
\documentclass[reqno]{amsart}
\usepackage{hyperref}

\AtBeginDocument{{\noindent\small
{\em Electronic Journal of Differential Equations},
Vol. 2005(2005), No. 141, pp. 1--17.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu  (login: ftp)}
\thanks{\copyright 2005 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2005/141\hfil Nonlinear decay]
{Nonlinear decay and scattering of solutions
 to a Bretherton equation in several space dimensions}
\author[A. D\'e Godefroy\hfil EJDE-2005/141\hfilneg]
{Akmel D\'e Godefroy}

\address{Akmel D\'e Godefroy \hfill\break
Laboratoire de Mathematiques Appliqu\'ees, UFRMI,
Universit\'e d'Abidjan Cocody, 22 BP 582 Abidjan 22,
Cote d'Ivoire}
\email{akmelde@yahoo.fr}

\date{}
\thanks{Submitted October 12, 2005. Published December 5, 2005.}
\subjclass[2000]{35B40, 35Q10, 35Q20}
\keywords{Asymptotic behavior; scattering problem; Bretherton equation}

\begin{abstract}
 We consider a Cauchy problem for the $n$-dimensional
 Bretherton equation. We establish the existence of a global
 solution and study its long-time behavior, with small data.
 This is done using the oscillatory integral techniques
 considered in \cite{k2}.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}
\newtheorem{remark}[theorem]{Remark}
\allowdisplaybreaks

\section{Introduction}

For the Bretherton equation, we consider the initial-value problem (I.V.P)
\begin{equation}  \label{e1.1}
\begin{gathered}
u_{tt} + u + {\triangle}u+ {\triangle}^{2}u =  F(u),
\quad x\in {\mathbb{R}}^{n},\; n\geq 1,\; t>0,  \\
u(x,0) = f_1(x),\\
u_{t} (x,0) = f_2(x),
\end{gathered}
\end{equation}
where $F(u)=|u|^{\alpha}u$ and $\alpha \geq 1$.
Problem \eqref{e1.1} with $n=1$ was introduced by Kalantorov and
Ladyzhenskaya in \cite{k1}, where they proved the blow-up of it's
solutions in finite time for large data. After an investigation on
the local existence of solutions to  \eqref{e1.1} with $n=1$,
Scialom  \cite{n1} pointed out that the global existence result for
``small data" remains an open problem.

Furthermore, using a new computational method called
``RATH" (Real Automated Tangent Hyperbolic function method),
Zhi-bin Li \emph{et al.} \cite{z1} showed the existence of solitary-wave
solutions of some partial differential equations. Yet, for the
Bretherton equation, the ``RATH" method showed the non-existence of
solitary-wave solution. Our scattering result here seems to
confirm the computation result of Zhi-bin Li \emph{et al.} for the
non-existence of solitary-wave solution to the Bretherton
equation, at least for small data. Indeed it is well known that
affirmative results on scattering are interpreted as the
nonexistence of solitary-wave solution of arbitrary small
amplitude, see \cite{b2,l1}. Our aim in this paper is to study the
global existence, the uniform in $x$ decay to zero and the
scattering  as $t\to \infty$, for
 solutions of \eqref{e1.1} with sufficiently small data.
More precisely, we show the following
 two theorems:

\begin{theorem} \label{thm1.1}
Let $\alpha > 5$ and $f_{1}, f_2 \in {\mathbb{H}}^{s}({\mathbb{R}}^{n})
\cap{\mathbb{L}}^{1}({\mathbb{R}}^{n})$, $n\geq 1$, with
$s\geq \frac{3}{2}n$. If $ |f_1|_{1} +\|f_1\|_{3n/2}
+|f_2|_{1} +\|f_2\|_{3n/2} < \delta$ with $\delta$
sufficiently small, then the solution $u$ of \eqref{e1.1} is
unique in $C({\mathbb{R}}, {\mathbb{H}}^{s}({\mathbb{R}}^{n}))$ and satisfies
\begin{equation}  \label{e1.2}
|u(x,t)|_{\infty}\leq c(1+t)^{-1/4}, \quad t \geq 0,
\end{equation}
where $c$ does not depend of $x$ and $t$. Moreover, there is
scattering for $t\to \pm\infty$, that is, there exist
$u_{+}, u_{-}$, solutions of the linear problem \eqref{e2.1}, such that
$\|u(t)-u_{\pm}(t)\|_{2}$ tends to 0 as $t\to \pm\infty$.
\end{theorem}

\begin{theorem} \label{thm1.2}
Let $\alpha > 1+\frac{4}{\theta}$ and $f_1, f_2 \in
{\mathbb{H}}^{r+\frac{5}{2}n+1}({\mathbb{R}}^{n})\cap{\mathbb{L}}^{q}_{r+\frac{5}{2}n}({\mathbb{R}}^{n}),\;
n\geq 1$, with $r >\frac{n}{p}$. If $\|f_1\|_{r+\frac{5}{2}n,q}
+\|f_2\|_{r+\frac{5}{2}n,q} + \|f_1\|_{r+\frac{5}{2}n+1}
+\|f_2\|_{r+\frac{5}{2}n+1} < \delta$ with $\delta$ small, then
the solution $u$ of the I.V.P \eqref{e1.1} satisfies
\begin{equation}
\|u(x,t)\|_{r,p}\leq c(1+t)^{- \frac{\theta}{4}}, \quad t \geq 0,
\end{equation}
where $ p= 2/(1- \theta), q= 1/(1+ \theta)$, and $\theta \in
]0,1[.$
\end{theorem}


\subsection*{Notation}
The notation $\| \cdot \|_{r,p}$ is used to denote the norm in
${\mathbb{L}}^p_r$ such that for $u \in {\mathbb{L}}^p_r({\mathbb{R}}^{n}),  \; \|u
\|_{r,p} =\|u \|_{{\mathbb{L}}^p_r}=\|(1- \Delta)^{r/2}u \|_{{\mathbb{L}}^p}<
\infty$. Also, $| \cdot |_p$ instead of $\| \cdot \|_{0,p}$
denotes the norm in ${\mathbb{L}}^p$, and ${\mathbb{H}}^s$ with norm $\| \cdot
\|_s$ is used instead of ${\mathbb{L}}^2_s$. Throughout this paper, $c$
represents a generic constant independent of $t$ and $x$. The
Fourier transform of a function $f$ is denoted by
$\widehat{f}(\xi)$ or ${\mathcal{F}}(f)(\xi)$ and ${\mathcal{F}}^{-1}(f) \equiv
\breve{f}$ denotes
the inverse Fourier transform of $f$.

For $1 \leq p,q \leq \infty$ and $f :\mathbb{R}^{n} \times \mathbb{R}\to\mathbb{R}$,
$$
\| f \|_{{\mathbb{L}}^{q}(\mathbb{R}; {\mathbb{L}}^p(\mathbb{R}^{n}))}
=\Big(\int^{+\infty}_{-\infty} \Big(
\int_{\mathbb{R}^{n}}|f(x,t)|^pdx\Big)^{q/p}dt\Big)^{1/q}.
$$

\section{Local existence result}

In this section, we write the Cauchy problem associated with $\eqref{e1.1}$
in it's integral form and we prove the local existence and
uniqueness of it's solution. Our method of proof is based on
linear estimates and a contraction mapping argument.
Thereupon, we state a locally well-posed theorem for
\eqref{e1.1}.

\begin{theorem} \label{thm2.1}
Let $s>n/2$ be a real number, and $f_1, f_2 \in
{\mathbb{H}}^s({\mathbb{R}}^{n})$, $n\geq1$. Then there exists $T_0>0$ which
depends on $\|f_1\|_{s}$ and $\|f_2\|_{s}$, and a unique solution
of \eqref{e1.1} in [0,T], such that
$u\in {\mathcal{C}}(0,T_0;{\mathbb{H}}^{s}({\mathbb{R}}^{n}))$.
\end{theorem}

\begin{proof}
Consider first the linear part of \eqref{e1.1}:
\begin{equation} \label{e2.1}
\begin{gathered}
u_{tt} + u + {\triangle}u+ {\triangle}^{2}u =  0, \quad
x\in {\mathbb{R}}^{n},\; n\geq 1,\; t>0,  \\
u(x,0) = f_1(x), \\
u_{t} (x,0) = f_2(x),
\end{gathered}
\end{equation}
The formal solution of \eqref{e2.1} is
\begin{equation} \label{e2.2}
u(x,t)=V_1(t)f_1(x) + V_2(t)f_2(x)
\end{equation}
where
\begin{gather*}
V_1(t)f_1(x)=[\frac{1}{2}(e^{it\phi(\xi)} +
e^{-it\phi(\xi)})\hat{f_1}(\xi)]^{\vee}(x),\\
V_2(t)f_2(x)=[\frac{1}{2i\phi(\xi)}(e^{it\phi(\xi)} -
e^{-it\phi(\xi)})\hat{f_2}(\xi)]^{\vee}(x)
\end{gather*}
with $\phi(\xi)=(1- |{\xi}|^2 + |{\xi}|^4)^{1/2}$.

