\documentclass[reqno]{amsart}
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\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2013 (2013), No. 132, pp. 1--23.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu}
\thanks{\copyright 2013 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2013/132\hfil Wave operators for KGS systems]
{Construction of wave operator for two-dimensional Klein-Gordon-Schr\"odinger
systems with Yukawa coupling}

\author[K. Tsuruta \hfil EJDE-2013/132\hfilneg]
{Kai Tsuruta}  % in alphabetical order

\address{Kai Tsuruta \newline
 Department of Applied Mathematical and Computational Sciences\\
 University of Iowa\\
 14 MacLean Hall\\
 Iowa City, IA 52245, USA}
\email{kai-tsuruta@uiowa.edu}

\thanks{Submitted November 2, 2012. Published May 29, 2013.}
\subjclass[2000]{35Q40, 35Q55}
\keywords{Klein-Gordon-Schr\"odinger; Yukawa coupling; wave operator}

\begin{abstract}
 We prove the existence of the wave operator for the
 Klein-Gordon-Schr\"odinger system with Yukawa coupling.
 This non-linearity type is below Strichartz scaling, and therefore
 classic perturbation methods will fail in any Strichartz space.
 Instead, we follow the ``first iteration method'' to handle these
 critical non-linearities.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}
\newtheorem{proposition}[theorem]{Proposition}
\newtheorem{corollary}[theorem]{Corollary}
\allowdisplaybreaks

\section{Introduction and Overview} \label{Intro}

We study the Klein-Gordon-Schr\"odinger system 
\begin{equation} \label{sys}
\begin{gathered}
 i\partial_t u + \frac{1}{2} \Delta u = \pm uv \\
 (\square + 1)v = \pm|\partial_x u|^2
\end{gathered}
\end{equation}
on $\mathbb{R}^2$ and show that wave operators exist under smallness 
conditions and
a control assumption on a single frequency band of the ``final data".

 A common choice of coupling, known as the Yukawa interaction, 
is to replace the non-linearity $\pm |\partial_x u|^2$ with $\pm |u|^2$. 
 With the Yukawa coupling, the system describes the interaction of a 
complex scalar nucleon field $u$ with a real scalar meson field $v$
 (see \cite{yukawa}). Our method only relies on the precise form of 
phase functions in frequency space and not on any conservation laws particular 
to our choice of non-linearity; therefore, the same method can be used to 
construct the wave operator in the case of Yukawa interaction.

Our purpose in this paper is to construct the wave operators for \eqref{sys}.  
Roughly, the positive-time wave operator of a non-linear dispersive equation is defined as 
follows: Suppose that for a solution $\psi_{lin}$ to the dispersive equation 
with no non-linearity and initial data $\psi_+$, there exists a unique 
solution $\psi$ to the non-linear equation with initial data $\psi_0$ such 
that $\psi$ behaves as $\psi_{lin}$ as $t\to \infty$
(this is known as scattering), then the positive-time wave operator is the map $W_+$ that 
takes $\psi_+$ to $\psi_0$. We similarly define the negative-time wave operator $W_-$ to consider behavior as $t\to -\infty$. In this paper, we will only construct $W_+$; $W_-$ can be constructed analogously.

As an explicit example, we discuss the positive-time wave operator for the Schr\"odinger 
equation with non-linearity $F(u)$. Solutions to the linear equation have 
the form $e^{\frac{1}{2}it\Delta}u_+$, where $u_+$ is the initial data at $t=0$. 
Suppose there is a space $X$ such that if for any $u_+ \in X$, there is a 
global strong $X$ solution $u$ to the non-linear Schr\"odinger equation 
with initial data $u_0$, such that
$$
\|u - e^{\frac{1}{2}it\Delta}u_+\|_X \to 0 \quad\text{as }t \to \infty.
$$
Then $W_+: X \to X$ is defined by $W_+(u_+) = u_0$.


In a space where the linear operator is an isometry, one can view 
the wave operator problem as an initial value problem in the limiting case 
$t_0 = \infty$. For instance, in the case of the Schr\"odinger equation
with non-linearity $F(u)$, the linear operator is an isometry in any $H^s$ space. In these spaces, we formally expect solutions to have the form
\begin{equation}
\label{sdh}
u(t) = e^{\frac{1}{2}it\Delta}u_+
- i \int_t^\infty e^{\frac{1}{2}i(t-s)\Delta}F(u)(s) ds,
\end{equation}
where $u_+$ is the scattered state of $u$.

The reason one expects a non-linear solution to have this linear behavior 
as $t\to \infty$ is that if the solutions tend to zero over time, 
then the non-linearity should tend to zero even faster as $t$ increases. 
Intuitively, this means that it should be easier to establish scattering 
for a higher degree non-linearity. However, high degree non-linearities 
augment the large values of the solution. These large values are usually the primary 
difficulty in establishing local well-posedness. Hence, the precise degree 
of non-linearity is very important in scattering theory.

Because the Klein-Gordon and Schr\"odinger equations both have a $t^{-d/2}$ 
decay as $t \to \infty$, quadratic non-linearities are something of a critical 
case in two dimensions. For example, it has been proven that on $\mathbb{R}^2$, one 
can construct the wave operators for the Schr\"odinger equation and the 
Klein-Gordon equation with power type non-linearities of the form 
$|\phi|^{p-1}\phi$ if $p >2$, but not if $1<p \leq 2$ 
(see, e.g., \cite{glassey,hayashi,strauss,tsutsumi}).

One explicit difficulty in dealing with quadratic-type non-linearities 
in two dimensions is our inability to use the Strichartz estimates. 
Perturbation methods that use the Strichartz estimates require 
the norm of the non-linearity $F(u)$ in some conjugate admissible pair 
space to be bounded by the norm of $u$ in an admissible pair space. 
However, since quadratic non-linearities fall below two-dimensional 
Strichartz scaling, we cannot hope to control $F(u)$ in this way.

Previous results for \eqref{sys} are mostly restricted to the Yukawa 
interaction and rely critically on conservation laws.
 Ozawa and Tsutsumi first studied this problem with the non-linearities
 $uv$ and $-|u|^2$ in \cite{ozawa}. They proved the existence of wave 
operators under certain smallness conditions on the scattered states, 
as well as the assumption that the Fourier support of the scattered 
state of $u$ was outside the unit disc. 
Shimomura\cite{shim1,shim2, shim3} improved these results with the 
same non-linearities. In \cite{shim1}, the existence of wave 
operators was established without any smallness condition on $v$'s scattered state, 
but the Fourier support of $u$'s scattered state was still required 
to be outside the unit disc. In \cite{shim2}, the support condition 
on $\hat{u}_+$ was substituted for a smallness condition on $v_+$ and a  
controllability assumption on the supports of $\hat{u}_+$ and $\hat{v}_+$ 
on a single circle. Finally, in \cite{shim3}, wave operators were shown to 
exist without any smallness condition on $v_+$ and no support conditions 
other than the controllability assumption of \cite{shim2}. 
All results rely on the energy method and first and second approximations 
to the asymptotic profiles of $u$ and $v$ to construct solutions on the the 
interval $[T,\infty)$ for some large $T$. Global well-posedness results 
were then used to extend the solution to $[0,\infty)$. 
Again, these results relied critically on the precise form of the non-linearity.

The Cauchy problem for the KGS system was solved in \cite{pecher1} 
and \cite{tzir} for the Yukawa coupling $-uv$ and $|u|^2$.  
In \cite{pecher1} the Fourier restriction norm method was used; in \cite{tzir} the  I-method was used. 
Both papers used Strichartz estimates on finite intervals and relied on energy and charge conservation to show existence of global solutions. The ability to use these conservation 
laws depends delicately on the non-linearities; hence, 
the specific choice of $-uv$ and $|u|^2$ was crucial in the result. 
In \cite{pecher2}, Pecher was able to show local existence without the
 use of energy conservation, and thus for a wider variety of 
Yukawa interactions ($\pm uv$ and $\pm |u|^2$).


\begin{subsection}{Notation} \label{notation}
We now discuss notation and introduce some operators.
We use the Fourier Transform defined by
$$
\mathcal{F}(g)(\xi) = \int_{\mathbb{R}^2} e^{-2\pi i \xi \cdot x} g(x) dx. 
$$
Sometimes we will use the notation $\hat{g}$ to denote $\mathcal{F}(g)$. 
We use the operator
$$ 
\square = \partial_{tt} - \Delta.
$$ 
The function $\langle \cdot \rangle$, known as the Japanese bracket, 
is defined for vectors by
$$ 
\langle x \rangle = \sqrt{1+|x|^2},
$$
while the operators $\langle \nabla \rangle$, $ e^{it\Delta}$, and 
$ e^{-it\langle \nabla \rangle}$ (known as Fourier multipliers) 
are defined by the identities
\[
 \mathcal{F}(\langle \nabla \rangle f ) = \sqrt{1+|\xi|^2} \hat{f},\quad
 \mathcal{F} (e^{it\Delta} f) = e^{-it|\xi|^2}\hat{f}, \quad 
 \mathcal{F}(e^{-it\langle \nabla \rangle} f) = e^{-it\sqrt{1+ |\xi|^2}}\hat{f}.
\]

We define the Klein-Gordon linear propagators $L$ and $\dot{L}$ by
\begin{gather*}
\mathcal{F}( L (f,g)) 
 = \cos(\langle \xi \rangle t)\hat{f} + \langle \xi \rangle^{-1} 
 \sin (\langle \xi \rangle t)\hat{g} \\
 \mathcal{F}(\dot{L}(f,g)) 
 = -\langle \xi \rangle^{-1}\sin(\langle \xi \rangle t)\hat{f} 
+ \cos(\langle \xi \rangle t) \hat{g}.
\end{gather*}
Let $\varphi(r)$ be a smooth cutoff function on $\mathbb{R}^+ \cup \{0\}$ 
that is congruent to 1 for $r \leq 1$ and supported on $[0,2]$. The 
Littlewood-Paley operators $P_k$ are then defined for $k \in \mathbb{Z}$ by
$$
\mathcal{F}(P_k f)(\xi) = (\varphi(|\xi|/2^k) 
- \varphi(|\xi|/2^{k-1}))\hat{f}(\xi).
$$
The space $L^p = L^p(\mathbb{R}^n)$ for $1\leq p < \infty$ is defined by 
its norm
$$ 
\|g\|_{L^p} = \Big(\int_{\mathbb{R}^n} |g|^p\Big)^{1/p} ,
$$
while $L^\infty$ is the space of all essentially bounded functions. 
From the $L^p$ spaces, we define the Sobolev spaces $W^{s,p}$ by the norm
$$
\|g\|_{W^{s,p}} = \|\langle \nabla \rangle^s g\|_{L^p}
$$
and denote $W^{s,2}$ as $H^s$.

We define the Besov Spaces $B_{p,q}^s$ by the norm
$$
\|g\|_{B_{p,q}^s} = \Big(\sum_{k \in \mathbb{Z}} \|\langle 2^k \rangle^s
 g\|^q_{L^P}\Big)^{1/q}.
$$
We also introduce the $Y$ space, which will be where we require the scattered 
states $u_+$ and $(v_+, \dot{v}_+)$ to be small. $Y$ is defined by the norm
$$
\|g\|_Y = \sum_{|\alpha + \beta| \leq 12} \|x^\alpha \partial^\beta g \|_{L^2} 
+ \|g\|_{W^{16,1}} + \|g\|_{H^{16}} + \|g\|_{B_{1,1}^6}.
$$
 For small $\delta$, we introduce the set $A_\delta$, defined as
$$
A_\delta = \{(\xi,\eta) \ | \ r_\xi - \delta \leq |\xi| \leq r_\xi 
+ \delta, \ r_\eta - \delta \leq |\eta| \leq r_\eta + \delta \},
$$
where the ordered pair $(r_\xi, r_\eta)$ is the unique solution on 
$\mathbb{R}^+$ to the system
\begin{gather*}
\frac{1}{2}r_\xi^2 - \frac{1}{2}(r_\xi - r_\eta)^2 
 - \langle r_\eta \rangle = 0\\
r_\xi - r_\eta\Big(1+ \frac{1}{\langle r_\eta \rangle} \Big) = 0.
\end{gather*} 
This system corresponds to the resonance set of a phase function.
 We will describe the meaning of resonance set and the role $A_\delta$ 
plays in our proof later in Subsection \ref{overview}. 
Roughly, we have that $(r_\xi, r_\eta) \approx (1.9002,1.1466)$.

