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{\tenrm\ifodd\pageno\rightheadline \else
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\def\rightheadline{EJDE--1999/38\hfil Boundary behavior and estimates \hfil\folio}
\def\leftheadline{\folio\hfil 
J. Fleckinger,  E. M. Harrell II, \& F. de Th\'elin
\hfil EJDE--1999/38}
\voffset=2\baselineskip
\vbox {\eightrm\noindent\baselineskip 9pt %
 Electronic Journal of Differential Equations,
Vol. {\eightbf 1999}(1999) No.~38, pp. 1--19.\hfill\break
ISSN: 1072-6691. URL: http://ejde.math.swt.edu or http://ejde.math.unt.edu
\hfil\break ftp  ejde.math.swt.edu \quad ftp ejde.math.unt.edu (login: ftp)}
\footnote{}{\vbox{\hsize=10cm\eightrm\noindent\baselineskip 9pt %
1991 {\eighti Subject Classification:} 35J60, 35J70.
\hfil\break
{\eighti Key words and phrases:} $p$-Laplacian, Hardy inequlity,
principal eigenvalue, boundary estimate, boundary perturbation.
\hfil\break
\copyright 1999 Southwest Texas State University  and
University of North Texas.\hfil\break
Reproduction of this article by any means, in its entirety including
this notice, is permitted for non--commercial purposes. \hfil\break
Submitted July 13, 1999. Published September 28, 1999.\hfil\break
The second author was supported by Centre National pour la Recherche 
Scientifique and by NSF grant DMS-9622730.} }

\bigskip\bigskip

\centerline{BOUNDARY BEHAVIOR AND ESTIMATES FOR SOLUTIONS}
\centerline{OF EQUATIONS CONTAINING THE $p$-LAPLACIAN}
\medskip
\centerline{Jacqueline Fleckinger,  Evans M. Harrell II, 
            \& Fran\c cois de Th\'elin}
\bigskip\bigskip

{\eightrm\baselineskip=10pt \narrower
\centerline{\eightbf Abstract}
 We use ``Hardy-type'' inequalities to derive $L^q$ estimates 
for solutions of equations containing the $p$-Laplacian with $p>1$.
We begin by deriving some inequalities using elementary ideas
from an early article [B3] which has been largely overlooked.
Then we derive $L^q$ estimates of the boundary behavior of
test functions of finite energy, and consequently of
principal (positive) eigenfunctions of functionals containing
the $p$-Laplacian.  The estimates contain exponents known to be
sharp when $p=2$.  These lead to estimates of the effect of
boundary perturbation on the fundamental eigenvalue.  Finally,
we present global $L^q$ estimates of solutions of the Cauchy
problem for some initial-value problems containing the
$p$-Laplacian.
\bigskip}


\def\div{\mathop{\rm div}}




\bigbreak
\centerline{\bf I. Introduction}
\medskip
\noindent
Our interest in this article is to derive potentially sharp $L^q$
estimates for solutions of equations containing the $p$-Laplacian,
in analogy with what is known for the usual Laplacian ($p=2$), and 
to explore the consequences of those estimates.

The $p$-Laplacian has applications in several fields, including 
glaciology, non-Newtonian fluid flow, and flow through
porous media.  It has been intensively studied in the mathematical
literature both because of these applications and because it is a 
model for understanding degenerate elliptic equations and 
non-convex functionals.  We refer to the recent book
[D3] for discussion and further references.
Here we define the $p$-Laplacian
in the weak sense, i.e., by considering
the variational analysis of energy forms
$$
R(\zeta):={{\|\nabla \zeta({\bf x})\|_{L^p}^p + \int V({\bf x})
 |\zeta({\bf x})|^p  d^{N}x} \over {\|\zeta({\bf x})\|_{L^p}^p }} 
 \eqno(1.1)
$$
with $\zeta({\bf x}) \in C_c^{\infty}(\Omega)$, or by density
$W_{0}^{1,p}$,  where $\Omega$ is a 
connected open set in ${\Bbb R} ^N$, and $V({\bf x})$ is a given real-valued 
function.  
The nonlinear operator known as the $p$-Laplacian 
arises in the first variation of (1.1), which leads to the equation
$$
- \Delta_p u + V({\bf x}) u^{p-1} = \lambda u^{p-1}, \eqno(1.2)$$
where
$$
\Delta_p \zeta := \nabla \cdot \left( |\nabla \zeta|^{p-2} \nabla
\zeta \right). \eqno(1.3)$$


The behavior in the $L^q$ sense
of Dirichlet eigensolutions of elliptic linear operators 
($p=2$) near a boundary has been studied in [E2], [P1], [D2].
In particular it was shown in [D2] 
 that sharp rates of decay can be derived from
inequalities of ``Hardy type'',
 $${c}^{2}\int_{\Omega }{\left|{\nabla \zeta }\right|}^{2} \ge 
\int_{\Omega }{\left|{\zeta  \over d({\bf 
x})}\right|}^{2},\eqno(1.4)$$
where $d({\bf x})$ denotes the distance from ${\bf x}$ to the 
boundary of the domain $\Omega$.  (Actually, $d({\bf x})$
may be any absolutely continuous function satisfying ${|\bf \nabla}d|
\le 1$ on $\Omega$).