We define
\begin{gather*}
S_1(t)f_1(x) = \frac{1}{{2}(2\pi)^{n}}\int_{{\mathbb{R}}^{n}}e^{ix\xi +
it\phi(\xi)}\hat{f_1}(\xi) d\xi, \\
 S_2(t)f_2(x) =
\frac{1}{2i(2\pi)^{n}}\int_{{\mathbb{R}}^{n}}e^{ix\xi +
it\phi(\xi)}\frac{\hat{f_2}(\xi)}{\phi(\xi)}d\xi.
\end{gather*}
Then
\begin{gather*}
V_1(t)f_1(x)=S_1(t)f_1(x) + S_1(-t)f_1(x), \\
V_2(t)f_2(x)=S_2(t)f_2(x) - S_2(-t)f_2(x).
\end{gather*} %2.3 2.4
Note that
\begin{equation} \label{e2.5}
\Phi(\xi) \geq {\frac{1}{2 \sqrt{3}}}(1+ |{\xi}|^2).
\end{equation}
Indeed, ${\phi(\xi)}^{2}=1- |{\xi}|^2 + |{\xi}|^4=(1-
\frac{1}{2}|{\xi}|^2)^{2} + \frac{3}{4}|{\xi}|^4$ so that if
$|{\xi}|\leq 1$ then
$$
{\phi(\xi)}^{2}\geq \frac{1}{4}+
\frac{3}{4}|{\xi}|^4 \geq
\frac{1}{4}(\frac{1}{3}+\frac{2}{3}|{\xi}|^2
+\frac{1}{3}|{\xi}|^4)=\frac{1}{12}(1+|{\xi}|^2)^{2}
$$
 and if $|{\xi}|\geq 1$ then
$$
{\phi(\xi)}^{2}\geq \frac{3}{4}|{\xi}|^4
\geq \frac{1}{12}(1+|{\xi}|^2)^{2}.
$$

\begin{remark} \label{rmk2.2} \rm
Since \eqref{e1.1} will not change when $t$ is switched to $-t$, the
solution $u(t)$ in Theorem \ref{thm2.1} can be extended to
$u\in {\mathcal{C}}([-T_0,T_0];{\mathbb{H}}^{s}({\mathbb{R}}^{n}))$.
\end{remark}

\begin{remark} \label{rmk2.3} \rm
Note that, since the negative sign of $t$ in $S_j(-t)$ acts
only on the sign of the phase function, the estimates of
$S_j(t)f(x)$ below hold also for $S_j(-t)f(x)$. Hence, to estimate
$V_j(t)f(x)$ one only has to estimate
$S_j(t)f(x)$, $ j=1,2$.
\end{remark}

 To prove the existence theorem for \eqref{e1.1}, we need the
following inequalities.

\begin{lemma} \label{lem2.4}
Let $f_1, f_2 \in {\mathbb{H}}^{s}({\mathbb{R}}^{n}), s\geq 0$, and $V_1(t),
V_2(t)$ defined in \eqref{e2.2}. Then
\begin{gather}
\|V_1(t)f_1(x)\|_{s} \leq c\|f_1\|_s  \label{e2.6}\\
 \|V_2(t)f_2\|_{s} \leq c\|f_2\|_{s-2} \leq  c\|f_2\|_{s}. \label{e2.7}
\end{gather}
\end{lemma}

The proof of the above lemma follows directly from the definition
of $V_1(t)$ and $V_2(t)$ in \eqref{e2.2} and the use of the
inequality \eqref{e2.5}.
\end{proof}

Thereafter, with Lemma \ref{lem2.4} in hand, one can use the contraction
mapping principle to prove the local well-posedness result in
Theorem \ref{thm2.1}. Then, thanks to the Duhamela principle, the solution
of \eqref{e1.1} verifies the integral equation
\begin{equation} \label{e2.8}
u(x,t)=V_1(t)f_1(x)+ V_2(t)f_2(x) +
\int^t_0V_2(t-\tau)(|u|^{\alpha }u)(\tau) d \tau.
\end{equation}
Let us define
\begin{equation} \label{e2.9}
\varphi(u)(t)=V_1(t)f_1(x)+ V_2(t)f_2(x) +
\int^t_0V_2(t-\tau)(|u|^{\alpha}u)(\tau) d \tau
\end{equation}
and the complete metric space
$$
F= \{v \in \mathcal{C}(0,T; {\mathbb{H}}^s({\mathbb{R}}^{n})), \; s>n/2, \quad
 \sup_{[0,T]}\|v(t)\|_{s} \leq a \},
$$
where $a$ is a positive real constant.

We begin by showing that $\varphi :F\to F$ is a contraction.
The use of the definition of $\varphi$ in \eqref{e2.9},
Lemma \ref{lem2.4} and
the fact that ${\mathbb{H}}^s({\mathbb{R}}^{n}))$, $s>n/2$ is an
Algebra, lead for all $0\leq t \leq T$, to
\begin{equation} \label{e2.10}
\begin{aligned}
 \|\varphi(u)(t)\|_{s} &\leq c(\|f_1\|_{s}+ \|f_2\|_{s}) +
c\int^t_0 \|(|u|^{\alpha}u)(\tau)\|_{s} d \tau  \\
&\leq c(\|f_1\|_{s}+ \|f_2\|_{s}) +
c\int^t_0 \|u(\tau)\|^{\alpha+1}_{s} d \tau  \\
&\leq c(\|f_1\|_{s}+ \|f_2\|_{s})+
cT(\sup_{[0,T]}\|u\|_{s})^{\alpha+1}.
\end{aligned}
\end{equation}
Thereby, taking $\mu$ as a positive constant such that
$\|f_1\|_{s}+\|f_2\|_{s}<\mu$, we get for $u \in F $,
$$
 \sup_{[0,T]}\|\varphi(u)(t)\|_{s} \leq c\{\mu +a^{\alpha +1}T\}
$$
so that choosing $a=2c\mu$, we obtain
$$
 \sup_{[0,T]}\|\varphi(u)(t)\|_{s} \leq c\{\mu +2^{\alpha +1}c^{\alpha +1}{\mu}^{\alpha +1}T\}
 = c\mu \{1 +2^{\alpha +1}c^{\alpha +1}{\mu}^{\alpha}T\}.
$$
Then, fixing $T$ such that
\begin{equation} \label{e2.11}
2^{\alpha +1}c^{\alpha +1}{\mu}^{\alpha}T<1
\end{equation}
we get
$$
\sup_{[0,T]}\|\varphi(u)(t)\|_{s} \leq 2c\mu =a.
$$
This shows that $\varphi$ maps $F$ into $F$.
The next step is to prove that $\varphi$ is in fact a contraction.
We consider $u$ and $v$ in $F$ with the same initial values. Thus
$$
(\varphi(u)-\varphi(v))(t)= \int^t_0V_2(t-\tau)(|u|^{\alpha }u
-|v|^{\alpha }v)(\tau) d \tau.
$$
To estimate $\sup_{[0,T]}\|(\varphi(u)-\varphi(v))(t)\|_{s}$ we
use Lemma \ref{lem2.4}, Taylor formula and the fact that
${\mathbb{H}}^s({\mathbb{R}}^{n}))$, $s>\frac{n}{2}$ is an Algebra; it follows
that for all $0\leq t\leq T$,
\begin{align*}
 \|(\varphi(u)-\varphi(v))(t)\|_{s}
&\leq c\int^t_0
\|(|u|^{\alpha}+ |v|^{\alpha })(u-v)(\tau)\|_{s} d \tau \\
&\leq c\int^t_0 \|(|u|^{\alpha}+ |v|^{\alpha })(\tau)\|_{s}
\|(u-v)(\tau)\|_{s} d \tau  \\
&\leq c T( \sup_{[0,T]}\|u\|^{\alpha }_{s} +
\sup_{[0,T]}\|v\|^{\alpha }_{s}) \sup_{[0,T]}\|u-v\|_{s}.
\end{align*}
which leads, with $a=2c\mu$ as above, to
\begin{equation} \label{e2.12}
 \|(\varphi(u)-\varphi(v))(t)\|_{s} \leq 2^{\alpha +1}c^{\alpha
 +1}{\mu}^{\alpha}T\sup_{[0,T]}\|u-v\|_{s}.
\end{equation}
Hence, with the choice of $T$ as above in (2.11), we get from
\eqref{e2.12} that $\varphi$ is a contraction map in $F$. Thus, the
application of contraction mapping principle gives the result of
local existence and uniqueness in Theorem \ref{thm2.1}.

For the sequel, we need the following inequalities which are
obtained by obvious computations including the inequality \eqref{e2.5}:
$\forall \xi \in {\mathbb{R}}^{n}$,
\begin{gather}
|{\nabla}\phi(\xi)|= \frac{|{\xi}||2|{\xi}|^{2}-1|}{(1-
|{\xi}|^2 + |{\xi}|^4)^{1/2}} \label{e2.13}\\
|{D}^{2}\phi(\xi)|\leq c. \label{e2.14}
\end{gather}


\section{Linear Estimates}

The purpose of this section is to study the linear equation
associated with \eqref{e1.1} and to establish linear estimates
needed for the next section. The following result is concerning
the decay of solutions of the linear problem \eqref{e2.1}.

\begin{lemma} \label{lem3.1}
Let $V_1(t)$ and $V_2(t)$ be defined as in \eqref{e2.2}. Let $f_{1}, f_2
\in {\mathbb{H}}^{\frac{3}{2}n}({\mathbb{R}}^{n})\cap{\mathbb{L}}^{1}({\mathbb{R}}^{n}), \;
n\geq 1$. Then there exists a constant $c$ independent of $f_1,
f_2, t$ and $x \in {\mathbb{R}}^{n}$ such that
\begin{equation} \label{e3.1}
|V_j(t)f_j|_{\infty}\leq c (|f_j|_{1}
+\|f_j\|_{3n/2}(1+t)^{-1/4}, \quad j=1,2,
\end{equation}
for all $t \geq 0$. Moreover, let $f_{1}, f_2 \in
{\mathbb{H}}^{\frac{3}{2}n}({\mathbb{R}}^{n})\cap{\mathbb{L}}^{1}_{\frac{5}{2}n+k}({\mathbb{R}}^{n})$,
$n\geq 1$, $ k \in {\mathbb{R}}^{+}$; then we have
\begin{equation} \label{e3.2}
\|V_j(t)f_j\|_{k,\infty}\leq c(\|f_j\|_{\frac{5}{2}n+k,1}
+\|f_j\|_{\frac{3}{2}n +k})(1+t)^{-1/4}, \quad j=1,2.
\end{equation}
\end{lemma}

Before proving the above lemma, we  prove the following lemma.