In this paper, we use the following dispersive estimates on $\mathbb{R}^2$ 
for $t>0$:
\begin{gather*}
\|e^{\frac{1}{2}i\Delta t}f\|_{L_x^\infty} \lesssim t^{-1}\|f\|_{L_x^1} \\
\|e^{-i\langle \nabla \rangle t} P_k g\|_{L_x^\infty} 
 \lesssim t^{-1} \langle 2^k \rangle^2\|P_kg\|_{L_x^1}.
\end{gather*}
We will also use  the Coifman-Meyer theorem (see \cite{coif,graf}). 
The version of the theorem we will use is stated as follows:

\begin{theorem}[Coifman-Meyer Theorem]
Let $m(\xi,\eta)$ be a bounded function on $\mathbb{R}^2 \times \mathbb{R}^2$. 
Suppose that
\[
\sup_{k\in \mathbb{Z}} \|m(2^k \cdot) \hat{P}_0\|_{H_\zeta^{5}} < \infty,
\]
where $\zeta = (\xi,\eta)$ and $P_0$ is the $k=0$ Littlewood-Paley operator. Then the operator $T_m(\xi,\eta)$, defined by
\[ \widehat{T_m (f,g)}(\xi) = \int_{\mathbb{R}^2} m(\xi,\eta)\hat{f}(\xi-\eta)\hat{g}(\eta) d\eta, \]
maps $L^p \times L^q \to L^r$, provided $2 \leq p,q \leq \infty$ and $\frac{1}{p} + \frac{1}{q} = \frac{1}{r}.$
\end{theorem}
\end{subsection}

\begin{subsection}{Main Results}
\noindent We may now present our main result:

\begin{theorem}\label{main_thm1}
Suppose we have
$$
\operatorname{supp}(\hat{u}_+(\eta))  \cap \{ \eta : .75 \leq |\eta| \leq .76 \}
 = \emptyset,
$$
and that for a sufficiently small $\delta>0$,
\begin{align*}
& \|u_+\|_Y + \|v_+\|_Y + \|\dot{v}_+\|_Y  \leq \delta.
\end{align*}
Then there is a unique solution  $(u,v)$ to \eqref{sys} such that
\[ 
\|\langle t \rangle \int_t^\infty 
e^{\frac{1}{2}i(t-s)\Delta}u\cdot v ds \|_{L_t^\infty H_x^3} 
+ \|\langle t \rangle \int_t^\infty e^{-i(t-s)
\langle \nabla \rangle}\langle \nabla \rangle^{-1}
(\nabla u \cdot \overline{\nabla u} )ds\|_{L_t^\infty H_x^3} < \infty, 
\]
and as $t \to \infty$,
\[
 \|e^{\frac{1}{2}it\Delta}u_+ - u(t) \|_{H_x^3} + \|L(v_+,\dot{v}_+) 
- v(t)\|_{H_x^3} + \|\dot{L}(v_+, \dot{v}_+) - \partial_t v(t) \|_{H_x^2}
\to 0. 
\]
\end{theorem}

In our method of proof, we may relax the support condition 
on $\hat{u}_+$ to the assumption
\[
\hat{u}_+(\xi-\eta) [v_+(\eta) + i\langle \nabla 
\rangle^{-1}\dot{v}_+(\eta)] \equiv 0 \quad\text{on }A_\delta.
\]
One should note that this theorem is established for non-linearities 
for which it is impossible to use the energy conservation laws on 
which previous results have relied critically.
\end{subsection}

\begin{subsection}{Overview of Method}
\label{overview}
Our method follows the work in \cite{lizhang}. We briefly explain the 
steps for the proof as follows: 

\noindent\textbf{Step 1: Reformulation}
We transform the system into one that is first-order in time by the 
variable assignment $h = v + i\langle \nabla \rangle^{-1} \partial_t v$. 
In terms of $h$, the system \eqref{sys} is then transformed to
\begin{gather*}
i\partial_t u + \frac{1}{2} \Delta u = \pm u \operatorname{Re}(h) \\
-i\partial_t h + \langle \nabla \rangle h 
= \pm \langle \nabla \rangle ^{-1} (\nabla u \cdot \overline{\nabla u} ).
\end{gather*}
We can then reformulate the problem using Duhamel's formula as:
\[
 \begin{pmatrix}
u(t)\\
h(t)
\end{pmatrix} =
\begin{pmatrix}
  e^{i\frac{1}{2}t\Delta}u_+ \pm  i\int_t^\infty e^{i\frac{1}{2}(t-s)\Delta} 
u \cdot \operatorname{Re}(h) ds \\
 e^{-it\langle \nabla \rangle}h_+ \pm i \int_{t}^\infty e^{-i(t-s)
\langle \nabla \rangle}\langle \nabla \rangle^{-1} (\nabla u \cdot \overline{\nabla u} )ds
\end{pmatrix}.
\]

\noindent\textbf{Step 2: First Iterate Analysis}
With the system reformulated, we next look to show that the natural first 
iterate of our contraction scheme has a $\langle t \rangle^{-1}$ decay in $H^3$. 
More specifically, we show the bilinear operators
\begin{gather*}
B_1(f,g) =  \int_t^\infty e^{i\frac{1}{2}(t-s) \Delta }f\cdot 
 \operatorname{Re}(g)ds \\
B_2(f,g)  = \int_t^\infty e^{-i(t-s) \langle \nabla \rangle} \langle 
 \nabla \rangle^{-1}(\nabla f \cdot \overline{\nabla g} )ds
\end{gather*}
have the following property:
\[  \Big \| 
\begin{matrix}
B_1(e^{i\frac{1}{2}\Delta t}u_+, e^{-i\langle \nabla \rangle t}h_+)\\
B_2(e^{i\frac{1}{2}\Delta t}u_+, e^{i\frac{1}{2}\Delta t}u_+)
\end{matrix}  \Big \|_{H_x^3}
 \lesssim \frac{1}{\langle t \rangle}. 
\]
Establishing this decay on the first iterate comprises the majority of the paper. 
The decay estimates are achieved by going to the frequency domain and 
carefully analyzing the resonance points for the purpose of using 
stationary phase methods.

The phase functions to consider are:
\begin{gather*}
\phi_0(\xi,\eta) = \frac{1}{2} |\xi|^2 - \frac{1}{2}|\xi - \eta|^2 
 + \langle \eta \rangle,\\
\phi_1(\xi,\eta) = \frac{1}{2} |\xi|^2 - \frac{1}{2}|\xi-\eta|^2 
 - \langle \eta \rangle, \\
\phi_2(\xi,\eta) = \langle \xi \rangle - \frac{1}{2} |\xi-\eta|^2 
 + \frac{1}{2}|\eta|^2.
\end{gather*}

We call the sets where $\partial_\eta \phi_i = 0$ and $\phi_i = 0$ the 
space resonance and time resonance sets of $\phi_i$, respectively. 
Roughly, the method is to integrate by parts in frequency space away 
from the space resonance set and to integrate by parts in time away 
from the time resonance set.  Those points where both 
$\partial_\eta \phi_i =0$ and $\phi_i = 0$ comprise the resonance set 
and cause the greatest difficulty as we cannot integrate by parts in 
either variable.

When $i = 0,2$, the resonance set is empty. Thus, with carefully 
chosen cutoff functions, we can always integrate by parts in either 
frequency space or time. The phase function $\phi_1$ is the most 
problematic and requires the most delicate treatment. 
This is due to the existence of a resonant set. We have
\[
\partial_\eta \phi_1(\xi,\eta)
 = \xi - \eta\Big(1 + \frac{1}{\langle \eta \rangle}\Big).
\]
Hence, $\partial_\eta \phi_1(\xi,\eta)$  and $\phi_1(\xi,\eta)$ are both zero if $\xi$ and 
$\eta$ are co-linear and the moduli of $\xi$ and $\eta$ solve the system
\begin{gather*}
\frac{1}{2}|\xi|^2 - \frac{1}{2}(|\xi| - |\eta|)^2 - \langle |\eta| \rangle  = 0\,,\\
|\xi| - |\eta|\Big(1+ \frac{1}{\langle |\eta| \rangle}\Big)  = 0\,.
\end{gather*}
Hence, the resonance set takes the form
$$
\{ (\xi,\eta) : \  \xi \parallel \eta, \ |\xi| = r_\xi,\  |\eta| = r_\eta\}. 
$$
It is because of this set that we must  assume
\[
\hat{u}_+(\xi-\eta)\hat{h}_+(\eta) \equiv 0 \quad\text{on }A_\delta. 
\]


The method of stationary phase for oscillatory integrals is well known and 
many classical results can be found in \cite{stein}. The idea of carefully
 analyzing resonance points is presented in \cite{germain}. 

\noindent\textbf{Step 3: Bilinear Estimates}
We introduce the space $X$ where we construct our solutions' non-linear terms
by its norm
\[
\|f\|_X = \|\langle t \rangle f\|_{L_t^\infty H_x^3}. 
\]
Through the use of Sobolev embedding, we establish the following estimates 
on the above-defined bilinear operators:
\begin{gather*}
 \|B_i(f,g)\|_X  \lesssim  \|f\|_X \cdot \|g\|_X,\\
 \|B_i(f,g)\|_X  \lesssim  \|\langle t \rangle f\|_{L_t^\infty 
 W^{3,\infty}([0,\infty) \times \mathbb{R}^2)}  \cdot \|g\|_X,\\
 \|B_i(f,g)\|_X  \lesssim  \|f\|_X \cdot \|\langle t \rangle g\|_{L_t^\infty
  W^{3,\infty}([0,\infty) \times \mathbb{R}^2)}.
 \end{gather*}
 These estimates are used to establish our iterative scheme as a contraction.

\noindent\textbf{Step 4: Contraction in the X-Space}
Finally, we define two iteration schemes as follows:
\begin{gather*}
u_1 = e^{i\frac{1}{2}\Delta t}u_+, \\
h_1 = e^{-i\langle \nabla \rangle t}h_+,
\end{gather*}
and
\begin{gather*}
u_{k+1}  =  u_1 + B_1(u_k, h_k),\\
h_{k+1}  = h_1 + B_2(u_k,u_k).
\end{gather*}
These are then shown to be contractions in $X$. This is done through induction. 
In the process, we use the dispersive estimates of the linear propagators, 
the first iterate estimates established in Step 2, and the bilinear 
estimates from Step 3.

{\it Remark:} One should note that because the linear operators for 
the Schr\"odinger and Klein-Gordon equations are isometries in $H^3$,
the linear solutions to both equations do not exist in the space $X$. 
In this way, our scheme is very different from any perturbation methods.
\end{subsection}


The remainder of the paper is organized as follows:

In Section 2, we transform \eqref{sys} into a system that is first-order in time.
 We then introduce the $X$ space and establish the bilinear estimates on $X$. 
Finally, we prove the Duhamel operators are contractions on $X$ using induction 
and the bilinear estimates. Part of this proof relies on the assumption that 
the first iterate of our scheme is sufficiently small in $X$.

In Section 3, which accounts for the bulk of the paper, we prove that 
the assumption on the smallness of the first iterate is valid if 
the final data $(u_+, h_+)$ is sufficiently small in some suitable space. 
This is done by resonance analysis and stationary phase calculations.