We were inspired by the philosophy of these articles to seek analogous 
estimates for the $p$-Laplacian.
$L^q$ versions of $(1.4)$ are known, with sharp constants, 
which would suffice for some of our purposes.  We begin, however, by
presenting a little--known but elementary way to derive inequalities
of this type, building on an idea of Boggio [B3], which 
predates related inequalities by Barta [B1], Duffin [D4],
Hardy [H1], and others.
This is the content of section II.

In section III we derive some estimates of boundary decay of 
principal eigenfunctions of equations containing the $p$-Laplacian
modeled on those of [D2] for elliptic second--order 
linear operators.  The argument there is based 
on the spectral theorem, however, which
is not available when $p \ne 2$, as the $p$-Laplacian is not
even linear then.  It was thus necessary to substantially
replace many of the technical ideas of [D2], and in the 
course of this we were obliged to establish certain special
algebraic inequalities
(see Section IV).  The constants involved in these inequalities 
determine the exponents appearing in the
theorems, and we have striven to make them as sharp as possible.
In Section V we use the estimates of Sections III and IV to estimate 
how the fundamental eigenvalue is affected by a boundary perturbation.

Finally, we turn our attention to the Cauchy problem for equations 
of the form 
	$$u^{p-2} u_{t} = \Delta_{p} u - V({\bf x}) u^{p-1},$$ 
and prove an $L^q$ growth estimate for solutions.

In the interest of clarity we have restricted ourselves to Euclidean 
domains and $p$-Laplacians without weights, and we have not 
attempted to specify the widest class of potentials $V({\bf x})$
for which our estimates remain valid. 
We anticipate few if any technical barriers
in extending our results to manifolds or to
$V({\bf x})$ in function classes analogous to those treated in [S1].

\noindent
{\bf Notation and terminology}

\noindent  A function or vector field is of class $AC^1$ if all components are 
differentiable by the Cartesian coordinates and the derivatives are
absolutely continuous.

\noindent  A {\it distance function} may be any absolutely continuous function
$d({\bf x})$
satisfying ${|\bf \nabla}d| \le 1$ a.e. on $\Omega$.  We invariably
choose $d({\bf x})$
as the distance from {\bf x} to the boundary of $\Omega$.

\noindent  The {\it energy form} is the functional $R(\zeta)$ defined in
$(1.1)$.

\noindent  The {\it Hardy constant} is the positive number defined in $(3.3)$,
which extends  $(1.4)$ to the case where $p\neq 2$. 

\noindent  The {\it index} $p$ is a real number in $(1, \infty)$, and the
{\it dual index} is $p' := p/(p-1)$.

\noindent  The {\it inradius} of a domain $\Omega$ is the supremum of the 
radii of all balls included in $\Omega$.

\noindent  The $p$-Laplacian is the nonlinear operator defined in $(1.3)$.

\noindent  The {\it principal eigenvalue} which appears in $(1.2)$ is
$$\lambda_1 =\inf\limits_{\zeta \in W_0^{1,p}(\Omega), \zeta 
\not \equiv 0} 
{\int_ {\Omega }\left({{\left|{\nabla \zeta }\right|}^{p}
+V({\bf x}){\left|{\zeta }\right|}^{p}}\right)d^N x \over 
\int_{\Omega }{\left|{\zeta }\right|} ^{p}d^N
x}.\eqno(1.5)$$ 

\noindent Under the conditions of this article, the minimum is attained in the
classical Sobolev  space $W_{0}^{1,p}(\Omega)$; the minimizer 
is known as the {\it principal eigenfunction}.

\noindent A {\it regular domain}
is a connected open set the boundary of which satisfies a
uniform external ball condition (See [D1], p. 27).  This condition
is implied by the standard uniform external cone condition.

\noindent A {\it test function} is a smooth function of compact support
in the domain $\Omega$, and the set of these is 
denoted $C_c^{\infty}$


\bigbreak
\centerline{\bf II. Lower bounds to energy forms}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\medskip
\noindent
In 1907, Boggio [B3] derived some lower bounds to 
the fundamental eigenvalue of the two-dimensional Laplacian
by applying the divergence theorem to a well chosen expression
containing two arbitrary differentiable functions.  From the 
modern point of view, his result can be interpreted as a 
quadratic-form inequality for the Dirichlet energy form of a test
function, 
which contains an arbitrary sufficiently smooth vector field,
good choices of which lead to useful lower bounds (see below).

In this section we discuss extensions of Boggio's idea
and connections with inequalities of Hardy and Rellich.  
To a certain extent the significance of the section is
historical, as estimates we need for later sections
can be found elsewhere in the literature.  In addition
to correcting the historical record, however, Boggio's idea is
significant because it an elementary and efficient way to 
obtain useful inequalities of this type.  
(We have recently learned from E. Mitidieri, in response 
to a preprint version of this article, that 
he also has a preprint [M2] emphasizing the efficiency
of deriving Hardy--type inequalities from the divergence
theorem.  Mitidieri's treatment is somewhat different from
ours, and he was 
unaware of [B3].)