\begin{lemma} \label{lem3.2}
Given $x \in {\mathbb{R}}^{n}$ and $t \in {\mathbb{R}}^{+}$, the phase function
$$
\Psi(\xi)=\phi(\xi)+t^{-1}(x,\xi)
$$
has a finite number of stationary points. Moreover, if ${\xi}_s$
is a stationary point of $\Psi$, then any point ${\eta}_s$
verifying $|{\eta}_s|=|{\xi}_s|$ is also a stationary point of
$\Psi$.
\end{lemma}

\begin{proof}
Since
$$
\nabla{\Psi}(\xi)=\nabla{\phi}(\xi)+xt^{-1}=\frac{{\xi}(2|{\xi}|^{2}-1)}{(1-
|{\xi}|^2 + |{\xi}|^4)^{1/2}}+xt^{-1},
$$
we have
\[
\nabla{\Psi}(\xi)=0\;\Leftrightarrow\;
{\xi}(2|{\xi}|^{2}-1)+xt^{-1}(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}=0
\]
and making the scalar product with
\begin{equation}label{e3.3}
{\xi}(2|{\xi}|^{2}-1)+xt^{-1}(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}
\end{equation}
we get
\begin{equation} \label{e3.4}
\nabla{\Psi}(\xi)=0 \Leftrightarrow
|{\xi}|^{2}(2|{\xi}|^{2}-1)^{2}+|xt^{-1}|^{2}(1- |{\xi}|^2 +
|{\xi}|^4)=0 \Leftrightarrow P(|\xi|)=0
\end{equation}
where $P(y)=4y^{6}-4y^{4}+y^{2}- |xt^{-1}|^{2}(1-y^{2}+y^{4}), \;
y \in {\mathbb{R}}_{+}.$ The stationary points of $\Psi$ are such that
their norms are the roots of $P(y)$. Then since $P(y)$ is
polynomial of degree $6$ so that it has at most $6$ roots, we
deduce that $\Psi$ has a finite number of stationary points in
${\mathbb{R}}^{n}$. Furthermore, since $P(0)=- |xt^{-1}|^{2}\leq 0$ and
$P(y)\to + \infty$ as $y\to + \infty$, and since
$P(y)$ is continuous, we deduce that there exists at least one
stationary point of $\Psi$. Therefore, $\Psi$ has a finite number
of stationary points. Moreover, we note that if ${\xi}_s$ is a
stationary point of $\Psi$ and if ${\eta}_s$ is a point verifying
$|{\eta}_s|=|{\xi}_s|$, then we have
$P(|{\eta}_s|)=P(|{\xi}_s|)=0$ and consequently from \eqref{e3.4}
${\eta}_s$ is also a stationary point of $\Psi$. This completes the proof
 of Lemma \ref{lem3.2}. \end{proof}

Next, we use Lemma \ref{lem3.2} to prove Lemma \ref{lem3.1}. Let
us recall that, thanks to Remark \ref{rmk2.2}, the inequality \eqref{e3.1}
 of proposition \eqref{e3.1} holds for $V_1(t)$ and $V_2(t)$
whenever it holds for $S_1(t)$ and $S_2(t)$.
If $0\leq t \leq 1$, we have, thanks to the Schwartz inequality,
\begin{equation} \label{e3.5}
\begin{aligned}
\quad |S_1(t)f_1(x)| &=
\frac{1}{{2}(2\pi)^{n}}|\int_{{\mathbb{R}}^{n}}e^{it\Psi(\xi)}\hat{f_1}(\xi)
d\xi| \\
&\leq c\int_{{\mathbb{R}}^{n}}|\hat{f_1}(\xi)| d\xi \\
&\leq c(\int_{{\mathbb{R}}^{n}}(1+|\xi|^{2})^{-n}
d\xi)^{1/2}\|f_1\|_{n}\leq c\|f_1\|_{n}  \\
&\leq c(1+t)^{-1/4}\|f_1\|_{3n/2}
\end{aligned}
\end{equation}
If $t\geq 1$, let $\Omega = \{\xi \in {\mathbb{R}}^{n}, |\xi|\leq
t^{\frac{1}{4n}}\} $ and
$q_t(\xi)={\chi}_{\Omega}(\xi)e^{it\phi(\xi)}$; then thanks to the
Schwartz and the Young inequality,
\begin{equation} \label{e3.6}
\begin{aligned}
&|S_1(t)f_1(x)| \\
&=\frac{1}{{2}(2\pi)^{n}}|(\int_\Omega
+\int_{{\Omega}^{c}})e^{it\phi(\xi)+ix\cdot
\xi}\hat{f_1}(\xi)d\xi| \\
&\leq c|\check{q_t}(x)\ast f_1(x)|_{\infty}
+c(\int_{{\Omega}^{c}}(1+|\xi|^{2})^{-\frac{3}{2}n}
d\xi)^{1/2}(\int_{{\Omega}^{c}}(1+|\xi|^{2})^{\frac{3}{2}n}|\hat{f_1}(\xi)|^{2}
d\xi)^{1/2} \\
&\leq c|\check{q_t}(x)|_{\infty}|f_1(x)|_{1} +
ct^{-1/4}\|f_1\|_{3n/2}
\end{aligned}
\end{equation}
where the first factor in the second term of the right hand side
of \eqref{e3.6} is a bound given $\forall t\geq 1$ by
\begin{align*}
\Big(\int_{\{|\xi|\geq t^{\frac{1}{4n}}
\}}(1+|\xi|^{2})^{-\frac{3}{2}n}d\xi\Big)^{1/2}
&\leq \Big(\int_{\{r\geq t^{\frac{1}{4n}}
\}}r^{-3n}r^{n-1}dr\Big)^{1/2}\\
&=c(t^{-1/2})^{1/2}=ct^{-1/4}.
\end{align*}
It remains to estimate $\check{q_t}(x)$. We need for the sequel,
the following notations: We take $\Omega= \{\xi \in {\mathbb{R}}^{n},
|\xi|\leq t^{\frac{1}{4n}}\}$ and let $\mathcal{E}_s= \{\xi \in
{\mathbb{R}}^{n}, \nabla\Psi(\xi)=0\}$ be the set of stationary points of
$\Psi$. Hence from Lemma \ref{lem3.2}, $\mathcal{E}_s$ has a finite number
of elements. Then set
$$
s(t^{-1/4})=\bigcup_{\zeta \in
\mathcal{E}_s}B(\zeta , t^{-1/4})\bigcup \{\xi \in
{\mathbb{R}}^{n}, |\xi|\leq t^{-1/4}\}
$$
where for each $\zeta \in \mathcal{E}_s$,
$B(\zeta , t^{-1/4})=\{\xi \in {\mathbb{R}}^{n},
|\xi - \zeta|\leq t^{-1/4}\}$. Let
$$
\mathcal{A}=s(t^{-1/4})\bigcup
\{\frac{1}{\sqrt{2}}(1-t^{-1/4})\leq|\xi|\leq
\frac{1}{\sqrt{2}}(1+t^{-1/4})\}.
$$
Hence
\begin{equation} \label{e3.7}
\check{q_t}(x) = \int_{\Omega}e^{it\phi(\xi)+ix\cdot \xi}d\xi
= \Big(\int_{\Omega \cap \mathcal{A}}+\int_{\Omega \cap
{\mathcal{A}}^{c}}\Big)e^{it\phi(\xi)+ix\cdot \xi} d\xi=I_{1}+I_{2}.
\end{equation}
Since from Lemma \ref{lem3.2}, $card(\mathcal{E}_s)<\infty$, we get
\begin{equation} \label{e3.8}
\begin{aligned}
 |I_1|&\leq \int_{\Omega \cap \mathcal{A}}d\xi \\
&\leq \sum_{\zeta \in \mathcal{E}_s}\int_{B(\zeta ,
 t^{-1/4})}d\xi + \int_{\{|\xi|\leq t^{-1/4}\}}d\xi
+ \int_{\{\frac{1}{\sqrt{2}}(1-t^{-1/4})\leq|\xi|\leq
\frac{1}{\sqrt{2}}(1+t^{-1/4})\}}d\xi \\
&\leq \int_{\{0 \leq r\leq t^{-1/4} \}}r^{n-1}dr +
\int_{\{\frac{1}{\sqrt{2}}(1-t^{-1/4})\leq r\leq
\frac{1}{\sqrt{2}}(1+t^{-1/4}) \}}r^{n-1}dr \\
&\leq  ct^{-\frac{n}{4}}
+\int_{\{\frac{1}{\sqrt{2}}(1-t^{-1/4})\leq r\leq
\frac{1}{\sqrt{2}}(1+t^{-1/4}) \}}r^{n-1}dr \\
&\leq ct^{-\frac{n}{4}} + ct^{-1/4}\leq ct^{-1/4}.
\end{aligned}
\end{equation}
For $I_2$, we point out that on
$$
{\mathcal{A}}^{c}=\{s(t^{-1/4})\}^{c}\bigcap \{ \{|\xi|
\leq \frac{1}{\sqrt{2}}(1-t^{-1/4}) \} \cup \{|\xi| \geq
\frac{1}{\sqrt{2}}(1+t^{-1/4}) \} \},
$$
$\Psi$ has no stationary point so that we can integrate $I_2$ by
parts as follows:
\begin{equation}
\begin{aligned} \label{e3.9}
|I_2| &= |\int_{\Omega \cap {\mathcal{A}}^{c}}e^{it\Psi(\xi)}
d\xi|\\
&= t^{-1}|\int_{\Omega \cap
{\mathcal{A}}^{c}}\frac{1}{\nabla\Psi(\xi)}\nabla(e^{it\Psi(\xi)})
d\xi| \\
&\leq  t^{-1}\int_{\Omega \cap
{\mathcal{A}}^{c}}|\nabla(\frac{1}{\nabla\Psi(\xi)})| d\xi +
t^{-1}\int_{\partial \{\Omega \cap {\mathcal{A}}^{c}
\}}\frac{d\xi}{|\nabla\Psi(\xi)|}
\\
&\leq  ct^{-1}\int_{\Omega \cap {\mathcal{A}}^{c}}
\{|\nabla(\frac{1}{\nabla\Psi(\xi)})|
+|\nabla(\frac{1}{|\nabla\Psi(\xi)|})| \}d\xi \\
&\leq  ct^{-1}\int_{\Omega \cap {\mathcal{A}}^{c}}
\frac{|D^{2}\Psi(\xi)|}{|\nabla\Psi(\xi)|^{2}}d\xi.
\end{aligned}
\end{equation}
 For the rest of this article, we consider a point $\xi_s \in \mathcal{E}_s$;
then we have
\begin{align*}
{\mathcal{A}}^{c}\subset
&\{\xi \in {\mathbb{R}}^{n}, |\xi - \xi_s|> t^{-1/4}\}\cap \{ |\xi |> t^{-1/4}\}
\cap \{\{|\xi| <\frac{1}{\sqrt{2}}(1-t^{-1/4}) \}\\
& \cup \{|\xi| > \frac{1}{\sqrt{2}}(1+t^{-1/4})\} \}.
\end{align*}
Hence from \eqref{e3.9}, we obtain
\begin{equation} \label{e3.10}
|I_2|\leq  ct^{-1}\int_{\Omega \cap \{E_1 \cup E_2\}\cap \{|\xi
- \xi_s|> t^{-1/4}\}\cap \{ |\xi |>
t^{-1/4}\}}\frac{|D^{2}\Psi(\xi)|}{|\nabla\Psi(\xi)|^{2}}d\xi
\end{equation}
where $E_1=\{\xi \in {\mathbb{R}}^{n}, |\xi|<\frac{1}{\sqrt{2}}(1-t^{-1/4})\}$
 and $E_2=\{\xi \in {\mathbb{R}}^{n}, |\xi| >\frac{1}{\sqrt{2}}(1+t^{-1/4})\}$.
For the sequel, we need the following inequality: with $E_1$ and $E_2$
as defined in \eqref{e3.10}, we claim that on $\{E_1 \cup E_2\}\cap
\{|\xi - \xi_s|> t^{-1/4}\}\cap \{ |\xi |>
t^{-1/4}\}$,
\begin{equation} \label{e3.11}
|{\nabla}\Psi(\xi)|\geq ct^{-1/4}
\frac{|{\xi}|(1+|{\xi}|)}{(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}}.
\end{equation}
To prove this inequality, let us give the following
remark.