\section{Reformulation, bilinear estimates, and contraction in the $X$-space}
\label{Prelim}

\begin{subsection}{Reformulation}

In this section, we will show the Duhamel operator maps are contractions. 
To this end, we rewrite the system \eqref{sys} into one that is first-order in time. To do this, we introduce the variable 
$h = v + i \langle \nabla \rangle^{-1} \partial_t v$. \eqref{sys} is 
then transformed to
\begin{equation}
\begin{gathered}
i\partial_t u + \frac{1}{2} \Delta u = \pm u\operatorname{Re}(h) \\
-i\partial_t h + \langle \nabla \rangle h
= \pm \langle \nabla \rangle ^{-1} (\nabla u \cdot \overline{\nabla u}).
\end{gathered}\label{l_duh}
\end{equation}
 If $(u,h)$ are to scatter to free solutions $(u_+,h_+)$ in $H^3$,
then we need
\begin{equation}
\label{scatter}
\|u - e^{\frac{1}{2}it\Delta} u_+\|_{H^3}
+ \|h - e^{-it\langle \nabla \rangle}h_+\|_{H^3} \to 0 \quad\text{as }
t \to \infty.
\end{equation}
Because the linear operators $ e^{\frac{1}{2}it\Delta}$ and
$ e^{-it\langle \nabla \rangle}$ are both isometries in $H^3$, \eqref{scatter}
is equivalent to
\[
\|e^{-\frac{1}{2}it\Delta}u - u_+\|_{H^3}
+ \|e^{it\langle \nabla \rangle}h - h_+\|_{H^3} \to 0 \quad\text{as }t\to \infty.
\]
Combining this with the Duhamel formulas for $u$ and $h$, we obtain
\begin{equation}\label{duhamel}
 \begin{pmatrix}
u(t)\\
h(t)
\end{pmatrix}=
\begin{pmatrix}
  e^{i\frac{1}{2}t\Delta}u_+ \pm  i\int_t^\infty e^{i\frac{1}{2}(t-s)\Delta}
u \cdot \operatorname{Re}(h) ds \\
 e^{-it\langle \nabla \rangle}h_+ \pm i \int_{t}^\infty e^{-i(t-s)
\langle \nabla \rangle}\langle \nabla \rangle^{-1} (\nabla u \cdot
\overline{\nabla u}) ds
\end{pmatrix}.
\end{equation}
Thus, we formally expect solutions to \eqref{sys} to have the form
of \eqref{duhamel}. We will find a pair $(u,h)^T$ that satisfies
\eqref{duhamel} and whose non-linear components are in $X$.
The work of showing that $(u,h)^T$ satisfies the conditions of \eqref{main_thm1}
is straightforward and omitted.
\end{subsection}

\begin{subsection}{Bilinear Estimates}

Based on \eqref{duhamel}, we define the following bilinear operators:
\begin{gather*}
B_1(f,g) =  \int_t^\infty e^{i\frac{1}{2}(t-s) \Delta }f\cdot
 \operatorname{Re}(g)ds \\
B_2(f,g)  = \int_t^\infty e^{-i(t-s) \langle \nabla \rangle} \langle 
\nabla \rangle^{-1}(\nabla f \cdot \overline{\nabla g}) ds.
\end{gather*}
Through these operators, we define our two iteration schemes:
\begin{gather*}
u_1 = e^{i\frac{1}{2}\Delta t}u_+, \\
h_1 = e^{-i\langle \nabla \rangle t}h_+,
\end{gather*}
and
\begin{gather*}
u_{k+1}  =  u_1 + B_1(u_k, h_k),\\
h_{k+1}  = h_1 + B_2(u_k,u_k).
\end{gather*}
To prove these schemes are contractions, we must show the bilinear 
operators have particular algebra estimates:

\begin{lemma} \label{algprops}
For $i = 1,2$, we have
\begin{gather}
 \|B_i(f,g)\|_X \lesssim  \|f\|_X \cdot \|g\|_X \label{ap1}, \\
 \|B_i(f,g)\|_X  \lesssim  \|\langle t \rangle f\|_{L_t^\infty W^{3,\infty}([0,\infty) \times \mathbb{R}^2)}  \cdot \|g\|_X \label{ap2},\\
 \|B_i(f,g)\|_X  \lesssim  \|f\|_X \cdot \|\langle t \rangle g\|_{L_t^\infty W^{3,\infty}([0,\infty) \times \mathbb{R}^2)}, \label{ap3}
 \end{gather}
where the space $X$ is defined by the norm
\[
\|g\|_X = \|\langle t \rangle g\|_{L_t^\infty H_x^3}. 
\]
\end{lemma}


\begin{proof}
This is a matter of direct calculation. For $i=2$, by the Minkowski inequality,
\[
\|B_2(f,g)\|_X \lesssim \Big\|\langle t \rangle 
\int_t^\infty \|\nabla f\cdot \overline{\nabla g} (s)\|_{H^2} ds 
\Big\|_{L_t^\infty ([0,\infty))}. 
\]
Next, by the H\"older inequality and Sobolev embedding,
\begin{align*}
 \|\nabla f\cdot \overline{\nabla g}(s) \|_{H^2} 
&\lesssim  \|\nabla^3 f\|_2 \|\nabla g\|_\infty 
 + \|\nabla^2 f\|_4 \|\nabla^2 g\|_4 + \|\nabla f\|_\infty \|\nabla^3 g\|_2 \\
&\lesssim  \langle s \rangle^{-2} \|f\|_X \|g\|_X .
\end{align*}
Combining these estimates, we have
\[
\|B_2(f,g)\|_X \lesssim  \sup_{t\geq 0} \langle t \rangle 
 \int_t^\infty \langle s \rangle^{-2} ds \cdot \|f\|_X \cdot \|g\|_X 
		\lesssim \|f\|_X \|g\|_X.
\]
This completes the proof of \eqref{ap1}. 
The proofs for \eqref{ap2} and \eqref{ap3} and the case $i=1$ are 
similar and we omit them.
\end{proof}
\end{subsection}

\begin{subsection}{Contraction in the $X$-Space}

With Lemma \eqref{algprops}, we may now show our iteration schemes are 
contractions in the $X$ space with fixed points satisfying \eqref{duhamel}.
We will use the estimate
\[ 
\|e^{itD}f\|_{L^\infty} \lesssim \frac{1}{\langle t \rangle} \|f\|_{B^3_{1,1}},
\]
where $D = \frac{1}{2}t\Delta \textrm{ or } -\langle \nabla \rangle$. 
For $t >1$, this bound comes from the dispersive estimates and the inequality
\[ 
\|f\|_{L^\infty} \lesssim \sum_{k \in \mathbb{Z}} \|P_k f\|_{L^\infty}. 
\]
For $ t \leq 1$, we use Sobolev embedding.
Denote $w_{k+1} = u_{k+1} - u_1$ and $z_{k+1} = h_{k+1} - h_1$ for
 $k \geq 1$. We are interested in the differences between successive values 
of $w_k$ and $z_k$ as, by construction, they are also the differences of 
successive values of $u_k$ and $h_k$, respectively. For $k \geq 2$, we have
\begin{equation}
\begin{aligned}
\| z_{k+2} - z_{k+1} \|_X
& = \| B_2(u_1 + w_{k+1}, u_1 + w_{k+1}) - B_2(u_1 + w_k, u_1 + w_k)\|_X   \\
& =  \|B_2(w_{k+1} - w_k, u_1 + w_{k+1}) + B_2(u_1 + w_k, w_{k+1} - w_k)\|_X   \\
& \lesssim \|w_{k+1} - w_{k}\|_X (\|w_k\|_X + \|w_{k+1}\|_X
 + \|\langle t \rangle u_1\|_{L_t^\infty W^{3,\infty}} ) \\
& \lesssim \|w_{k+1} - w_{k}\|_X (\|w_k\|_X + \|w_{k+1}\|_X
 + \|u_+\|_{B_{1,1}^6}).
\end{aligned} \label{diff2}
\end{equation}
Similarly,
\begin{equation}
\begin{aligned}
\| w_{k+2} - w_{k+1} \|_X
& = \|B_1(u_1 + w_{k+1}, h_1 + z_{k+1}) - B_1(u_1 + w_k, h_1 + z_k) \|_X  \\
&= \|B_1(w_{k+1} - w_k, h_1 + z_{k+1}) + B_1(u_1 + w_k, z_{k+1} - z_k ) \|_X  \\
& \lesssim \|w_{k+1} - w_k\|_X ( \|z_{k+1}\|_X + \|h_+\|_{B_{1,1}^6})\\
&\quad + \|z_{k+1} - z_k\|_X (  \|w_k\|_X+\|u_+\|_{B_{1,1}^6}).
\end{aligned} \label{diff1}
\end{equation}
With these estimates, we prove by induction that under suitable
conditions on the final data the iteration scheme is a contraction.
			
\begin{lemma} \label{smallz}
Let $w_j$, $z_j$, and the space $X$ be as defined above. Assume
\[
\|u_+\|_{B_{1,1}^6},\ \|h_+\|_{B_{1,1}^6} \leq \delta
\]
and
\[
\|B_1(u_1,h_1)\|_X, \ \|B_2(u_1,u_1)\|_X \leq \delta
\]
for some sufficiently small $\delta$. Then for $n \geq 3$, we have
\[
\|w_j\|_X, \ \|z_j\|_X \leq \delta \cdot \Big(\sum_{j=0}^n \frac{1}{2^l}\Big),
\quad \forall 2 \leq j \leq n.
\]
\end{lemma}

\begin{proof} 
This is a proof by induction on $n$. For $n=3$, we have
\begin{align*}
\|w_3\|_X 
&= \|B_1(w_2 + u_1, z_2 + h_1)\|_X \\
&\leq C_0\|w_2\|_X (\|z_2\|_X + \|h_+\|_{B_{1,1}^6}) 
 + \|z_2\|_X \|u_+\|_{B_{1,1}^6} + \|B_1(u_1,h_1)\|_X    \\
&\leq C_1\cdot \delta^2 + \delta.
\end{align*}
\begin{align*}
\|z_3\|_X & = \|B_2(w_2 + u_1, w_2 + h_1)\|_X \\
& \leq C_2 \|w_2\|_X ( \|u_+\|_{B_{1,1}^6} + \|h_+\|_{B_{1,1}^6}) 
 + \|B_2(u_1,h_1)\|_X \\
& \leq C_3 \cdot \delta^2 + \delta .
\end{align*}
Choosing $\delta$ sufficiently small completes the base case. 
Now consider $j = n+1$. By equations \eqref{diff2} and \eqref{diff1}, we have
\begin{align*}
\|w_{n+1} - w_n \|_X 
&\leq  C \cdot \|w_n-w_{n-1}\|_X \cdot (\|z_n\|_X +  \|h_+\|_{B_{1,1}^6}) \\
&\quad + C \cdot\|z_n - z_{n-1}\|_X \cdot (\|w_{n-1}\|_X + \|u_+\|_{B_{1,1}^6})\\
&\leq  (C \cdot 3 \delta)^{n-2} \cdot (\|w_3 - w_2\|_X + \|z_3 - z_2\|_X) \\
&\leq (C \cdot 3 \delta)^{n-2} \cdot 6\delta.
\end{align*}
\begin{align*}
\|z_{n+1} - z_n\|_X 
& \leq C' \cdot  \|w_n - w_{n-1} \|_X ( \|w_n\|_X + \|w_{n-1}\|_X 
 + \|u_+\|_{B_{1,1}^6} ) \\
& \leq (C'\cdot 5 \delta)(C \cdot 6 \delta)^{n-1} \cdot \|w_3 - w_2\|_X  \\
&\leq (C' \cdot 5 \delta)(C \cdot 6 \delta)^{n-1} \cdot 3\delta.
\end{align*}
Therefore, for sufficiently small $\delta$,
\begin{gather*}
\|w_{n+1}\|_X \leq  \|w_n\|_X + \delta \cdot \frac{1}{2^{n+1}} 
 \leq \delta \cdot\Big(\sum_{l=0}^{n+1}\frac{1}{2^l}\Big),
\\
\|z_{n+1}\|_X  \leq \|z_n\|_X + \delta \cdot \frac{1}{2^{n+1}} 
 \leq \delta \cdot\Big(\sum_{l=0}^{n+1}\frac{1}{2^l}\Big).
\end{gather*}
\end{proof}

\begin{corollary} \label{xsol}
With the hypothesis of Lemma \ref{smallz}, $w_k$ and $z_k$ are Cauchy 
sequences in $X$ and therefore have strong limits in $X$.
\end{corollary}

Using this corollary, we may show the existence of solutions to 
\eqref{duhamel} for positive time values if we assume small $u_+$
 and $h_+$ data in $B_{1,1}^6$ and that the first iterate of our scheme 
is sufficiently small in the $X$-space. The remainder of the paper 
will demonstrate that the latter can be achieved if we assume some suitable 
norm of the data $u_+$ and $h_+$ is small.
\end{subsection}


\section{Analysis of the first iterate}

The purpose of this section is to prove that under suitable conditions on 
$(u_+,h_+)$, $B_1(u_1,h_1)$ and $B_2(u_1,u_1)$ have a decay of
 $\langle t \rangle^{-1}$ in $H^3$.

