
in
$\mathbb R^3$
. Let
$u^\infty _{j}(\hat{{\mathbf{x}}};\; u^i)$
be the far-field pattern associated with the scatterers
$(\Omega _j;\; k,{\mathbf{d}},q_j,\eta _j),j=1,2$
and the incident field
$u^i$
. If
$(\Omega _j;\; k,{\mathbf{d}},q_j,\eta _j)$
are admissible and (5.3) is fulfilled, then
$ \Omega _1\Delta \Omega _2$
defined by (5.4) cannot contain a convex polyhedral corner. Furthermore, if
$\Omega _1$
and
$\Omega _2$
are two admissible convex polyhedrons, then
\begin{equation*}\Omega _1=\Omega _2.\end{equation*}
Consider the direct scattering problem (5.1) associated with a convex polyhedron medium
$(\Omega ;\; k,{\mathbf{d}},q)$
, which is a special case of (1.3) by letting
$\eta \equiv 0$
on
$\partial \Omega$
. In Corollary 5.5, we give a global unique determination for a convex polyhedron
$\Omega$
associated with the direct scattering problem (5.1) by a single far-field measurement under generic physical settings. Corollary 5.5 can be proved directly by using Theorem 5.4 and the detailed proof is omitted. Compared with the corresponding uniqueness result in [Reference Hu, Salo and Vesalainen38] for the shape determination of a cuboid scatterer by a single measurement, we relax the geometrical restriction on the uniqueness determination regarding medium shapes by a single measurement from a cuboid to a general convex polyhedron.
Corollary 5.5.
Consider the scattering problem (5.1) with scatterers
$(\Omega _j;\; k,{\mathbf{d}},q_j),j=1,2,$
in
$\mathbb R^3$
. Let
$u^\infty _{j}(\hat{{\mathbf{x}}};\; u^i)$
be the far-field pattern associated with the scatterers
$(\Omega _j;\; k,{\mathbf{d}},q_j),j=1,2$
and the incident field
$u^i$
. Assume that the total wave field
$u_j$
corresponding to (5.1) associated with
$(\Omega _j;\; k,{\mathbf{d}},q_j)$
$(j=1,2)$
satisfies (5.2). Suppose that
$\Omega _j$
is a convex polyhedron,
$j=1,2$
. Denote
$\mathcal{V}(\Omega _j )$
by a set composed of all vertexes of
$\Omega _j$
with
$j=1,2$
. For any
${\mathbf{x}}_{c,j} \in \mathcal{V}(\Omega _j )$
, if there exists sufficient small
$h\in \mathbb R_+$
such that
$q_j\in H^2(\overline{ \mathcal{K}_{{\mathbf{x}}_{c,j} }^h } )$
with
$q_j({\mathbf{x}}_{c,j} ) \neq 1$
for
$j=1,2$
, where
$\mathcal{K}_{{\mathbf{x}}_{c,j} }^h=\Omega \cap B_h( {\mathbf{x}}_{c,j})\Subset \Omega _j$
, then the condition (5.3) implies that
$\Omega _1=\Omega _2.$
When the shape of an admissible scatter
$\Omega$
is uniquely determined by a single measurement, under a-prior knowledge the potential
$q$
associated with
$\Omega$
we can recover the surface parameter
$\eta$
by a single measurement provided that
$\eta$
is a non-zero constant. We can use a similar argument for proving [Reference Diao, Cao and Liu26, Theorem 4.2] to establish Theorem 5.6. The detailed proof is omitted. The technical condition (5.8) can be easily fulfilled under generic physical scenarios; see the detailed discussion in [Reference Diao, Cao and Liu26, Remark 4.2].
Theorem 5.6.
Consider the conductive scattering problem (1.3) with the admissible conductive scatterers
$(\Omega _m;\;k,{\mathbf{d}},q,\eta _m)$
in
$\mathbb R^3$
, where
$\eta _m\not =0$
,
$m=1,2$
, are two constants. Let
$u_m^\infty (\hat{{\mathbf{x}}};\; u^i)$
be the far-field pattern with the scatterers
$(\Omega _m;\; k,{\mathbf{d}},q,\eta _m),m=1,2$
and the incident field
$u^i$
. Suppose that
\begin{equation*}u_1^\infty (\hat {\textbf {x}};\; u^i)=u_2^\infty (\hat {\textbf {x}};\; u^i),\ for\ all\ \hat {\textbf {x}}\in \mathbb S^2\end{equation*}
with a fixed incident wave
$u^i$
. If
\begin{equation} \mbox{ $k$ is not an eigenvalue of the partial differential operator $\Delta +k^2q$, } \end{equation}
and
$\Omega _m$
is a cuboid (
$m=1,2$
), we have
$\eta _1=\eta _2$
. Similarly, when
\begin{equation*} \Omega _m=\cup _{j^{(m)}=1}^{\ell ^{(m)}}\mathcal {C}_{\textbf {x}_{j^{(m)}},\textbf v_{j^{(m)}},\theta _{j^{(m)}}}^{\ast }\cup D_m \in \mathcal {T},\quad m=1,2, \end{equation*}
if the conditions (5.8), (5.7a) and (5.7b) are fulfilled, one has
$\eta _1=\eta _2$
.
Financial support
The work of H. Diao is supported by National Natural Science Foundation of China (No. 12371422) and the Fundamental Research Funds for the Central Universities, JLU (No. 93Z172023Z01). The work of X. Fei is supported by NSFC/RGC Joint Research Grant No. 12161160314. The work of Hongyu Liu is supported by the NSFC/RGC Joint Research Scheme, N_CityU101/21; ANR/RGC Joint Research Scheme, A-CityU203/19; and the Hong Kong RGC General Research Funds (projects 11311122, 12301420 and 11300821).
Competing interests
None.
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