\begin{remark} \label{rmk3.3} \rm
Let $\xi_s \in \mathcal{E}_s$. Then for any $\xi \in {\mathbb{R}}^{n}$,
there exists an index set $J$ empty or not, with
$J \in \{1,\dots,n\}$ such that
\[
\mathop{\rm sgn}({\xi}_i)=
\begin{cases}- \mathop{\rm sgn}({\xi}_{si}) & \text{if } i \in J \\
 \mathop{\rm sgn}({\xi}_{si}) &\text{if }  i \in J^c.
\end{cases}
\]
\end{remark}

Let us prove now inequality \eqref{e3.11}. In view of Remark \ref{rmk3.3}, let
$\xi_s \in \mathcal{E}_s$ and let $J$ be an index set such that
\[
 \mathop{\rm sgn}({\xi}_i)
=\begin{cases} - \mathop{\rm sgn}({\xi}_{si}) &\text{if }  i \in J \\
 \mathop{\rm sgn}({\xi}_{si}) &\text{if } i \in J^c.
\end{cases}
\]
Moreover, define a point $\eta_s$ by
\[
 \eta_{si}=\begin{cases}
{\xi}_{si} &  \text{if } i \in J \\
 -{\xi}_{si} &  \text{if } i \in J^c
\end{cases}
\]
where $J$ is the same index set as above. Hence from Lemma \ref{lem3.2},
$\eta_s$ is also a stationary point and then thanks to Remark \ref{rmk3.3}
and the definition of $\eta_s$, we have on
$E_2=\{\xi \in {\mathbb{R}}^{n}, |\xi|>\frac{1}{\sqrt{2}}(1+t^{-1/4})\}$
and for $|\xi_s| \geq \frac{1}{\sqrt{2}}$,
\begin{align*}
|{\nabla}\Psi(\xi)| &=  |{\nabla}\Psi(\xi)-{\nabla}\Psi(\eta_s)|
=  |{\nabla}\phi(\xi)-{\nabla}\phi(\eta_s)|\\
&=|{\xi}\frac{(2|{\xi}|^2-1)}{(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}}-{\eta_s}\frac{(2|{\eta_s}|^2-1)}{(1-
|{\eta_s}|^2 + |{\eta_s}|^4)^{1/2}}| \\
&=  (\sum_{i \in J} + \sum_{i \in
J^c})|{\xi_i}\frac{(2|{\xi}|^2-1)}{(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}}-{\eta_{si}}\frac{(2|{\eta_s}|^2-1)}{(1-
|{\eta_s}|^2 + |{\eta_s}|^4)^{1/2}}| \\
&=  \sum_{i \in J} |{\xi_i}\frac{(2|{\xi}|^2-1)}{(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}}-{\xi_{si}}\frac{(2|{\xi_s}|^2-1)}{(1-
|{\xi_s}|^2 + |{\xi_s}|^4)^{1/2}}| \\
&\quad + \sum_{i \in J^c} |{\xi_i}\frac{(2|{\xi}|^2-1)}{(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}}+{\xi_{si}}\frac{(2|{\xi_s}|^2-1)}{(1-
|{\xi_s}|^2 + |{\xi_s}|^4)^{1/2}}| \\
&=  \sum_{i \in J} |{\mathop{\rm sgn}(\xi_i)|\xi_i|}\frac{(2|{\xi}|^2-1)}{(1-
|{\xi}|^2 +
|{\xi}|^4)^{1/2}}-{\mathop{\rm sgn}(\xi_{si})|\xi_{si}|}\frac{(2|{\xi_s}|^2-1)}{(1-
|{\xi_s}|^2 + |{\xi_s}|^4)^{1/2}}| \\
&\quad + \sum_{i \in J^c} |{\mathop{\rm sgn}(\xi_i)|\xi_i|}\frac{(2|{\xi}|^2-1)}{(1-
|{\xi}|^2 +
|{\xi}|^4)^{1/2}}+{\mathop{\rm sgn}(\xi_{si})|\xi_{si}|}\frac{(2|{\xi_s}|^2-1)}{(1-
|{\xi_s}|^2 + |{\xi_s}|^4)^{1/2}}| \\
&=  \sum_{i \in J} |{\mathop{\rm sgn}(\xi_i)|\xi_i|}\frac{(2|{\xi}|^2-1)}{(1-
|{\xi}|^2 +
|{\xi}|^4)^{1/2}}+{\mathop{\rm sgn}(\xi_{i})|\xi_{si}|}\frac{(2|{\xi_s}|^2-1)}{(1-
|{\xi_s}|^2 + |{\xi_s}|^4)^{1/2}}| \\
&\quad + \sum_{i \in J^c} |{\mathop{\rm sgn}(\xi_i)|\xi_i|}\frac{(2|{\xi}|^2-1)}{(1-
|{\xi}|^2 +
|{\xi}|^4)^{1/2}}+{\mathop{\rm sgn}(\xi_{i})|\xi_{si}|}\frac{(2|{\xi_s}|^2-1)}{(1-
|{\xi_s}|^2 + |{\xi_s}|^4)^{1/2}}| \\
&=  (\sum_{i \in J}+ \sum_{i \in J^c})
(\frac{|\xi_i|(2|{\xi}|^2-1)}{(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}}+\frac{|\xi_{si}|(2|{\xi_s}|^2-1)}{(1-
|{\xi_s}|^2 + |{\xi_s}|^4)^{1/2}}) \\
&\geq \frac{|\xi|(\sqrt{2}|{\xi}|-1)(\sqrt{2}|{\xi}|+1)}{(1-
|{\xi}|^2 + |{\xi}|^4)^{1/2}} \geq
t^{-1/4}\frac{|\xi|(|{\xi}|+1)}{(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}}.
\end{align*}
Again on $E_2=\{\xi \in {\mathbb{R}}^{n}, |\xi|>\frac{1}{\sqrt{2}}(1+t^{-1/4})\}$
but now for $|\xi_s| \leq \frac{1}{\sqrt{2}}$, we write thanks to
the definition of $\eta_s$,
\begin{align*}
|{\nabla}\Psi(\xi)| &=
|{\nabla}\phi(\xi)-{\nabla}\phi(-\eta_s)|\\
&=|{\xi}\frac{(2|{\xi}|^2-1)}{(1-|{\xi}|^2 +
|{\xi}|^4)^{1/2}}+{\eta_s}\frac{(2|{\eta_s}|^2-1)}{(1-
|{\eta_s}|^2 + |{\eta_s}|^4)^{1/2}}| \\
&=  |{\xi}\frac{(2|{\xi}|^2-1)}{(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}}-{\eta_s}\frac{(1-2|{\eta_s}|^2)}{(1-
|{\eta_s}|^2 + |{\eta_s}|^4)^{1/2}}|
\end{align*}
so that thanks to Remark \ref{rmk3.3} and the definition of $\eta_s$, we
follow the same lines as above to obtain
\begin{align*}
|{\nabla}\Psi(\xi)|&=|\xi|\frac{(2|{\xi}|^2-1)}{(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}}+|\xi_{s}|\frac{(1-2|{\xi_s}|^2)}{(1-
|{\xi_s}|^2 + |{\xi_s}|^4)^{1/2}}\\
& \geq
ct^{-1/4}\frac{|\xi|(|{\xi}|+1)}{(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}}.
\end{align*}
For this time, on $E_1=\{\xi \in {\mathbb{R}}^{n}, |\xi|
<\frac{1}{\sqrt{2}}(1-t^{-1/4})\}$ and if $|\xi_s| \geq
\frac{1}{\sqrt{2}}$, we write thanks to the definition of $\eta_s$
above,
\begin{align*}
|{\nabla}\Psi(\xi)| &=
|{\nabla}\phi(-\eta_s)-{\nabla}\phi(\xi)|\\
&=|-{\eta_s}\frac{(2|{\eta_s}|^2-1)}{(1- |{\eta_s}|^2 +
|{\eta_s}|^4)^{1/2}}-{\xi}\frac{(2|{\xi}|^2-1)}{(1-
|{\xi}|^2 +|{\xi}|^4)^{1/2}}| \\
&=  |-{\eta_s}\frac{(2|{\eta_s}|^2-1)}{(1- |{\eta_s}|^2 +
|{\eta_s}|^4)^{1/2}}+{\xi}\frac{(1-2|{\xi}|^2)}{(1-
|{\xi}|^2 + |{\xi}|^4)^{1/2}}|
\end{align*}
so that thanks to Remark \ref{rmk3.3} and the definition of $\eta_s$, we follow the
same lines as above to get
\begin{align*}
|{\nabla}\Psi(\xi)|&=|\xi_s|\frac{(2|{\xi_s}|^2-1)}{(1- |{\xi_s}|^2
+ |{\xi_s}|^4)^{1/2}}+|\xi|\frac{(1-2|{\xi}|^2)}{(1-
|{\xi}|^2 + |{\xi}|^4)^{1/2}} \\
&\geq ct^{-1/4}\frac{|\xi|(|{\xi}|+1)}{(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}}.
\end{align*}
Finally, still on $E_1=\{\xi \in {\mathbb{R}}^{n}, |\xi|
<\frac{1}{\sqrt{2}}(1-t^{-1/4})\}$ but now for $|\xi_s|
\leq \frac{1}{\sqrt{2}}$, we write with the definition of
$\eta_s$,
\begin{align*}
|{\nabla}\Psi(\xi)| &=  |{\nabla}\phi(\eta_s)-{\nabla}\phi(\xi)|\\
&=|{\eta_s}\frac{(2|{\eta_s}|^2-1)}{(1- |{\eta_s}|^2 +
|{\eta_s}|^4)^{1/2}}-{\xi}\frac{(2|{\xi}|^2-1)}{(1-
|{\xi}|^2 +|{\xi}|^4)^{1/2}}| \\
&=  |-{\eta_s}\frac{(1-2|{\eta_s}|^2)}{(1- |{\eta_s}|^2 +
|{\eta_s}|^4)^{1/2}}+{\xi}\frac{(1-2|{\xi}|^2)}{(1-
|{\xi}|^2 + |{\xi}|^4)^{1/2}}|
\end{align*}
 so that proceeding as above, we find thanks
to Remark \ref{rmk3.3} and the definition of $\eta_s$,
$$
|{\nabla}\Psi(\xi)| \geq
ct^{-1/4}\frac{|\xi|(|{\xi}|+1)}{(1- |{\xi}|^2 +
|{\xi}|^4)^{1/2}}.
$$
This completes  the proof of \eqref{e3.11}.