By Plancherel's theorem, it is sufficient to measure an $L^2$ norm in 
the frequency domain. By definition, we have
\begin{equation} \label{fit}
\begin{pmatrix}
B_1(u_1,h_1) \\
B_2(u_1,u_1)
\end{pmatrix} =
\begin{pmatrix}
 \int_t^\infty e^{i\frac{1}{2}(t-s)\Delta}
 \big[\big(e^{i\frac{1}{2}s\Delta}u_+\big)\operatorname{Re}
\big(e^{-is\langle \nabla \rangle}h_+\big)\big] ds \\
 \int_t^\infty e^{-i(t-s)\langle \nabla \rangle}\langle \nabla \rangle^{-1}
\big[ \nabla\big(e^{i\frac{1}{2}s\Delta}u_+ \big) \cdot
\overline{\nabla \big(e^{i\frac{1}{2}s\Delta}u_+\big)} \big]ds
\end{pmatrix}.
\end{equation}
Hence, in the frequency domain,
\begin{align*}
\big\|\begin{pmatrix}
B_1(u_1,h_1)\\
B_2(u_1,u_1)
\end{pmatrix} \big\|_{H_x^3}
&\lesssim \big\|\begin{pmatrix}
\langle \xi \rangle^3 \mathcal{F}(B_1(u_1,h_1))\\
\langle \xi \rangle^3 \mathcal{F}(B_2(u_1,u_1))
\end{pmatrix} \big\|_{L_\xi^2} \\
&\lesssim
 \Big\| \begin{pmatrix} 	
	 \langle \xi \rangle^3 \int_t^\infty
 \int_{\mathbb{R}^2} e^{is\phi_j(\xi,\eta)}\hat{u}_+(\xi-\eta)\hat{g_j}(\eta)
 d\eta ds \\
	 \langle \xi \rangle^2  \int_t^\infty \int_{\mathbb{R}^2}
  e^{is\phi_2(\xi,\eta)}(\xi-\eta)\hat{u}_+(\xi-\eta)\eta\bar{\hat{u}}_+(-\eta)
 d\eta ds
\end{pmatrix} \Big\| _{L_\xi^2}.
\end{align*}
 Where $j = 0,1$; the phase functions $\phi_0$, $\phi_1$, and $\phi_2$
take the form
\begin{gather*}
\phi_0(\xi,\eta) = \frac{1}{2} |\xi|^2 - \frac{1}{2}|\xi-\eta|^2
  + \langle \eta \rangle \label{phi0},\\
\phi_1(\xi,\eta) = \frac{1}{2} |\xi|^2 - \frac{1}{2}|\xi-\eta|^2
 - \langle \eta \rangle \label{phi1},\\
\phi_2(\xi,\eta) = \langle \xi \rangle - \frac{1}{2} |\xi-\eta|^2
 + \frac{1}{2}|\eta|^2 \label{phi2};
\end{gather*}
and $g_0(\xi) = \bar{\hat{h}}_+(-\xi)$,  $g_1(\xi) = \hat{h}_+(\xi)$.

For readability, we will divide the work of establishing the necessary 
frequency bounds into several lemmas and propositions.

\begin{subsection}{Preliminary lemmas}

\begin{lemma} \label{hlem}
Let $h(\xi,\eta)$ be a bounded function, then for all $n \in \mathbb{N}$ and 
$f,g \in H^n$, we have
$$
\int_{\mathbb{R}^2}| h(\xi,\eta) \hat{f}(\xi - \eta) \hat{g}(\eta)|d\eta 
\lesssim \frac{1}{\langle \xi \rangle^n} \| f\|_{H_x^n} \|g\|_{H_x^n}.
$$
\end{lemma}

\begin{proof}
First, by the triangle inequality, we have 
$\langle \xi \rangle \leq \langle \xi-\eta \rangle +  \langle \eta \rangle $. 
Hence, $\langle \xi \rangle^n \lesssim \langle \xi-\eta \rangle^n
 + \langle \eta \rangle^n$. Thus, since $h(\xi,\eta)$ is assumed to be bounded, 
we have
\begin{align*}
\int_{\mathbb{R}^2} |h(\xi,\eta)\hat{f}(\xi - \eta) \hat{g}(\eta)|d\eta 
&\lesssim \int_{\mathbb{R}^2} \Big|\frac{\langle \xi-\eta \rangle^n 
  + \langle \eta \rangle^n}{\langle \xi \rangle^n} \hat{f}(\xi - \eta)
  \hat{g}(\eta)\Big|d\eta \\
& = \frac{1}{\langle \xi \rangle^n} \int_{\mathbb{R}^2} |\langle \xi
 -\eta \rangle^n \hat{f}(\xi - \eta)\hat{g}(\eta) 
 + \langle \eta \rangle^n \hat{g}(\eta) \hat{f}(\xi - \eta) | d\eta \\
& \lesssim \frac{1}{\langle \xi \rangle^n} (\|\langle \xi 
 - \cdot \rangle^n \hat{f}(\xi-\cdot)\hat{g}(\cdot)\|_{L_\eta^1} 
 + \|\langle \cdot \rangle^n \hat{g}(\cdot)\hat{f}(\xi-\cdot)\|_{L_\eta^1}). 
\end{align*}
By H\"older, we then have
\begin{align*}
\int_{\mathbb{R}^2} |h(\xi,\eta)\hat{f}(\xi - \eta) \hat{g}(\eta)|d\eta 
&\lesssim \frac{1}{\langle \xi \rangle^n}( \|f\|_{H_x^n}\|g\|_{L_x^2} 
 + \|g\|_{H_x^n}\|f\|_{L_x^2})\\
& \lesssim \frac{1}{\langle \xi \rangle^n}\|f\|_{H_x^n}\|g\|_{H_x^n}.
\end{align*}
\end{proof}

\begin{lemma}[Short Time Control] \label{t<1}
Suppose $0 \leq t \leq 1$ and $f,g \in H_x^5$, then for $j=0,1,2;$
$$
\Big\| \langle \xi \rangle^3\int_t^1 \int_{\mathbb{R}^2} 
e^{is\phi_j(\xi,\eta)} \hat{f}(\xi-\eta) \hat{g}(\eta)d\eta ds\Big\|_{L_\xi^2} 
\lesssim \frac{1}{\langle t \rangle} \|f\|_{H^5} \|g\|_{H^5}.
$$
\end{lemma}

\begin{proof}
Using Lemma \ref{hlem}, we have
\begin{align*}
\big|\int_t^1 \int_{\mathbb{R}^2} e^{is\phi_j(\xi,\eta)} \hat{f}(\xi-\eta) 
\hat{g}(\eta)d\eta ds \big| 
& \lesssim \int_t^1 \frac{1}{\langle \xi \rangle^5} \|f\|_{H_x^5} \|g\|_{H_x^5} 
ds \\
&\lesssim \frac{1}{\langle \xi \rangle^5} \|f\|_{H_x^5} \|g\|_{H_x^5} .
\end{align*}
Hence,
\begin{align*}
\Big\|\langle \xi \rangle^3 \int_t^1 \int_{\mathbb{R}^2} 
e^{is\phi_j(\xi,\eta)} \hat{f}(\xi-\eta) \hat{g}(\eta)d\eta ds\Big\|_{L_\xi^2} 
&\lesssim \|f\|_{H_x^5}\|g\|_{H_x^5} \|\frac{1}{\langle \xi 
 \rangle^2}\|_{L_\xi^2} \\
&\lesssim \frac{1}{\langle t \rangle}\|f\|_{H_x^5} \|g\|_{H_x^5}.
\end{align*}
\end{proof}

Using Lemma \ref{t<1}, it is now sufficient to estimate the first iterate 
just for the case $t \geq 1$. From henceforth, we will assume 
$t \geq 1$.

In the following lemma, we show how, away from the space resonance set,
 one may integrate by parts in time to obtain a $\langle t \rangle^{-1}$ 
decay in $H^3$.

\begin{lemma}[Decay Away from Space Resonance] \label{ibp_sp}
Let $\phi: \mathbb{R}^2 \times \mathbb{R}^2 \to \mathbb{R}$ such that 
$|\partial_\eta \phi(\xi,\eta)| \gtrsim s^{-\alpha_1}$ and 
$|\partial_\eta^k \phi(\xi,\eta)|\lesssim 1$ for all $k \geq 2$. 
Further, suppose $h(\xi,\eta)$ is a smooth function with 
$|\partial_\eta^j h(\xi,\eta)| \lesssim s^{j\cdot \alpha_2}$ for all 
$j \geq 1$. If $2\alpha_1 + \alpha_2 \leq \frac{2}{3}$, then
\begin{align*}
\Big\| \langle \xi \rangle^3\int_t^\infty \int_{\mathbb{R}^2} 
e^{is\phi(\xi,\eta)}h(\xi, \eta)\hat{f}(\xi-\eta)\hat{g}(\eta)d\eta ds
\Big\|_{L_\xi^2} \lesssim  \frac{1}{t} \|f\|_Y\|g\|_Y.
\end{align*}
\end{lemma}

\begin{proof}
Define the operator $D_\phi$ on a sufficiently smooth scalar-valued function
$f(\xi,\eta)$ by
$$
D_\phi f(\xi,\eta) = \frac{\nabla_\eta \phi(\xi,\eta)}{is|\nabla_\eta 
\phi(\xi,\eta)|^2} \cdot \nabla_\eta f(\xi,\eta). 
$$
By the inequality $2\alpha_1 + \alpha_2 \leq 2/3$, we have that there 
exists a natural number $N \leq 6$ such that $N(1-2\alpha_1 - \alpha_2) \geq 2$. 
Observe that
\[
D^N_\phi (e^{is\phi}) = e^{is\phi},
\]
so we may integrate by parts $N$ times using $D_\phi$. This yields one principal 
term and $N$ boundary terms. The boundary terms each vanish due to the decay 
assumptions on $f$ and $g$ and the assumption that 
$\partial_\eta \phi(\xi,\eta)$ is bounded below. Thus, we are only left 
to consider the principal term.
\begin{equation}
\begin{aligned}
&\Big|\int_t^\infty \int_{\mathbb{R}^2} e^{is\phi(\xi,\eta)}
 h(\xi, \eta)\hat{f}(\xi-\eta)\hat{g}(\eta)d\eta ds\Big| \\
&= \Big|\int_t^\infty \int_{R^2} e^{is\phi(\xi,\eta)} (D^t)^N[ h(\xi,\eta)
\hat{f}(\xi-\eta) \hat{g}(\eta)] d\eta ds \Big|.
\end{aligned} \label{nints}
\end{equation}
Let $X$ represent the right-hand side of \eqref{nints}. Inductively,
one can establish the bound
\begin{align*}
X &\lesssim  \int_t^\infty \int_{\mathbb{R}^2}
 \frac{1}{s^N}\Big(\frac{1}{|\nabla_\eta \phi(\xi,\eta)|^{2N}}
 + \frac{1}{|\nabla_\eta \phi(\xi,\eta)|^N}\Big) \\
&\quad\times \sum_{\ \beta_i \leq N} |\partial_\eta^{\beta_1} h(\xi,\eta)
 \partial_\eta^{\beta_2} \hat{f}(\xi-\eta) \partial^{\beta_3} \hat{g}(\eta)|
  d\eta ds.
\end{align*}
Hence,
\begin{align*}
X
& \lesssim \int_t^\infty \int_{\mathbb{R}^2}
 \frac{ s^{N\cdot \alpha_2}}{s^{N(1-2\alpha_1)}}\sum_{\beta_2, \beta_3 \leq N}
 |\partial_\eta^{\beta_2} \hat{f}(\xi-\eta) \partial_\eta^{\beta_3} \hat{g}(\eta)| d\eta ds \\
& \lesssim \int_t^\infty \frac{1}{s^2} \frac{1}{\langle \xi \rangle^5}
 \sum_{\beta_2, \beta_3 \leq N} (\|\mathcal{F}^{-1}(\partial_\eta^{\beta_2}
 \hat{f})\|_{H_x^{5}}\| \mathcal{F}^{-1}(\partial_\eta^{\beta_3}\hat{g})\|_{H_x^{5}}) \\
& \lesssim \frac{1} {\langle \xi \rangle^5 t} \sum_{\beta_2, \beta_3
 \leq N} (\|\mathcal{F}^{-1}(\partial_\eta^{\beta_2}\hat{f})\|_{H_x^{5}}\|
  \mathcal{F}^{-1}(\partial_\eta^{\beta_3}\hat{g})\|_{H_x^{5}}).
\end{align*}
\end{proof}

We may preform the same calculations with $(\xi-\eta)\hat{f}(\xi-\eta)$ and $\eta \hat{g}(\eta)$ replacing $\hat{f}(\xi-\eta)$ and $\hat{g}(\eta)$, respectively, to obtain the following corollary:

\begin{corollary} \label{ibp_spc}
Let $\phi(\xi,\eta)$ and $h(\xi,\eta)$ satisfy the conditions of Lemma 
\ref{ibp_sp}. Then 
\[ 
\Big\| \langle \xi \rangle^2\int_t^\infty \int_{\mathbb{R}^2} 
e^{is\phi(\xi,\eta)}h(\xi, \eta)(\xi-\eta)\hat{f}(\xi-\eta)\eta\hat{g}(\eta)d\eta 
ds\Big\|_{L_\xi^2} 
\lesssim  \frac{1}{t} \|f\|_Y\|g\|_Y.
 \]
\end{corollary}

Now that we have established a $\langle t \rangle^{-1}$ decay away from the 
frequency space resonance set, we will move on to establishing this decay 
away from the time resonance set. This will be accomplished by the use of 
integration in time and the following lemma:

\begin{lemma} \label{t_bdry}
Let $h(\xi,\eta)$ be a smooth, bounded function. Suppose that for 
$0\leq \gamma_1, \gamma_2 \leq 5$ we have
\[ 
|\partial^{\gamma_1}_\xi \partial^{\gamma_2}_\eta h(\xi,\eta)| 
\lesssim \langle \xi \rangle^{5} + \langle \eta \rangle^{5}.
\]
Then for $j=0, 1,2;$
\begin{equation}
\Big\|\langle \xi \rangle^3 \int_{\mathbb{R}^2}e^{it\phi_j(\xi,\eta)}
h(\xi,\eta) \hat{f}(\xi-\eta)\hat{g}(\eta)d\eta\Big\|_{L_\xi^2}
 \lesssim \frac{1}{t}\| f\|_{W_x^{15,1}} \|g\|_{H_x^{15}}. \label{t_bd}
\end{equation}
\end{lemma}


\begin{proof}
Let $K$ denote the left-hand side of \eqref{t_bd}. 
Then by Plancherel, we see
\[
K = \|T_h(e^{\frac{1}{2}it\Delta}f, e^{itD_j}g)\|_{H_x^3}. \\
\]
Here, $T_h$ is a bilinear operator with symbol $h(\xi,\eta)$; $D_0, D_1$ 
and $D_2$ are the operators $ \langle \nabla \rangle$, 
$-\langle \nabla \rangle$ and $-\Delta/2$, respectively. More precisely,
$$
\widehat{T_h(f_1,f_2)}(\xi) = \int h(\xi,\eta) \hat{f_1}(\xi-\eta) 
\hat{f_2}(\eta) d\eta. 
$$
Rewriting, we have
\begin{align*}
T_h(e^{\frac{1}{2}it\Delta}f, e^{itD_j}g)
& = \int \frac{h(\xi,\eta)}{\langle \eta \rangle^{12} 
 \langle \xi-\eta \rangle^{12}}\widehat{e^{\frac{1}{2}it\Delta} 
 \langle \nabla \rangle^{12} f}(\xi-\eta)\widehat{e^{itD_j}
 \langle \nabla \rangle^{12} g}(\eta) d\eta\\
& = T_{\tilde{h}}(e^{\frac{1}{2}it\Delta}\langle \nabla \rangle^{12} f,
  e^{itD_j}\langle \nabla \rangle^{12} g),
\end{align*}
where
\[
\tilde{h}(\xi,\eta) = \frac{h(\xi,\eta)}{\langle \eta \rangle^{12} 
\langle \xi -\eta \rangle^{12}}. 
\]
Therefore,
\begin{align*}
K &= \|T_h (e^{\frac{1}{2}it\Delta} f, e^{itD_j}g)\|_{H_x^3} \\
&\lesssim \sum_{ 0\leq \alpha \leq 3} \Big\| \xi^{\alpha} 
 \int \tilde{h}(\xi,\eta) \widehat{e^{\frac{1}{2}it\Delta}
 \langle \nabla \rangle^{12}f}(\xi-\eta) \widehat{e^{itD_j}
 \langle \nabla \rangle^{12} g}(\eta) d\eta  \Big\|_{L_\xi^2}\\
& \lesssim \sum_{ |\alpha'| \leq 3} \sum_{(\alpha_1,\alpha_2) = \alpha'} 
 \Big\| (\xi -\eta)^{\alpha_1}\eta^{\alpha_2}\\
&\quad \times \int \tilde{h}(\xi,\eta)
 \langle \xi - \eta \rangle^{12}\widehat{e^{\frac{1}{2}it\Delta}f}(\xi-\eta) 
 \langle \eta \rangle^{12} \widehat{e^{itD_j}g}(\eta) d\eta \Big\|_{L_\xi^2}\\
& \lesssim \sum_{|\alpha'| \leq 3}\sum_{(\alpha_1, \alpha_2) = \alpha'} 
 \big\|T_{\tilde{h}} (e^{\frac{1}{2}it\Delta} \langle \nabla \rangle^{12}
 \partial^{\alpha_1}f, e^{itD_j}\langle \nabla \rangle^{12}
  \partial^{\alpha_2}g)\big\|_{L_x^2}.
\end{align*}
Because we have assumed that for $0 < \gamma_1, \gamma_2 \leq 5,$
\[ 
|\partial^{\gamma_1}_\xi \partial^{\gamma_2}_\eta h(\xi,\eta)| 
\lesssim \langle \xi \rangle^{5} + \langle \eta \rangle^{5},
\]
$\tilde{h}$ is a Coifman-Meyer multiplier. Hence, using the Coifman-Meyer 
multiplier theorem and the dispersive estimate for the Schr\"odinger's 
fundamental solution, we have
\begin{align*}
&\sum_{0\leq\alpha_1, \alpha_2 \leq 3} \big\|T_{\tilde{h}}
(e^{\frac{1}{2}it\Delta} \langle \nabla \rangle^{12} \partial^{\alpha_1}f,
 e^{itD_j}\langle \nabla \rangle^{12} \partial^{\alpha_2}g)\big\|_{L_x^2} \\
& \lesssim \sum_{0 \leq\alpha_1 \leq 3} \big\|e^{\frac{1}{2}it\Delta}
 \langle \nabla \rangle^{12} \partial^{\alpha_1}f \big\|_\infty 
 \|g\|_{H^{15}} \\
&\lesssim \frac{1}{t} \|\langle \nabla \rangle^{15} f \|_{L_x^1} \|g\|_{H^{15}}.
\end{align*}
\end{proof}

With Lemma \ref{t_bdry}, we may now show how, away from the time resonance set, 
one may use integration in time to obtain a 
$\langle t \rangle^{-1}$ decay in $H^3$.

\begin{lemma}[Decay Away Time Resonance] \label{ibp_time}
Let $h(\xi,\eta)$ satisfy the bounds
\[ 
|\partial_\xi^{\alpha} \partial_\eta^{\beta} h(\xi,\eta) | \lesssim 1
\]
for $0 \leq \alpha, \beta \leq 5$. Furthermore, suppose 
$\phi_j(\xi,\eta) \gtrsim 1$  for $j = 0, 1, 2$. Then for $f, g \in Y,$ 
we have
\begin{align*}
\Big\|\langle \xi \rangle^3\int_t^\infty \int_{\mathbb{R}^2} 
e^{is\phi_j(\xi,\eta)} h(\xi,\eta) \hat{f}(\xi-\eta) \hat{g}(\eta) 
d\eta ds\Big\|_{L_\xi^2} &\lesssim \frac{1}{t}\|f \|_Y\|g\|_Y.
\end{align*}
\end{lemma}

\noindent{\it Remark:} For our purposes, $h(\xi,\eta)$ will typically be a smooth cutoff function.

\begin{proof}
Integration in time yields
\begin{align}
&\Big|\int_t^\infty \int_{\mathbb{R}^2} e^{is\phi_j(\xi,\eta)}
 h(\xi,\eta) \hat{f}(\xi-\eta) \hat{g}(\eta) d\eta ds\Big|  \nonumber\\
&\lesssim \lim_{M \to \infty}\Big|\int_{\mathbb{R}^2} 
e^{iM\phi_j(\xi,\eta)}\frac{h(\xi,\eta)}{\phi_j(\xi,\eta)} 
 \hat{f}(\xi-\eta)\hat{g}(\eta) d\eta \Big|\label{bd_intt} \\
&\quad + \Big|\int_{\mathbb{R}^2} e^{it\phi_j(\xi,\eta)}
\frac{h(\xi,\eta)}{\phi_j(\xi,\eta)} \hat{f}(\xi-\eta)\hat{g}(\eta) d\eta \Big|.
 \label{p_intt}
\end{align}
We wish to control both of these terms by using Lemma \ref{t_bdry}. 
Hence, we must verify that for $0\leq \gamma_1, \gamma_2 \leq 5$,
\[
\partial_\xi^{\gamma_1} \partial_\eta^{\gamma_2} 
\Big(\frac{h(\xi,\eta)}{\phi_j(\xi,\eta)}\Big) 
\lesssim \langle \xi \rangle^{5} + \langle \eta \rangle ^{5}. 
\]
By the bounds on $h(\xi,\eta)$ and $\phi_j(\xi,\eta)$, we have
\[
|\partial_\xi^{\gamma_1}\partial_\eta^{\gamma_2}(h(\xi,\eta) 
\cdot \phi_j^{-1}(\xi,\eta))| 
\lesssim \sum_{0 \leq \gamma_1, \gamma_2 \leq 5} 
|\partial_\xi^{\gamma_1} \partial_\eta^{\gamma_2} (\phi_j^{-1}(\xi,\eta))|.
\]
One can verify that for a multi-index $\gamma$ with $|\gamma| \geq 2$, 
$|\partial^{\gamma} \phi_j(\xi,\eta)| \lesssim 1$. Hence,
\begin{align*}
\sum_{0 \leq \gamma_1, \gamma_2 \leq 5} |\partial_\xi^{\gamma_1} 
\partial_\eta^{\gamma_2} (\phi_j^{-1}(\xi,\eta))| 
&\lesssim 1 + |\partial_\xi \phi_j(\xi,\eta)|^{5} + |\partial_\eta \phi_j(\xi,\eta)|^{5} \\
&\lesssim 1+ |\eta|^{5} + |\xi|^{5}.
\end{align*}
Thus, we may use Lemma \ref{t_bdry} to conclude
\[
\|\langle \xi \rangle^3 \eqref{p_intt}\|_{L_\xi^2} 
\lesssim \frac{1}{t} \|f\|_{W_x^{15,1}} \|g\|_{H_x^{15}}.
\]
Similarly,
\[
\|\eqref{bd_intt}\|_{L_\xi^2} \lesssim \lim_{M \to \infty} 
\frac{1}{M}\|f\|_{W_x^{12,1}} \|g\|_{H_x^{12}} = 0. 
\]
Furthermore, one can verify that 
\[
\|\eqref{bd_intt}\|_{H_\xi^2} 
\lesssim \sum_{|\alpha| \leq 2}\|x^\alpha f\|_{H_x^5}\|g\|_{H_x^5} 
\lesssim \|f\|_Y\|g\|_Y. 
\]
By Sobolev embedding, \eqref{bd_intt} is then an $L_\xi^\infty$ 
function whose $L_{\xi}^2$-norm is zero. Hence, it is identically 
zero for all $\xi$.
\end{proof}
\end{subsection}