For the sequel, we need the following inequality which, thanks to
\eqref{e2.14} and \eqref{e3.11}, is obviously shown: That is: On
$$
\Omega\cap \{E_1 \cup E_2\}\cap \{|\xi - \xi_s|> t^{-1/4}\}\cap \{
|\xi |> t^{-1/4}\}
$$
where $\Omega$ is defined in \eqref{e3.5}
and $E_1$ and $E_2$ are defined in \eqref{e3.10}, we have
\begin{equation} \label{e3.12}
\frac{|D^{2}\Psi(\xi)|}{|{\nabla}\Psi(\xi)|^{2}} \leq
ct^{1/2}\frac{(1- |{\xi}|^2 +
|{\xi}|^4)}{|\xi|^{2}(|{\xi}|+1)^{2}} \leq
ct^{1/2}\frac{(1 + |{\xi}|)^2}{|\xi|^{2}}.
\end{equation}
Therefore, from \eqref{e3.10}, \eqref{e3.11}, \eqref{e3.12}, we get
\begin{equation} \label{e3.13}
\begin{aligned}
 |I_2| &\leq ct^{-1}\int_{\Omega \cap \{E_1 \cup
E_2\}\cap \{|\xi - \xi_s|> t^{-1/4}\}\cap \{ |\xi |>
t^{-1/4}\}}\frac{|D^{2}\Psi(\xi)|}{|\nabla\Psi(\xi)|^{2}}d\xi
\\
&\leq ct^{-1}t^{1/2}\int_{\Omega \cap \{E_1 \cup
E_2\}\cap \{|\xi - \xi_s|> t^{-1/4}\}\cap \{ |\xi |>
t^{-1/4}\}}|\xi|^{-2}(1 + |{\xi}|)^2d\xi
 \\
 &\leq ct^{-1/2}\int_{\Omega \cap E_1 \cap
 \{|\xi - \xi_s|> t^{-1/4}\}\cap \{ |\xi |>
t^{-1/4}\}}|\xi|^{-2}(1 + |{\xi}|)^2d\xi
 \\
&\quad + ct^{-1/2}\int_{\Omega \cap E_2\cap \{|\xi - \xi_s|>
t^{-1/4}\}\cap \{ |\xi |> t^{-1/4}\}}|\xi|^{-2}(1 + |{\xi}|)^2d\xi \\
&\leq ct^{-1/2} \{\int_{ \{ t^{-1/4}<|\xi |
 <\frac{1}{\sqrt{2}}(1-t^{-1/4})\}}
 |\xi|^{-2}d\xi
 +  \int_{ \{ \frac{1}{\sqrt{2}}(1+t^{-1/4})<|\xi |
 < t^{\frac{1}{4n}}\}}d\xi \}  \\
&\leq ct^{-1/2} \{ \int_{ \{ t^{-1/4}<r
 <\frac{1}{\sqrt{2}}(1-t^{-1/4})\}}
 r^{-2}r^{n-1}dr   \\
&\quad + \int_{ \{ \frac{1}{\sqrt{2}}(1+t^{-1/4})<r
 < t^{\frac{1}{4n}}\}}r^{n-1}dr \}  \\
&\leq ct^{-1/2} \{ \int_{ \{ t^{-1/4}<r
 <1\}} r^{-2}dr + t^{\frac{n-1}{4n}}\int_{ \{
 \frac{1}{\sqrt{2}}(1+t^{-1/4})<r
 < t^{\frac{1}{4n}}\}}dr \} \leq ct^{-1/4},
\end{aligned}
\end{equation}
where $E_1=\{\xi \in {\mathbb{R}}^{n}, |\xi|<\frac{1}{\sqrt{2}}(1-t^{-1/4})\}$
and $E_2=\{\xi \in {\mathbb{R}}^{n}, |\xi| >\frac{1}{\sqrt{2}}(1+t^{-1/4})\}$.
Hence, with the estimates on $I_1$ and $I_2$ in \eqref{e3.8} and
\eqref{e3.13} above, and thanks to \eqref{e3.7}, we are led to
\[ %3.14
|\check{q}_t(x)|_{\infty}\leq  ct^{-1/4} \quad \forall t\geq 1.
\]
Combining this inequality, \eqref{e3.6} and \eqref{e3.5}, we find
$$
|S_1(t)f_1(x)| \leq c
(1+t)^{-1/4}(|f_1|_{1}+\|f_1\|_{3n/2} \quad \forall t\geq 0,
$$
which with Remark \ref{rmk2.2} leads to \eqref{e3.1} for the case $j=1$. Let us
prove now the inequality \eqref{e3.1} for the case $j=2$
 If $0\leq t \leq1$, we have thanks to the Schwartz inequality and
the inequality \eqref{e2.5} on $\phi(\xi)$,
\begin{equation} \label{e3.15}
\begin{aligned}
|S_2(t)f_2(x)|
&= \frac{1}{{2}(2\pi)^{n}}|\int_{{\mathbb{R}}^{n}}
e^{it\Psi(\xi)}\frac{\hat{f_2}(\xi)}{\phi(\xi)} d\xi| \\
&\leq c\int_{{\mathbb{R}}^{n}}\frac{|\hat{f_2}(\xi)|}{|{\phi(\xi)}|} d\xi \\
&\leq c\int_{{\mathbb{R}}^{n}}\frac{|\hat{f_2}(\xi)|}{(1 +
 |{\xi}|^{2})} d\xi \\
&\leq c(\int_{{\mathbb{R}}^{n}}(1+|\xi|^{2})^{-n}
 d\xi)^{1/2}\|f_2\|_{n-2}   \\
&\leq c\|f_2\|_{n-2} \leq c(1+t)^{-1/4}\|f_2\|_{3n/2}.
\end{aligned}
\end{equation}
If $t\geq 1$, then we have with the notation $\Omega = \{\xi \in
{\mathbb{R}}^{n}, |\xi|\leq t^{\frac{1}{4n}}\}$ given above and thanks to
\eqref{e2.5}, the Schwartz and the Young inequalities,
\begin{equation} \label{e3.16}
\begin{aligned}
 |S_2(t)f_2(x)| &=
\frac{1}{{2}(2\pi)^{n}}
\Big|\Big(\int_\Omega+\int_{{\Omega}^{c}}\Big)e^{it\phi(\xi)+ix\cdot
\xi}\frac{\hat{f_2}}{\phi(\xi)}(\xi)d\xi\Big| \\
&\leq c|\check{k_t}(x)\ast f_2(x)|_{\infty}
+c\Big(\int_{{\Omega}^{c}}(1+|\xi|^{2})^{-\frac{3}{2}n}
d\xi\Big)^{1/2}\|f_2\|_{3n/2}  \\
&\leq c|\check{k_t}(x)|_{\infty}|f_2(x)|_{1} +
ct^{-1/4}\|f_2\|_{3n/2}
\end{aligned}
\end{equation}
where the function
$k_t(\xi)={\chi}_{\Omega}(\xi) e^{it\phi(\xi)}/ \phi(\xi)$.
On the other hand, with the same notations of $\Omega$ and
$\mathcal{A}$ given in \eqref{e3.5}, \eqref{e3.7}, \eqref{e3.9}, we write
\begin{equation} \label{e3.17}
\check{k_t}(x) = \frac{1}{(2\pi)^{n}}\Big(\int_{\Omega \cap
\mathcal{A}}+\int_{\Omega \cap
{\mathcal{A}}^{c}}\Big)e^{it\phi(\xi)+ix\cdot \xi}\frac{1}{\phi(\xi)}
d\xi=J_{1}+J_{2}.
\end{equation}
Then, with the use of the inequality \eqref{e2.5}, we follow the same
lines as the estimation of $I_1$ in \eqref{e3.8} to get
\begin{equation} \label{e3.18}
|J_{1}| \leq ct^{-1/4}.
\end{equation}
For the estimation of $J_2$, we need the following inequality
which with the use of \eqref{e2.5}, \eqref{e2.13}, \eqref{e2.14}, \eqref{e3.11}, \eqref{e3.12}, is
obviously proved. That is: On
\begin{equation} \label{e3.19}
\begin{gathered}
\Omega\cap \{E_1 \cup E_2\}\cap
\{|\xi - \xi_s|> t^{-1/4}\}\cap \{ |\xi |> t^{-1/4}\}, \\
\frac{|D^{2}\Psi(\xi)|}{|{\nabla}\Psi(\xi)|^{2}|\phi(\xi)|}
+\frac{|{\nabla}\phi(\xi)|}{|{\nabla}\Psi(\xi)||\phi(\xi)|^{2}}
\leq ct^{1/2}|\xi|^{-2}(1 + |{\xi}|^2).
\end{gathered}
\end{equation}
Therefore, following the same lines as in the proofs of \eqref{e3.9} and
\eqref{e3.13}, we find thanks to \eqref{e3.19} and integration by parts
(as for $I_2$),
\begin{equation} \label{e3.20}
\begin{aligned}
\quad |J_2| &=  |\int_{\Omega \cap
{\mathcal{A}}^{c}}e^{it\Psi(\xi)}\frac{1}{\phi(\xi)} d\xi|=
t^{-1}|\int_{\Omega \cap
{\mathcal{A}}^{c}}\frac{1}{\nabla{\Psi(\xi)}\phi(\xi)}\nabla(e^{it\Psi(\xi)})
d\xi| \\
&\leq  t^{-1}\{\int_{\Omega \cap
{\mathcal{A}}^{c}}|\nabla(\frac{1}{\nabla{\Psi(\xi)}\phi(\xi)})|
d\xi + \int_{\partial \{\Omega \cap {\mathcal{A}}^{c}
\}}\frac{d\xi}{|\nabla\Psi(\xi)||\phi(\xi)|}\} \\
&\leq  ct^{-1}\int_{\Omega \cap {\mathcal{A}}^{c}}
|\nabla(\frac{1}{\nabla{\Psi(\xi)}\phi(\xi)})|
d\xi  \\
&\leq  ct^{-1}\int_{\Omega \cap {\mathcal{A}}^{c}}
\{\frac{|D^{2}\Psi(\xi)|}{|\nabla\Psi(\xi)|^{2}|\phi(\xi)|} +
\frac{|{\nabla}\phi(\xi)|}{|{\nabla}\Psi(\xi)||\phi(\xi)|^{2}} \}
d\xi  \\
 &\leq ct^{-1/2}\int_{\Omega \cap E_1 \cap
 \{|\xi - \xi_s|> t^{-1/4}\}\cap \{ |\xi |>
t^{-1/4}\}}|\xi|^{-2}(1 + |{\xi}|^2)d\xi \\
&\quad + ct^{-1/2}\int_{\Omega \cap E_2\cap \{|\xi - \xi_s|>
t^{-1/4}\}\cap \{ |\xi |> t^{-1/4}\}}|\xi|^{-2}(1
+ |{\xi}|^2)d\xi  \\
&\leq  ct^{-1/4}.
\end{aligned}
\end{equation}
Hence \eqref{e3.17} and the estimates \eqref{e3.18} and \eqref{e3.20}
 on $J_1$ and
$J_2$ above, give
$$
|\check{k_t}(x)| \leq ct^{-1/4} \; \forall t \geq 1.
$$
Then, this with \eqref{e3.16} give
\[ %3.21
|S_2(t)f_2(x)| \leq c
(1+t)^{-1/4}(|f_2|_{1}+\|f_2\|_{3n/2} \; \forall
t\geq 1,
\]
Combining this inequality  and \eqref{e3.15}, we get with
Remark \ref{rmk2.2} the
desired inequality \eqref{e3.1} for the case $j=2$. This finishes up the
proof of inequality \eqref{e3.4}. In order to prove the inequality \eqref{e3.2}
of Lemma \ref{lem3.1}, we set $J^k = (1-\triangle)^{k/2}$ with $k \in \mathbb{R}$,
and we note that
\begin{align*}
J^kS_1(t)f_1(x)&=
 J^k{\mathcal{F}}^{-1}(\frac{1}{2}e^{it\phi(\xi)}\hat{f_1}(\xi))(x) \\
&={\mathcal{F}}^{-1}(\frac{1}{2}(1+|{\xi}|^{2})^{k/2}e^{it\phi(\xi)}
 \hat{f_1}(\xi))(x) \\
&=  \frac{1}{{2}(2\pi)^{n}} \int_{{\mathbb{R}}^{n}}(1
 +|{\xi}|^{2})^{k/2}e^{it\phi(\xi)+ix\cdot
\xi}\hat{f_1}(\xi)d\xi
\end{align*}
and
$$
J^kS_2(t)f_2(x) = \frac{1}{{2}(2\pi)^{n}} \int_{{\mathbb{R}}^{n}}(1
+|{\xi}|^{2})^{k/2}e^{it\phi(\xi)+ix\cdot
\xi}\frac{\hat{f_2}}{\phi(\xi)}(\xi)d\xi.
$$
Henceforth, we can prove the inequality \eqref{e3.2} of Lemma \ref{lem3.1}. We
begin with the case $j=1$:
For $0 \leq t \leq 1$, we follow the same lines as in \eqref{e3.5} and we
get
\begin{equation} \label{e3.22}
|J^kS_1(t)f_1(x)| \leq c
(1+t)^{-1/4}\|f_1\|_{\frac{3}{2}n+k}.
\end{equation}
If $t\geq 1$, let $p_t(\xi)=(1+|{\xi}|^{2})^{-\frac{5}{4}n}
{\chi}_{\Omega}(\xi)e^{it\phi(\xi)}$
where $\Omega = \{\xi \in {\mathbb{R}}^{n}, |\xi|\leq t^{\frac{1}{4n}}\}$
is defined above in \eqref{e3.6}. Then thanks to the Schwartz and the
Young inequalities, we have as in \eqref{e3.6},
\begin{equation} \label{e3.23}
\begin{aligned}
|J^{k}S_1(t)f_1(x)|
&=\frac{1}{{2}(2\pi)^{n}}\Big|\Big(\int_\Omega+\int_{{\Omega}^{c}}\Big)
e^{it\phi(\xi)+ix\cdot \xi}(1+|{\xi}|^{2}\Big)^{-\frac{k}{2}}
\hat{f_1}(\xi)d\xi\Big|   \\
&\leq c|\check{p_t}(x)\ast
(1-\triangle)^{\frac{(\frac{5}{2}n+k)}{2}}f_1(x)|_{\infty} \\
&\quad +c\Big(\int_{{\Omega}^{c}}(1+|\xi|^{2})^{-\frac{3}{2}n}
d\xi\Big)^{1/2}(\int_{{\Omega}^{c}}(1+|\xi|^{2})^{\frac{3}{2}n+k}|\hat{f_1}(\xi)|^{2}
d\xi)^{1/2}  \\
&\leq c|\check{p_t}(x)|_{\infty}\|f_1(x)\|_{\frac{5}{2}n+k,1} +
ct^{-1/4}\|f_1\|_{\frac{3}{2}n+k}.
\end{aligned}
\end{equation}
Then, with the same notation of $\mathcal{A}$ and $\Omega$ given
in \eqref{e3.7} above, we write:
\begin{equation} \label{e3.24}
\check{p_t}(x) = \frac{1}{(2\pi)^{n}}\Big(\int_{\Omega \cap
\mathcal{A}}+\int_{\Omega \cap {\mathcal{A}}^{c}}\Big)
(1+|{\xi}|^{2})^{-\frac{5}{4}n}e^{it\phi(\xi)+ix\cdot \xi}
d\xi=I'_{1}+I'_{2}
\end{equation}
and following the same lines as in \eqref{e3.8} we get
\begin{equation} \label{e3.25}
|I'_{1}|\leq c\int_{\Omega \cap \mathcal{A}}(1
+|{\xi}|^{2})^{-\frac{5}{4}n}d\xi\leq c\int_{\Omega \cap
\mathcal{A}}d\xi \leq ct^{-1/4}.
\end{equation}
For the sequel, we need the following inequality which with the
help of the inequalities \eqref{e2.5}, \eqref{e2.12}, \eqref{e2.13},
 \eqref{e3.11}, \eqref{e3.12}, is
easily proved. That is, for all $\xi \in {\mathbb{R}}^{n}$ and for any
given $\gamma \geq 0$,
\begin{equation} \label{e3.26}
|\nabla(\frac{1}{{\nabla}\Psi(\xi)(1 +
|{\xi}|^2)^{\frac{\gamma}{2}}})|
+|\nabla(\frac{1}{\phi(\xi){\nabla}{\Psi(\xi)}(1 +
|{\xi}|^2)^{\frac{\gamma}{2}}})|  \leq
ct^{1/2}|\xi|^{-2}(1 + |{\xi}|^2).
\end{equation}
Henceforth, thanks to the above inequality, we follow the same lines
as in the proof of \eqref{e3.20}, and using integration by parts, we get
\begin{equation} \label{e3.27}
\begin{aligned}
|I'_2| &=  \frac{1}{2(2\pi)^{n}}|\int_{\Omega \cap
{\mathcal{A}}^{c}}\frac{e^{it\Psi(\xi)}}{(1 +
|{\xi}|^2)^{\frac{\gamma}{2}}} d\xi|\\
&=  \frac{1}{2(2\pi)^{n}}t^{-1}|\int_{\Omega \cap
{\mathcal{A}}^{c}}\frac{\nabla(e^{it\Psi(\xi)})}{\nabla{\Psi(\xi)}(1
+ |{\xi}|^2)^{\frac{\gamma}{2}}} d\xi|    \\
&\leq  ct^{-1}\int_{\Omega \cap
{\mathcal{A}}^{c}}|\nabla(\frac{1}{\nabla\Psi(\xi)(1 +
|{\xi}|^2)^{\frac{\gamma}{2}}})| d\xi
 \\
 &\leq ct^{-1/2}\int_{\Omega \cap E_1 \cap
 \{|\xi - \xi_s|> t^{-1/4}\}\cap \{ |\xi |>
t^{-1/4}\}}|\xi|^{-2}(1 + |{\xi}|^2)d\xi
 \\
&\quad + ct^{-1/2}\int_{\Omega \cap E_2\cap \{|\xi - \xi_s|>
t^{-1/4}\}\cap \{ |\xi |> t^{-1/4}\}}|\xi|^{-2}(1
+ |{\xi}|^2)d\xi   \\
\leq  ct^{-1/4}.
\end{aligned}
\end{equation}
Therefore, \eqref{e3.24} and the estimates in \eqref{e3.25} and
\eqref{e3.27} of $I'_1$ and $I'_2$ above, give
$$
|\check{p_t}(x)| \leq ct^{-1/4} \; \quad t \geq 1.
$$
so that thanks to \eqref{e3.23} we get for all $t \geq 1$,
\begin{equation} \label{e3.28}
|J^kS_1(t)f_1(x)| \leq c
(1+t)^{-1/4}(\|f_1\|_{\frac{5}{2}n+k,1}+\|f_1\|_{\frac{3}{2}n+k}),
 \quad k \geq 0.
\end{equation}
Finally, combining \eqref{e3.22} and \eqref{e3.28}, and thanks to
Remark \ref{rmk2.2}, we find the case $j=1$ of the inequality
\eqref{e3.2} of Lemma \ref{lem3.1}.
Likewise, following the same lines as in the proof of the case
$j=1$ of \eqref{e3.2}, and with the use of the inequalities \eqref{e2.5} and
\eqref{e3.26}, we prove the case $j=2$ of the inequality \eqref{e3.2}. This,
with Remark \ref{rmk2.2} puts an end of the proof of the inequality \eqref{e3.2}
and consequently of Lemma \ref{lem3.1}.