With these lemmas in place, we are now ready to establish the necessary 
decay on $B_1(u_1,h_1)$ and $B_2(u_1,u_1)$. Recall that $u_1$ and $h_1$ 
are the linear evolutions of $u$ and $h$ respectively and that 
in the frequency space, $B_1(u_1,h_1)$ and $B_2(u_1,u_1)$ have the form
\begin{gather*}	
B_1(u_1,h_1) = \int_t^\infty \int_{\mathbb{R}^2} e^{is\phi_j(\xi,\eta)}
 \hat{u}_+(\xi-\eta)\hat{g_j}(\eta) d\eta ds \\
B_2(u_1,u_1)  = \int_t^\infty \int_{\mathbb{R}^2} e^{is\phi_2(\xi,\eta)}
 (\xi-\eta)\hat{u}_+(\xi-\eta)\eta\bar{\hat{u}}_+(-\eta) d\eta ds,
\end{gather*}
where $g_0(\xi) = \bar{\hat{h}}_+(-\xi)$ and $g_1(\xi) = \hat{h}_+(\xi)$.

The main idea is to identify the space and time resonance sets of each 
phase function $\phi_j$. Away from the space resonance set, 
we can establish the $\langle t \rangle^{-1}$ decay using Lemma \ref{ibp_sp}; 
away from the time resonance set, we use Lemma \ref{ibp_time}. 
Points where both $\phi_j$ and $\partial_\eta \phi_j$ are identically zero 
are in the resonance set. We avoid difficulties at these points by placing 
proper assumptions on the support of $\hat{u}_+$ and $\hat{h}_+$.

For the purposes of separating the integration regime based on resonance sets, 
we will use the function $\varphi$, which was defined in 
Subsection \ref{notation} and has the property that $\varphi(r) = 1$ for 
$0 \leq r$ and $\varphi(r) = 0$ for $r > 2$.

Recall that by Lemma \ref{t<1}, we need only establish decay for $t \geq 1$. 
Hence, it is enough to show the $H^3$ norms of $B_1(u_1,h_1)$ and 
$B_2(u_1,u_1)$ have a $t^{-1}$ decay.

\begin{subsection}{Analysis of $\phi_0$}
We first estimate $\|\langle \xi \rangle^3\mathcal{F}(B_1(u_1,h_1) \|_{L_\xi^2}$. 
We begin by considering the case when the phase function is $\phi_0$. 
In this case, one can verify that the set of $(\xi,\eta)$ for which 
$\phi_0(\xi,\eta) = 0$ is disjoint from the set for which 
$\partial_\eta \phi_0(\xi,\eta) = 0$. Thus, with carefully chosen cutoff 
functions, we can divide the space into several regimes and integrate by 
parts on every regime in either time or frequency space.

\begin{proposition} \label{phi1-}
Let
\[
\phi_0(\xi,\eta) =\frac{1}{2}|\xi|^2 - \frac{1}{2}|\xi-\eta|^2 
+ \langle \eta \rangle,
\]
 then we have 
\[
\Big\| \langle \xi \rangle^3 \int_t^\infty \int_{\mathbb{R}^2} 
e^{is\phi_0(\xi,\eta)}\hat{u}_+(\xi-\eta)\bar{\hat{h}}_+(-\eta) d\eta ds
\Big\|_{L_\xi^2} 
\lesssim \frac{1}{t}\|u_+\|_Y\|h_+\|_Y.
\]
\end{proposition}

\begin{proof}
Dividing the integration regime, we have
\begin{align}
&\int_t^\infty \int_{\mathbb{R}^2} e^{is\phi_0(\xi,\eta)}
 \hat{u}_+(\xi-\eta)\bar{\hat{h}}_+(-\eta) d\eta ds\\
&= \varphi(A|\xi|)\int_t^\infty \int_{\mathbb{R}^2} \varphi(2 |\eta|)
  e^{is\phi_0 (\xi,\eta)} \hat{u}_+(\xi-\eta) \bar{\hat{h}}_+(-\eta) d\eta ds
 \label{1t1}\\
&\quad + \varphi(A|\xi| )\int_t^\infty  
 \int_{\mathbb{R}^2}[1-\varphi(2|\eta|)] e^{is\phi_0 (\xi,\eta)} 
 \hat{u}_+(\xi-\eta) \bar{\hat{h}}_+(-\eta) d\eta ds 
\label{1t2}\\
&\quad + [1-\varphi(A |\xi|)] \int_t^\infty \int_{\mathbb{R}^2} \varphi(B|\eta 
 -\eta_0|)e^{is\phi_0 (\xi,\eta)} \hat{u}_+(\xi-\eta) \bar{\hat{h}}_+(-\eta) 
 d\eta ds 
 \label{1t3}\\
&\quad + [1-\varphi(A |\xi|)] \int_t^\infty  \int_{\mathbb{R}^2}
[1-\varphi(B|\eta-\eta_0|)] e^{is\phi_0 (\xi,\eta)} \hat{u}_+(\xi-\eta) 
\bar{\hat{h}}_+(-\eta) d\eta ds, \label{1t4}
\end{align}
where $A$ and $B$ are large constants and for each $\xi$, the point 
$\eta_0$ is the unique point in $\mathbb{R}^2$ such that
$$
\xi = \eta_0\Big(1-\frac{1}{\langle \eta_0 \rangle}\Big).
$$
Note that since
\[
\partial_\eta \phi_0(\xi,\eta) 
= \xi - \eta \Big(1-\frac{1}{\langle \eta \rangle} \Big),
\]
we have that for a fixed $\xi$, $\eta_0$ is the unique point for which 
$\partial_\eta \phi_0(\xi,\eta) = 0$.

We begin our estimate with \eqref{1t1}, where $|\xi| \leq 2A^{-1}$. 
On this regime, we have that $|\eta| \leq 1$. Hence,
\[
|\phi_0(\xi,\eta)| 
\geq \langle \eta \rangle - |\xi| |\eta| - \frac{1}{2}|\eta|^2 
\geq 1 - \frac{2}{A} - \frac{1}{2} 
\geq \frac{1}{4}.
\]
We therefore apply Lemma \ref{ibp_time} to obtain
$$
\|\langle \xi \rangle^3\eqref{1t1}\|_{L_\xi^2} 
\lesssim \frac{1}{t} \|u_+\|_Y \|h_+\|_Y.
$$
We next consider \eqref{1t2}. For this term, we have that $|\xi| \leq 2A^{-1}$
and we are integrating over a regime where $|\eta| \geq 1/2$. Thus,
\begin{align*}
|\partial_\eta \phi_0(\xi,\eta)| 
& = \Big|\xi - \eta\Big(1-\frac{1}{\langle \eta \rangle} \Big)\Big|\\
& \geq  |\eta|\Big(1-\frac{1}{\langle \eta \rangle}\Big)  - |\xi| \\
& \geq \frac{1}{2} \Big(1 - \frac{1}{\langle \frac{1}{2} \rangle}\Big) 
 - \frac{2}{A} \\
& \geq \frac{1}{100}.
\end{align*}
Using Lemma \ref{ibp_sp} with $\alpha_1, \alpha_2 = 0$ and $N=2$ yields
$$
\|\langle \xi \rangle^3\eqref{1t2} \|_{L_\xi^2} 
\lesssim \frac{1}{t} \|u_+\|_Y\|h_+\|_Y. 
$$
For \eqref{1t3}, we seek an absolute lower bound on $|\phi_0(\xi,\eta)|$ 
for the purpose of using Lemma \ref{ibp_time}. 
 Let $\theta$ be the angle between $\eta$ and $\eta_0$. By making $B$ 
large relative to $A$, we may assume $0 \leq \cos \theta$. 
Now we consider two cases:

 Case 1: $|\eta| \leq 2$. 
Then we have
\[
|\phi_0(\xi,\eta)| \geq \langle \eta \rangle - \frac{1}{2}|\eta|^2
					\geq \langle \eta \rangle - |\eta|.
\]
On the closed ball $B(0,2)$, $\langle \eta \rangle - |\eta|$ 
is a strictly positive function. Thus, it attains an absolute minimum 
greater than zero. Hence, $|\phi_0(\xi,\eta)| \geq \delta$.

 Case 2: $|\eta| > 2$.
Enlarging $B$ we may assume $\eta_0 \geq 1.99$ and $|\eta_0| \geq .99 |\eta|$. 
This gives
\begin{align*}
|\phi_0(\xi,\eta)| 
& \geq |\eta_0 |\Big(1-\frac{1}{\langle \eta_0 \rangle}\Big) |\eta| \cos \theta - \frac{1}{2}|\eta|^2 \\
& \geq  |\eta_0 |\Big(1-\frac{1}{\langle 1.99 \rangle}\Big) |\eta| \cos \theta - \frac{1}{2}|\eta|^2 \\
&\geq .53 |\eta_0\|\eta|\cos \theta - \frac{1}{2} |\eta|^2 \\
&\geq  |\eta| (.52\cos \theta - .5) .
\end{align*}
Because $|\eta|$ has a lower bound, we may, if necessary, again enlarge 
$B$ so that $\cos \theta \geq .99$. This gives $|\phi_0(\xi,\eta)| \geq 1/5$. 
With an absolute lower bound on $|\phi_0(\xi,\eta)|$, we may now use 
Lemma \ref{ibp_time} to conclude
$$
\|\langle \xi \rangle^3\eqref{1t3}\|_{L_\xi^2} 
\lesssim \frac{1}{t} \|u_+\|_Y\|h_+\|_Y.
$$
For \eqref{1t4}, we wish to show 
$|\partial_\eta \phi_0(\xi,\eta)| \gtrsim 1$, with the intent of using 
Lemma \ref{ibp_sp}. For this purpose, set $\theta$ as the angle between 
$\eta_0$ and $\eta$. We consider several cases:

Case 1: $|\theta| \geq \pi/2$.
Then
\[
|\partial_\eta \phi_0(\xi,\eta)| \geq |\xi| \geq \frac{1}{A}.
 \]

Case 2: $|\eta| \leq \frac{1}{2}|\xi|$.
Then
\[
|\partial_\eta \phi_0(\xi,\eta)| \geq |\xi| - |\eta| \geq \frac{1}{2A} .
\]

Case 3: $|\eta| \geq \frac{1}{2}|\xi|, \ \ 0\leq \theta <\pi/2$.
By our assumption on the distance between $\eta$ and $\eta_0$, we have
\[
B^{-2} \leq |\eta_0|^2 + |\eta|^2 - 2|\eta_0| |\eta| \cos\theta.
\]
Thus, we can bound $\cos \theta$ as
\[
0  \leq \cos \theta \leq  
\frac{|\eta_0|^2 + |\eta|^2 - \epsilon}{2|\eta_0| |\eta|},
\]
for $\epsilon = B^{-2}$. Hence,
\begin{align}
&|\partial_\eta \phi_0(\xi,\eta)|^2 \nonumber\\
& = |\eta_0|^2\Big(1-\frac{1}{\langle \eta_0 \rangle}\Big)^2 
 + |\eta|^2\Big(1-\frac{1}{\langle \eta \rangle}\Big)^2 
 - 2 |\eta_0| |\eta| \Big(1-\frac{1}{\langle \eta_0 \rangle}\Big)
 \Big(1- \frac{1}{\langle \eta \rangle}\Big)\cos\theta  \nonumber\\
&\gtrsim  |\eta_0|^2\Big(1-\frac{1}{\langle \eta_0 \rangle}\Big)^2 
 + |\eta|^2\Big(1-\frac{1}{\langle \eta \rangle}\Big)^2 
 - \Big(1-\frac{1}{\langle \eta_0 \rangle}\Big)
 \Big(1- \frac{1}{\langle \eta \rangle}\Big)\big(|\eta_0|^2 
 + |\eta|^2 - \epsilon\big)  \nonumber\\
&= \Big( \frac{1}{\langle \eta \rangle} - \frac{1}{\langle \eta_0 \rangle}\Big)
\Big[|\eta_0|^2\Big(1-\frac{1}{\langle \eta_0\rangle}\Big) - |\eta|^2
\Big(1-\frac{1}{\langle \eta \rangle}\Big)\Big] \label{to}\\
&\quad + \epsilon\Big(1-\frac{1}{\langle \eta_0 \rangle}\Big)
 \Big(1-\frac{1}{\langle \eta \rangle}\Big). \label{tt}
\end{align}
Since $|x| \geq |y|$ implies  
$\langle y \rangle^{-1} \geq \langle x \rangle^{-1}$, the term \eqref{to} 
is a product of two numbers with the same sign. Thus,
\begin{align*}
|\partial_\eta \phi_0(\xi,\eta)| 
& \gtrsim \epsilon \Big(1-\frac{1}{\langle \eta_0 \rangle}\Big)
 \Big(1-\frac{1}{\langle \eta \rangle}\Big) \\
& \gtrsim \epsilon\Big(1-\frac{1}{\langle A^{-1} \rangle}\Big)
 \Big(1 -\frac{1}{\langle \frac{1}{2A}\rangle} \Big)
 \gtrsim 1.
\end{align*}
 Hence, we may use Lemma \ref{ibp_sp} with $\alpha_1, \alpha_2 = 0$ and 
$N=2$ to obtain
$$
\|\langle \xi \rangle^3\eqref{1t4} \|_{L_\xi^2}
 \lesssim \frac{1}{t} \|u_+\|_Y\|h_+\|_Y.
$$
\end{proof}
\end{subsection}


\begin{subsection}{Analysis of $\phi_1$}
We now consider the case where the phase function is $\phi_1$. 
In this case, there is a set $A \subset \mathbb{R}^2 \times \mathbb{R}^2$ 
on which $\phi_1(\xi,\eta)$ and $\partial_\eta \phi_1(\xi,\eta)$ are both zero. 
On this set, we can not integrate by parts in either frequency space or time. 
Instead, we place appropriate assumptions on the final data so that 
$B_1(u_1,h_1)$ is identically zero around $A$.

\begin{proposition} \label{phi1-prop}
Let
\begin{align*}
\phi_1(\xi,\eta) = \frac{1}{2}|\xi|^2 - \frac{1}{2}|\xi-\eta|^2 
- \langle \eta \rangle,
\end{align*}
then the resonance set of $\phi_1$ is non-empty and contained in the set 
$A_\delta$ defined in Subsection \ref{notation}. If
$$
\hat{u}_+(\xi-\eta)\hat{h}_+(\eta) \equiv 0 \quad\text{on }A_\delta,
$$
then
\[
\Big\| \langle \xi \rangle^3 \int_t^\infty \int_{\mathbb{R}^2} 
e^{is\phi_1(\xi,\eta)}\hat{u}_+(\xi-\eta)\hat{h}_+(\eta) d\eta ds
\Big\|_{L_\xi^2} \lesssim \frac{1}{t}\|u_+\|_Y\|h_+\|_Y.
\]
\end{proposition}

\begin{proof}
Note that
\[
\partial_\eta \phi_1(\xi,\eta) = \xi - \eta\Big(1+\frac{1}{\langle 
\eta \rangle}\Big).
\]
Recall that $A_\delta$ is defined as
$$
A_\delta = \{(\xi,\eta) : r_\xi - \delta \leq |\xi| \leq r_\xi + \delta, 
\; r_\eta - \delta \leq |\eta| \leq r_\eta + \delta \},
$$
where the ordered pair $(r_\xi, r_\eta)$ is the unique solution on 
$\mathbb{R}^+$ to the system
\begin{gather*}
\frac{1}{2}r_\xi^2 - \frac{1}{2}(r_\xi - r_\eta)^2 - \langle r_\eta \rangle = 0\\
r_\xi - r_\eta\Big(1+ \frac{1}{\langle r_\eta \rangle} \Big) = 0.
\end{gather*}
From the form of $\partial_\eta \phi_1(\xi,\eta)$ and the definition 
of $r_\xi$ and $r_\eta$, one can see that if $(\xi_R,\eta_R)$ 
is a resonance point of $\phi_1(\xi,\eta)$, then $\xi$ is co-linear with 
$\eta$, $|\xi_R| = r_\xi$, and $|\eta_R| = r_\eta$.

Let $\psi_1$ be a smooth cutoff function on $\mathbb{R}$ supported on 
$[r_\xi-\delta/2, r_\xi + \delta/2]$ and congruent to 1 on 
$[r_\xi-\delta/4, r_\xi+\delta/4]$.  Similarly, let $\psi_2$ be a smooth 
cutoff function on $\mathbb{R}$ supported on 
$[r_\eta - \delta/2, r_\eta + \delta/2]$ and congruent to 1 on 
$[r_\eta - \delta/4, r_\eta + \delta/4]$.

For each $\xi$, we also define $\eta_0$ as the unique point in $\mathbb{R}^2$ 
such that
$$
\xi = \eta_0\Big(1+\frac{1}{\langle \eta_0 \rangle}\Big).
$$
Decomposing, we have
\begin{align}
&\int_t^\infty \int_{\mathbb{R}^2} 
 e^{is\phi_1(\xi,\eta)}\hat{u}_+(\xi-\eta)\hat{h}_+(\eta) d\eta ds\\
 &= \int_t^\infty \int_{\mathbb{R}^2} [1-\varphi(B|\eta-\eta_0|)]
 e^{is\phi_1(\xi,\eta)} \hat{u}_+(\xi-\eta) \hat{h}_+(\eta) d\eta ds \label{1t1-}\\
&\quad + \int_t^\infty \int_{\mathbb{R}^2} \varphi(B|\eta-\eta_0|)
 [1-\psi_1(|\xi|)\psi_2(|\eta|)]e^{is\phi_1(\xi,\eta)} 
 \hat{u}_+(\xi-\eta) \hat{h}_+(\eta) d\eta ds \label{1t2-}\\
&\quad + \int_t^\infty \int_{\mathbb{R}^2} \varphi(B|\eta-\eta_0|)
 \psi_1(|\xi|)\psi_2(|\eta|)e^{is\phi_1(\xi,\eta)} \hat{u}_+(\xi-\eta) 
 \hat{h}_+(\eta) d\eta ds. \label{1t3-}
\end{align}
We begin our estimates with \eqref{1t1-}. On its regime, we have
\begin{align*}
|\partial_\eta \phi_1(\xi,\eta)| 
&= \Big|\eta_0\Big(1+\frac{1}{\langle \eta_0 \rangle}\Big) - \eta\Big(1+\frac{1}{\langle \eta \rangle}\Big)\Big| \\
& \geq |\eta - \eta_0| \\
&\geq \frac{1}{B}.
\end{align*}
Hence, we may use Lemma \ref{ibp_sp} with $\alpha_1, \alpha_2 = 0$ and 
$N = 2$ to establish
$$
\|\langle \xi \rangle^3\eqref{1t1-}\|_{L_\xi^2} 
\lesssim \frac{1}{t}\|u_+\|_Y\|h_+\|_Y.
$$
We now bound \eqref{1t2-}. To this end, we first consider the values 
of $\phi_1$ at the stationary phase points. More precisely, 
we will first establish a lower bound on $\phi_1(\xi,\eta_0)$.  
If $|\xi| > 100$, then we have
\begin{align*}
|\phi_1(\xi,\eta_0)| 
& = |\xi \cdot \eta_0 - \frac{1}{2}|\eta_0| - \langle \eta_0 \rangle| \\
& = |\eta_0|^2\Big(1 + \frac{1}{\langle \eta_0 \rangle}\Big) - \frac{1}{2}|\eta_0|^2 - \langle \eta_0 \rangle \\
& \geq \frac{1}{2}|\eta_0|^2 - \langle \eta_0 \rangle 
 \geq 1.
\end{align*}
In the case of $|\xi| \leq 100$, we claim that by enlarging $B$ relative 
to $\delta$, we may assume
$$
0 \leq |\xi| \leq r_\xi - \delta/100,
$$
or
$$ 
r_\xi + \delta/100 \leq |\xi |\leq 100.
$$
To see this, assume for contradiction that some $\xi$ with
\[ 
|\xi| \in [r_\xi + \delta/100, r_\xi - \delta/100] 
\]
is in our integration regime. Then we also have that
\[
|\eta_0| \in [r_\eta - \delta/20, r_\eta + \delta/20].
\]
Hence, by enlarging $B$, we may use the term $\varphi(B|\eta-\eta_0|)$ 
to assume that
\[
|\eta| \in [r_\eta-\delta/10, r_\eta + \delta/10] .
\]
 But this point must then lie outside our integration regime as 
$1-\psi_1(|\xi|)\psi_2(|\eta|)= 0$. Thus, if $|\xi| \leq 100$, 
then we may also assume that
\[
|\xi| \notin [r_\xi  - \delta/100, r_\xi  + \delta/100]. 
\]
Furthermore, we know that either $\phi_1(\xi,\eta)$ or 
$\partial_\eta \phi_1(\xi,\eta)$ is non-zero at a given point in the regime 
of \eqref{1t2-}. Thus, $|\phi_1(\xi, \eta_0)| >0$ for all relevant $\xi$.
 We then have that $\phi_1(\xi,\eta_0)$ is a function in $\xi$ that 
is continuous and non-zero. This implies that on the compact set
\[ 
[0, r_\xi - \delta/100] \cup [r_\xi + \delta/100, 100],
\]
$\phi_1(\xi,\eta_0)$ must attain some absolute lower bound $\delta_0$. We also have that
$$
|\partial_\eta \phi_1(\xi,\eta)| \leq |\eta_0 - \eta| 
+ \Big|\frac{\eta_0}{\langle \eta_0 \rangle} 
- \frac{\eta}{\langle \eta \rangle} \Big| \leq 3.
$$
Then, by the Fundamental Theorem of Calculus,
$$
|\phi_1(\xi,\eta)| \geq \delta_0 - 3|\eta - \eta_0|.
$$
Enlarging $B$, we obtain $|\phi_1(\xi,\eta)| \geq \delta_0/2$. 
Now we may use Lemma \ref{ibp_time} to obtain
$$
\|\langle \xi \rangle^3 \eqref{1t2-}\|_{L_\xi^2}
 \lesssim \frac{1}{t}\|u_+\|_Y\|h_+\|_Y.
$$
Finally, \eqref{1t3-} is identically zero by the assumption that 
$\hat{u}_+(\xi-\eta)\hat{h}_+(\eta) \equiv 0$ on $A_\delta$.
\end{proof}
\end{subsection}


\begin{subsection}{Analysis of $\phi_2$}
Finally, we estimate 
$\|\langle \xi \rangle^3 \mathcal{F}(B_2(u_1,u_1))\|_{L_\xi^2}$.