Let us give now the following lemma which will be useful for the
${\mathbb{L}}^{p}-{\mathbb{L}}^{q}$ estimates.

\begin{lemma} \label{lem3.4}
Let $f_1, f_2 \in {\mathbb{L}}^{1}_{\frac{5}{2}n+k}({\mathbb{R}}^{n})$, $k\geq 0$,
$n\geq 1$. Then
\begin{equation} \label{e3.29}
\|V_j(t)f_j(x)\|_{k, \infty} \leq c
(1+t)^{-1/4}\|f_j\|_{\frac{5}{2}n+k,1},
 \quad j=1,2.
\end{equation}
\end{lemma}

\begin{proof}
Thanks to inequality \eqref{e3.2} of Lemma \ref{lem3.1}, it suffices to use
the Sobolev embedding $W^{n,1}({\mathbb{R}}^{n}) \subset {\mathbb{L}}^{2}({\mathbb{R}}^{n})$
 and we get
\begin{align*}
\|V_j(t)f_j(x)\|_{k, \infty}
&\leq c(1+t)^{-1/4}(\|f_j\|_{\frac{5}{2}n+k,1}+
\|f_j\|_{\frac{3}{2}n+k}) \\
&= c (1+t)^{-1/4}(\|f_j\|_{\frac{5}{2}n+k,1}+
|J^{\frac{3}{2}n+k}f_j|_{2}) \\
&\leq c (1+t)^{-1/4}(\|f_j\|_{\frac{5}{2}n+k,1}+
\|J^{\frac{3}{2}n+k}f_j\|_{n,1}) \\
&=  2c(1+t)^{-1/4}\|f_j\|_{\frac{5}{2}n+k,1},
 \; \; j=1,2.
\end{align*}
\end{proof}

To end with this section, we give the following lemma.

\begin{lemma} \label{lem3.5}
Let $f_1, f_2 \in {\mathbb{H}}^{k+\frac{5}{2}n+1}({\mathbb{R}}^{n})
\cap{\mathbb{L}}^{q}_{k+\frac{5}{2}n}({\mathbb{R}}^{n})$,
$k \geq 0$, $n\geq 1$. Then
\begin{equation} \label{e3.30}
\|V_j(t)f_j(x)\|_{k, p} \leq c
(1+t)^{-\frac{\theta}{4}}\|f_j\|_{\frac{5}{2}n+k,q},
 \quad j=1,2
\end{equation}
where $p=2/(1-\theta)$, $q=2/(1+\theta)$, $\theta \in ]0,1[$.
\end{lemma}

\begin{proof}
Thanks to \eqref{e2.6} and \eqref{e2.7}, we get for any
$k \in \mathbb{R}_{+}$,
\begin{equation} \label{e3.31}
\|V_j(t)f_j(x)\|_{k} \leq c\|f_j(x)\|_{k} \leq
c\|f_j\|_{\frac{5}{2}n+k},
 \quad j=1,2;
\end{equation}
that is
\begin{equation} \label{e3.32}
|J^{k}V_j(t)f_j(x)|_{2} \leq c|J^{\frac{5}{2}n+k}f_j(x)|_{2},
 \quad j=1,2.
\end{equation}
Moreover, from \eqref{e3.29} in Lemma \ref{lem3.4} we have
\begin{equation} \label{e3.33}
|J^{k}V_j(t)f_j(x)|_{\infty} \leq
c(1+t)^{-1/4}|J^{\frac{5}{2}n+k}f_j(x)|_{1},
 \quad j=1,2.
\end{equation}
We know that (see above),
\[
J^{k}V_j(t)(f_j(x))=V_j(t)(J^{k}f_j(x))
=J^{-\frac{5}{2}n}V_j(t)(J^{\frac{5}{2}n+k}f_j(x)).
\]
Therefore, thanks to \eqref{e3.32} and \eqref{e3.33},
we apply the interpolation
theorem (see \cite{b1}) for the evolution operator
$J^{-\frac{5}{2}n}V_j(t)$, $j=1,2$, and we find the inequality
\eqref{e3.30} of Lemma \ref{lem3.5}. This finishes up the proof of
Lemma \ref{lem3.5}.
\end{proof}


\section{Decay and Scattering results of Solutions to the Nonlinear Equation}

\begin{proof}[Proof of Theorem Theorem \ref{thm1.1}]
We write \eqref{e1.1} in its integral form as given in \eqref{e2.8}:
\begin{equation} \label{e4.1}
u(x,t)=V_1(t)f_1(x)+ V_2(t)f_2(x) +
\int^t_0V_2(t-\tau)(|u|^{\alpha }u)(\tau) d \tau.
\end{equation}
where $V_1(t)$ and $V_2(t)$ are defined in (2.3), (2.4). Then,
taking the ${\mathbb{L}}^{\infty}$ norm of the both sides of \eqref{e4.1} we get
thanks to Lemma \ref{lem3.1},
\begin{equation}
\begin{aligned} \label{e4.2}
|u(t)|_{\infty} &\leq c(1+t)^{-1/4}(|f_1|_{1}
+\|f_1\|_{3n/2}+ |f_2|_{1} +\|f_2\|_{3n/2}
\\
&\quad + c\int^t_0(1+(t-\tau))^{-1/4}(||u|^{\alpha }u|_{1}
+\|{|u|}^{\alpha
}u\|_{3n/2}(\tau) d\tau \\
 &\leq c(1+t)^{-1/4}(|f_1|_{1}
+\|f_1\|_{3n/2}+ |f_2|_{1} +\|f_2\|_{3n/2}\\
&\quad + c\int^t_0(1+(t-\tau))^{-1/4}(|u|^{\alpha
-1}_{\infty}|u|^{2}_{2} +|u|^{\alpha
}_{\infty}\|u\|_{3n/2}(\tau) d \tau.
\end{aligned}
\end{equation}
Then, we define the quantity
$$
Q(t)= \sup_{0\leq \tau \leq t} \{(1+\tau)^{ \frac{1}{4}}
|u(\tau)|_{\infty}+\|u(\tau)\|_{3n/2} \}.
$$
 From \eqref{e4.2}
\begin{equation} \label{e4.3}
\begin{aligned}
|u(t)|_{\infty} &\leq c(1+t)^{-1/4}(|f_1|_{1}
+\|f_1\|_{3n/2}+ |f_2|_{1} +\|f_2\|_{3n/2}
\\
&\quad + c{Q(t)}^{\alpha +1}\int^t_0(1+(t-\tau))^{-1/4}(1+\tau)^{- \frac{1}{4}(\alpha -1)} d\tau.
\end{aligned}
\end{equation}
But since for $\alpha> 5$,
\begin{align*}
& \int^t_0(1+(t-\tau))^{-1/4}(1+\tau)^{- \frac{1}{4}(\alpha -1)}
d\tau \\
&= (\int^{\frac{t}{2}}_{0} +
\int^{t}_{\frac{t}{2}})(1+(t-\tau))^{-1/4}(1+\tau)^{-
\frac{1}{4}(\alpha -1)} d \tau \leq c(1+t)^{-1/4}
\end{align*}
we deduce from \eqref{e4.3} that for $\alpha> 5$,
\begin{equation} \label{e4.4}
(1+t)^{\frac{1}{4}}|u(t)|_{\infty} \leq c\{|f_1|_{1}
+\|f_1\|_{3n/2}+ |f_2|_{1} +\|f_2\|_{3n/2} +
{Q(t)}^{\alpha +1}\}
\end{equation}
Furthermore, we get for $\alpha> 5$, thanks to the inequalities
\eqref{e2.6} and \eqref{e2.7} of Lemma \ref{lem2.4} and with \eqref{e4.1},
\begin{equation}
\begin{aligned} \label{e4.5}
\|u(t)\|_{3n/2} &\leq c\{ \|f_1\|_{3n/2}+
 \|f_2\|_{3n/2} + \int^t_0\|{|u|}^{\alpha
}u\|_{3n/2}(\tau) d\tau \}\\
 &\leq c\{\|f_1\|_{3n/2} +\|f_2\|_{3n/2} +
\int^t_0|u|^{\alpha
}_{\infty}\|u\|_{3n/2}(\tau) d \tau \} \\
 &\leq c\{\|f_1\|_{3n/2} +\|f_2\|_{3n/2} +
{Q(t)}^{\alpha +1}\int^t_0(1+\tau)^{- \frac{\alpha}{4}} d\tau\}
\\
 &\leq c\{\|f_1\|_{3n/2} +\|f_2\|_{3n/2} +
{Q(t)}^{\alpha +1}\}.
\end{aligned}
\end{equation}
Therefore, \eqref{e4.4} and \eqref{e4.5} give
\begin{equation} \label{e4.6}
Q(t) \leq c\{|f_1|_{1} +\|f_1\|_{3n/2}+ |f_2|_{1}
+\|f_2\|_{3n/2} + {Q(t)}^{\alpha +1}\}.
\end{equation}
Henceforth, thanks to the inequality \eqref{e4.6}, if
$ |f_1|_{1}+\|f_1\|_{3n/2}+ |f_2|_{1} +\|f_2\|_{3n/2} <\delta $
with $\delta >0$ small enough, we find that $Q(t)$ is
bounded. Indeed, it is well known that inequality \eqref{e4.6} is
satisfied if $Q(t) \in [0, \beta_1]\cup[\beta_2, \infty[$ with $0<
\beta_1 < \beta_2 < \infty$ since $\delta$ is small. Thereby,
since $Q(0) \leq 2\|f_1\|_{3n/2} <2\delta$ (because
${\mathbb{H}}^{\frac{3}{2}n}({\mathbb{R}}^{n})\subset{\mathbb{L}}^{\infty}({\mathbb{R}}^{n})$),
the continuity of $Q(t)$ and the inequality \eqref{e4.6} allow us to
conclude that $Q(t)$ remains bounded for all $t\geq 0$. Thus, we
have obtained a bound of $Q(t)$ and consequently an a-priori
estimate of the local solution which permit us to extend globally
the local solution of Theorem \ref{thm2.1}. Moreover, this a-priori
estimate provides the inequality \eqref{e1.2} of Theorem \ref{thm1.1}.
 For the
proof of the scattering result in the Theorem \ref{thm1.1}, we define
\begin{equation} \label{e4.7}
u_{+}(x,t)=u(x,t) + \int^{+\infty}_{t}V_2(t-\tau)(|u|^{\alpha
}u)(\tau) d \tau
\end{equation}
where $u(x,t)$ is the solution of \eqref{e1.1} given by
Theorem \ref{thm1.1}.
We only consider the case of $u_{+} \; (t\to +\infty)$
since the proof for the case of $u_{-} \; (t\to -\infty)$
is similar. Then, thanks to \eqref{e4.7} and with the use of the
inequalities \eqref{e2.7} of Lemma \ref{lem2.4} and \eqref{e1.2} of
Theorem \ref{thm1.1},
we have,
\begin{align*}
\|u(t)-u_{+}(t)\|_{2,2}
&\leq c\int^{+\infty}_{t} |(|u|^{\alpha }u)(\tau)|_{2} d \tau \\
&\leq  c\int^t_0 |u(\tau)|^{\alpha}_{\infty} |u(\tau)|_{2}d \tau  \\
&\leq c\int^{+\infty}_{t}(1+\tau)^{-\frac{\alpha}{4}}d\tau
\end{align*}
and the integral on the right-hand side approaches to zero as
$t\to  + \infty$, since by hypothesis of Theorem \ref{thm1.1},
$\alpha >5$.

Thereafter, set  $g_{+}(x)= f_2(x)
+\int^{+\infty}_{0}V_2(-\tau)(|u|^{\alpha}u)(\tau) d \tau.$ Then
thanks to \eqref{e4.7} and \eqref{e4.1}, we may write $u_{+}$ as
\begin{equation}
 u_{+}(x,t) = V_1(t)f(x)+ V_2(t)g_{+}(x).
\end{equation}
Therefore, we can see that $u_{+}(t)$ is a solution of the
linearized equation \eqref{e2.1}. This completes the proof of
Theorem \ref{thm1.1}.
\end{proof}

\begin{proof}[Proof of Theorem \ref{thm1.2}]
To prove Theorem \ref{thm1.2}, we need the following inequality of
Gagliardo-Nirenberg type.

\begin{lemma} \label{lem4.1}
Let $u$ belong to ${\mathbb{L}}^{p_{2}}({\mathbb{R}}^{n})$ and its derivatives
of order $m$, $D^{m}u$ belong to ${\mathbb{L}}^{r_{1}}({\mathbb{R}}^{n})$,
$1\leq  p_{2}$, $r_{1} \leq \infty$. For the derivatives
$D^{j}u$ $0\leq j < m$, the following inequalities hold:
$$
|D^{j}u|_{p_{1}} \leq c|D^{m}u|^{a}_{r_{1}}|u|^{1-a}_{p_{2}},
$$
where
$$
\frac{1}{p_{1}}=\frac{j}{n}+a(\frac{1}{r_1}-\frac{m}{n})+(1-a)\frac{1}{p_2},
$$
for all $a$ in the interval $\frac{j}{m}\leq a \leq 1$.
\end{lemma}
The proof of the above lemma can be found in \cite{n1}.

 Now, we  prove Theorem \ref{thm1.2}. We recall the notation
$p= 2/(1- \theta)$, $q= 1/(1+ \theta)$, $\theta \in ]0,1[$.
 Let $r>\frac{n}{p}$ and apply the norm ${\mathbb{L}}^{p}_{r}({\mathbb{R}}^{n})$
to the two sides of \eqref{e4.1}. Then, thanks to Lemma \ref{lem3.5}, the
Gagliardo-Nirenberg inequality in Lemma \ref{lem4.1} and Sobolev imbeddings
theorems,
\begin{equation} \label{e4.9}
\begin{aligned}
& \|u(x,t)\|_{r,p}\\
&\leq \|V_1(t)f(x)\|_{r,p}+\|V_2(t)g(x)\|_{r,p}
 + \int^t_0 \|V_2(t-\tau)(|u|^{\alpha -1}u)(\tau)\|_{r,p} d \tau  \\
 &\leq c(1+t)^{- \frac{\theta}{4}}(\|f_1\|_{\frac{5}{2}n+r,q}
 +\|f_2\|_{\frac{5}{2}n+r,q})
+ c\int^t_0(1+(t-\tau))^{- \frac{\theta}{4}}\||{u}|^{\alpha
  }u(\tau)\|_{\frac{5}{2}n+r,q} d\tau \\
&\leq c(1+t)^{- \frac{\theta}{4}}(\|f_1\|_{\frac{5}{2}n+r,q}
  +\|f_2\|_{\frac{5}{2}n+r,q})  \\
&\quad + c\int^t_0(1+(t-\tau))^{- \frac{\theta}{4}}\||{u}|^{\alpha
 }u(\tau)\|^{a}_{\frac{5}{2}n+r+1,2}||{u}|^{\alpha
 }u(\tau)|^{1-a}_{1} d\tau \\
&\leq c(1+t)^{- \frac{\theta}{4}}(\|f_1\|_{\frac{5}{2}n+r,q}
 +\|f_2\|_{\frac{5}{2}n+r,q})\\
&\quad + c\int^t_0(1+(t-\tau))^{- \frac{\theta}{4}}(|u|^{\alpha}_{\infty}
 \|u\|_{\frac{5}{2}n+r+1})^{a}(|u|^{\alpha-1}_{\infty}|u|^{2}_{2} )^{1-a}
 d \tau
\end{aligned}
\end{equation}
where
$$
a=\frac{(\frac{5}{2}n+r)/n+(1-\theta)/2}
{(\frac{5}{2}n+r+1)/n+1/2} =1-\frac{1/n+\theta/2}
{(\frac{5}{2}n+r+1)/n+1/2}.
$$
Set
$$
K(t)= \sup_{0\leq \tau \leq t} \{(1+\tau)^{ \frac{\theta}{4}}
\|u(\tau)\|_{r,p}+\|u(\tau)\|_{\frac{5}{2}n+r+1} \}.
$$
Hence, since (by hypothesis above) $r>n/p$, then thanks to the
Sobolev imbedding theorem
${\mathbb{L}}^{p}_{r}({\mathbb{R}}^{n})\subset{\mathbb{L}}^{\infty}({\mathbb{R}}^{n})$ and with
\eqref{e4.9}, we get for $\alpha >1+ 4/\theta$,
\begin{align*} %4.10
&\|u(x,t)\|_{r,p}\\
&\leq c(1+t)^{-\frac{\theta}{4}}(\|f_1\|_{\frac{5}{2}n+r,q}
+\|f_2\|_{\frac{5}{2}n+r,q}) \\
&\quad + c\int^t_0(1+(t-\tau))^{- \frac{\theta}{4}}(\|u\|^{\alpha
}_{r,p}\|u\|_{\frac{5}{2}n+r+1})^{a} (\|u\|^{\alpha-1}_{r,p}
\|u\|^{2}_{\frac{5}{2}n+r+1} )^{1-a} d \tau. \\
&\leq  c(1+t)^{- \frac{\theta}{4}}(\|f_1\|_{\frac{5}{2}n+r,q}
+\|f_2\|_{\frac{5}{2}n+r,q})
\\
&\quad + c\int^t_0(1+(t-\tau))^{- \frac{\theta}{4}}({K(t)}^{\alpha
+1}(1+\tau)^{- \alpha\frac{\theta}{4}})^{a}
({K(t)}^{\alpha +1}(1+\tau)^{- (\alpha-1)\frac{\theta}{4}} )^{1-a} d \tau.
\\
&\leq c(1+t)^{- \frac{\theta}{4}}(\|f_1\|_{\frac{5}{2}n+r,q}
  +\|f_2\|_{\frac{5}{2}n+r,q})\\
&\quad + {K(t)}^{\alpha +1}\int^t_0(1+(t-\tau))^{-
\frac{\theta}{4}}(1+\tau)^{- (\alpha-1)\frac{\theta}{4}}
d\tau \\
&\leq c(1+t)^{- \frac{\theta}{4}}\{\|f_1\|_{\frac{5}{2}n+r,q}
+\|f_2\|_{\frac{5}{2}n+r,q} + {K(t)}^{\alpha +1}\}.
\end{align*}
We deduce from the above inequality that for $\alpha >1+ 4/\theta$,
\begin{equation} \label{e4.11}
(1+t)^{ \frac{\theta}{4}}\|u(x,t)\|_{r,p} \leq
c\{\|f_1\|_{\frac{5}{2}n+r,q} +\|f_2\|_{\frac{5}{2}n+r,q} +
{K(t)}^{\alpha +1}\}.
\end{equation}
Furthermore, thanks to the inequalities \eqref{e2.6}, \eqref{e2.7}
of Lemma \ref{lem2.4}
and following the same lines as in the proof of the inequality
\eqref{e4.5}, we find with \eqref{e4.1} and for $\alpha >1+ 4/\theta$
\begin{equation} \label{e4.12}
\|u(x,t)\|_{\frac{5}{2}n+r+1} \leq c\{\|f_1\|_{\frac{5}{2}n+r+1}
+\|f_2\|_{\frac{5}{2}n+r+1} + {K(t)}^{\alpha +1}\}.
\end{equation}
Then the combination of \eqref{e4.11} and \eqref{e4.12} leads to the
inequality
\begin{equation} \label{e4.13}
K(t) \leq c\{\|f_1\|_{\frac{5}{2}n+r,q}
+\|f_2\|_{\frac{5}{2}n+r,q} + \|f_1\|_{\frac{5}{2}n+r+1}
+\|f_2\|_{\frac{5}{2}n+r+1} + {K(t)}^{\alpha +1}\}.
\end{equation}
Therefore, as above, we find that if
\[
\|f_1\|_{\frac{5}{2}n+r,q}
+\|f_2\|_{\frac{5}{2}n+r,q} + \|f_1\|_{\frac{5}{2}n+r+1}
+\|f_2\|_{\frac{5}{2}n+r+1}
\]
 is sufficiently small, then the
inequality \eqref{e4.13} gives $K(t) \leq c$ for all $t \geq 0$. This
implies that $\|u(x,t)\|_{r,p} \leq c(1+t)^{ -\frac{\theta}{4}}$
for all $t \geq 0$, and Theorem \ref{thm1.2} is proven.
\end{proof}

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