\begin{proposition} \label{b_2_bd}
Let
\[
\phi_2(\xi,\eta) = \langle \xi \rangle - \frac{1}{2}|\xi-\eta|^2 
+ \frac{1}{2}|\eta|^2, 
\]
then we have 
\begin{align*}
\Big\| \langle \xi \rangle^2  \int_t^\infty \int_{\mathbb{R}^2} 
e^{is\phi_2(\xi,\eta)}(\xi-\eta)\hat{u}_+(\xi-\eta)\eta\bar{\hat{u}}_+(-\eta)
 d\eta ds \Big\|_{L_\xi^2} & \lesssim \frac{1}{t} \|u_+\|_Y^2.
\end{align*}
\end{proposition}

\begin{proof}
We decompose as follows:
\begin{align}
&\Big|\int_t^\infty \int_{\mathbb{R}^2} e^{is\phi_2(\xi,\eta)}
 (\xi-\eta)\hat{u}_+(\xi-\eta)\eta\bar{\hat{u}}_+(-\eta) d\eta ds \Big| \\
 & \lesssim \Big| \int_t^\infty \int_{\mathbb{R}^2} e^{is\phi_2(\xi,\eta)}
(1-\varphi(As^{1/3}|\xi|))(\xi-\eta)\hat{u}_+(\xi-\eta)\eta 
\bar{\hat{u}}_+(-\eta) d\eta ds\Big| \label{2t1}\\
&\quad +   \Big|\int_t^\infty \varphi(As^{1/3} |\xi|) 
 \int_{\mathbb{R}^2} \varphi\Big(\frac{|\eta|}{s^{1/3}}\Big) 
 e^{is\phi_2(\xi,\eta)}(\xi-\eta) \hat{u}_+(\xi-\eta)\eta  
 \bar{\hat{u}}_+(-\eta) d\eta ds\Big| \label{2t2}\\
&\quad +  \Big|\int_t^\infty \varphi(As^{1/3} |\xi|) 
 \int_{\mathbb{R}^2}\Big(1- \varphi\Big(\frac{|\eta|}{s^{1/3}}\Big)\Big) 
 e^{is\phi_2(\xi,\eta)} (\xi-\eta)\hat{u}_+(\xi-\eta)\eta \bar{\hat{u}}_+(-\eta) 
 d\eta ds \Big|. \label{2t3}
\end{align}
We first consider \eqref{2t1}, where 
$$ 
|\xi| \geq \frac{1}{As^{1/3}} .
$$
Since $\partial_\eta \phi_2(\xi,\eta) = \xi$, we may use 
Corollary \ref{ibp_spc}  with $\alpha_1 = 1/3$, $\alpha_2 = 0$, and 
index $N = 6$ to obtain
$$
\|\langle \xi \rangle^2 \eqref{2t1}\|_{L_\xi^2} \lesssim \frac{1}{t} \|u_+\|_Y^2.
$$
We now move on to estimating \eqref{2t2}, where we have
\[
|\xi| \leq \frac{2}{As^{1/3}} 
\]
and we are integrating over a regime on which
$$  
|\eta| \leq 2s^{1/3}.
$$
Therefore, we have
\begin{align*}
|\phi_2(\xi, \eta)| 
& \geq \langle \xi \rangle - \frac{1}{2}|\xi|^2 - |\xi \cdot \eta| \\
& \geq 1 - \frac{1}{4} - \frac{4}{A} \\
& \geq \frac{1}{2}.
\end{align*}
Though $\phi_2(\xi,\eta)$ has an absolute lower bound, we may not 
directly use Lemma \ref{ibp_time}, since our symbol $h$ is a function of time. 
Instead, we integrate by parts in time to obtain 
\begin{align}
\eqref{2t2} 
&\leq \Big|\varphi(At^{1/3}|\xi|) \int_{\mathbb{R}^2} e^{it\phi_2(\xi,\eta)}\frac{\varphi(|\eta|t^{-1/3})}{\phi_2(\xi,\eta)} (\xi-\eta)\hat{u}_+(\xi-\eta) \eta \bar{\hat{u}}_+(-\eta)d\eta \Big| \label{bt2} \\
&\quad + \Big| \int_{\mathbb{R}^2} (\xi-\eta)\hat{u}_+(\xi-\eta)\eta 
\bar{\hat{u}}_+(-\eta) \nonumber \\
&\quad\times \int_t^\infty \frac{e^{is\phi_2(\xi,\eta)}}{\phi_2(\xi,\eta)} 
\partial_s \Big( \varphi(As^{1/3}|\xi|) \varphi(|\eta|s^{-1/3})\Big) 
ds d\eta \Big|. \label{pt2}
\end{align}
Let $\psi(r)$ be a smooth function defined for $r \geq 0$ such that 
$\psi(r) = 0$ for $r < 1/4$ and $\psi(r) = 1 $ for $r \geq 1/2$. Then we have
\[ 
\eqref{bt2} \leq  \Big| \int_{\mathbb{R}^2} e^{it\phi_2(\xi,\eta)}
\frac{\psi(|\phi_2(\xi,\eta)|)\varphi(|\eta|t^{-1/3})}{\phi_2(\xi,\eta)} 
(\xi-\eta)\hat{u}_+(\xi-\eta) \eta \bar{\hat{u}}_+(-\eta)d\eta \Big|.
 \]
Using Lemma \ref{t_bdry}, we have
\begin{align*}
&\Big| \int_{\mathbb{R}^2} e^{it\phi_2(\xi,\eta)}
 \frac{\psi(|\phi_2(\xi,\eta)|)\varphi(|\eta|t^{-1/3})}{\phi_2(\xi,\eta)} 
 (\xi-\eta)\hat{u}_+(\xi-\eta) \eta \bar{\hat{u}}_+(-\eta)d\eta \Big|\\
&\lesssim \frac{1}{t} \|\nabla u_+\|_{W^{15,1}}\|\nabla u_+\|_{H_x^{15}} \\
&\lesssim \frac{1}{t}\|u_+\|_{Y}^2.
\end{align*}
For \eqref{pt2}, integrating by parts again yields
\begin{align}
\eqref{pt2} &\lesssim \Big| \int_{\mathbb{R}^2} 
\frac{e^{it\phi_2(\xi,\eta)}}{(\phi_2(\xi,\eta))^2}\partial_t
 \Big( \varphi(A|\xi|t^{1/3})\varphi(|\eta|t^{-1/3})\Big)\nonumber\\
&\quad\times (\xi-\eta) \hat{u}_+(\xi-\eta)\eta \bar{\hat{u}}_+(-\eta) d\eta 
\Big|
 \label{boundary2} \\
&\quad + \Big|\int_{\mathbb{R}^2} (\xi-\eta)\hat{u}_+(\xi-\eta) 
\eta \bar{\hat{u}}_+(-\eta) \nonumber\\
&\quad\times \int_t^\infty \frac{e^{is\phi_2(\xi,\eta)}}{(\phi_2(\xi,\eta))^2} 
\partial^2_s \Big(\varphi(As^{1/3}|\xi|)\varphi(|\eta|s^{-1/3})\Big) ds d\eta 
\Big|. \label{principle2}
\end{align}
Calculating, we have   
\begin{align*}
&\eqref{boundary2} \\
&\lesssim \Big| \int_{\mathbb{R}^2}
 \frac{e^{it\phi_2(\xi,\eta)}}{(\phi_2(\xi,\eta))^2}|\xi|t^{-2/3}
 \varphi'(A|\xi|t^{1/3})\varphi(|\eta|t^{-1/3}))(\xi-\eta)\hat{u}_+(\xi-\eta)
 \eta \bar{\hat{u}}_+(-\eta) d\eta \Big| \\
& \quad+\Big| \int_{\mathbb{R}^2} \frac{e^{it\phi_2(\xi,\eta)}}{(\phi_2(\xi,\eta))^2} 
 \varphi(A|\xi|t^{1/3})|\eta|t^{-4/3}\varphi'(|\eta|t^{-1/3}))(\xi-\eta)\hat{u}_+
 (\xi-\eta)\eta \bar{\hat{u}}_+(-\eta) d\eta \Big| \\
&\lesssim \int_{\mathbb{R}^2} \Big(|\xi|t^{-2/3}\varphi'(A|\xi|t^{1/3}) 
 + |\eta|t^{-4/3}\varphi'(|\eta|t^{-1/3})\Big)|(\xi-\eta)\hat{u}_+(\xi-\eta)
 \eta \bar{\hat{u}}_+(-\eta) |d\eta  \\
&\lesssim \frac{1}{t} \int_{\mathbb{R}^2} |(\xi-\eta)\hat{u}_+
 (\xi-\eta)\eta\bar{\hat{u}}_+(-\eta)| d\eta \\
& \lesssim \frac{1}{t\langle \xi \rangle^4} \|u_+\|_{H_x^5}^2.
\end{align*}
Similarly,
\begin{align*} \eqref{principle2}
&\lesssim \int_{\mathbb{R}^2} |(\xi-\eta)\hat{u}_+(\xi-\eta) \eta
 \bar{\hat{u}}_+(-\eta)|  \int_t^\infty \frac{1}{s^2} ds d\eta \\
&\lesssim \frac{1}{t\langle \xi \rangle^4} \|u_+\|^2_{H_x^5}.
\end{align*}
Finally, we bound \eqref{2t3}, where
\[
|\xi| \leq \frac{2}{As^{1/3}}
\]
and we are integrating over a regime on which
$$
 |\eta| \geq s^{1/3}.
$$
For this term, we can get the necessary decay by assuming high regularity
on $u_+$. More precisely,
\begin{align*}
&\|\langle \xi \rangle^3\eqref{2t3}\|_{L_\xi^2}\\
&\lesssim \Big\|\langle \xi \rangle^2\int_t^\infty \int_{\mathbb{R}^2}
\Big(1-\varphi\Big(\frac{|\eta|}{s^{1/3}}\Big)\Big)e^{is\phi_2(\xi,\eta)}
\frac{ \langle \eta \rangle^{6}}{\langle
 \eta \rangle^{6}}(\xi-\eta)\hat{u}_+(\xi-\eta)\eta \bar{\hat{u}}_+(-\eta)
 d\eta ds \Big\|\\
& \lesssim \Big\| \langle \xi \rangle^2\int_t^\infty \frac{1}{s^{2}}
 \int_{\mathbb{R}^2} \langle \eta \rangle^{7} | (\xi-\eta)\hat{u}_+(\xi - \eta)
 \bar{\hat{u}}_+(-\eta)| d\eta ds\Big\|_{L_\xi^2}\\
& \lesssim \Big\| \langle \xi \rangle^2\int_t^\infty \frac{1}{s^{2}
 \langle \xi \rangle^4} \| u_+\|_{H_x^{11}} \|u_+\|_{H_x^5} ds \Big\|_{L_\xi^2}\\
&\lesssim \frac{1}{t} \|u_+\|_{H_x^{11}}^2.
\end{align*}
\end{proof}
\end{subsection}

\subsection*{Acknowledgements}
I would like to thank Professors Xiaoyi Zhang and Dong Li for their 
suggestions, and Professor Zhang also for her help in 
proofreading this manuscript.
The research resulting in this paper was partially supported by grant 
DMS-0602242 from the  NSF VIGRE.

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\end{document}