Our generalization of Boggio's result to the situation of 
$p$--Laplacians is:


\proclaim{Theorem II.1}.
Let $\Omega$ be a regular domain and 
$\zeta \in C_{c}^{\infty }\left({\Omega }\right)$. 
Let ${\bf Q}$ be a vector field on $\Omega$ of class $AC^1$.  Then
$$\int_{\Omega }{\left|{\nabla \zeta }\right|}^{p} \ge 
\int_{\Omega }\left\{{\div {\bf Q}- (p-1) 
{\left|{\bf Q}\right|}^{p'}}\right\}{\left|{\zeta }\right|}^{p}\
d^N x.
\eqno(2.1)$$

\noindent {\bf Remarks:}
Boggio's result corresponds to the case $p=2$:
$$\int_{\Omega }{\left|{\nabla \zeta }\right|}^{2}\ge 
\int_{\Omega }{\zeta }^{2}\left({\div  {\bf Q}
- {\left|{\bf Q}\right|}^{2}}\right) d^2 x.  $$
The basic estimates for inequalities of the Hardy type (see Section 5.3
of [D1]) result from choices for ${\bf Q}$ such as
$${\bf Q} = - {\rm const.} \nabla Ln(x_1)$$
where $x_1$ is a Cartesian coordinate.  We shall make similar choices
below.
\vskip0.2cm
\noindent
{\bf Proof:}
$$0=\int_{\Omega} \div  \left({\bf Q}|\zeta|^p\right)=\int_\Omega(\div 
{\bf Q})
|\zeta|^p+p\int_\Omega|\zeta|^{p-2}\zeta \nabla \zeta\cdot {\bf Q}.$$
With
${\bf w}=|\zeta|^{p-2}\zeta\bf Q$, Young's inequality gives
$$|\nabla \zeta\cdot {\bf w}|\le {1\over p}\, |\nabla \zeta|^p+{1\over
p'}\,
|{\bf w}|^{p'}={1\over p}\, |\nabla \zeta|^p +{1\over p'}\,|\zeta|^p
|{\bf Q}|^{p'}, $$
so
$$\int_\Omega |\nabla \zeta|^p\ge\int_\Omega \left(\div  {\bf Q}-{p\over
p'}\, |{\bf Q}|^{p'}\right)|\zeta|^p.$$
\hfill $\diamondsuit$

\noindent
Our first application of this theorem is to derive a Hardy-type 
inequality with the known sharp constant [M1].


\proclaim{Corollary II.2}.
 Let $\Omega\subset{\Bbb R}^N_+=\{{\bf x}\in{\Bbb R}^N,x_1>0\}$,
$\zeta\in C^\infty_c(\Omega)$, $p'={p\over p-1}$.  Then:
$$\int_\Omega {|\zeta|^p\over x_{1}^p}\le (p')^p\int_\Omega 
\left|{{\partial \zeta} \over {\partial x_1}}\right|^p.$$

\noindent
{\bf Proof:}
We use the one-dimensional version of Theorem II.1, 
with 
${\bf Q}= ({-\alpha\over x_1^{p-1}}, 0, \ldots ,0)$, 
finding $\div {\bf Q}=
{\alpha(p-1)\over x_1^p}$, and $|{\bf Q}|^{p'}={\alpha^{p'}\over
x_1^p}$.  Then
for all $\alpha >0$ we have: 
$$\int_{\Omega}\left|{{\partial \zeta} \over {\partial x_1}}\right|^p
\ge (p-1)\int_\Omega (\alpha-\alpha^{p'})
{\left|\zeta\over x_1\right|^p}.$$
Now, $\alpha-\alpha^{p'}$ reaches its maximum for $p'\alpha^{p'-1}=1$,
which gives $\alpha={1\over (p')^{p-1}}$ and 
$$\alpha-\alpha^{p'}={1\over (p')^{p-1}}\,\left[1-{1\overwithdelims []
(p')^{p-1}}^{p'-1}\right]={1\over (p')^{p-1}}\left(1-{1\over p'}\right)
={1\over (p')^{p-1}}\times {1\over p}.$$
Hence $\int_\Omega|\nabla \zeta|^p \ge {p-1\over p}\times {1\over
(p')^{p-1}}
\int_{\Omega}
{\left|\zeta\over x_1\right|^p}$, and we obtain the desired result.
\hfill $\diamondsuit$


\proclaim{Corollary II.3}.
 Let $\Omega$ be a regular domain in ${\Bbb R} ^N$, 
and let $d({\bf x})$ 
denote the distance from the boundary.  Assume that the 
inradius of $\Omega$ is finite.  Then,  there exists 
$c_p < \infty$ such that, for any $\zeta \in W_0^{1,p}(\Omega)$ 
Hardy's inequality  holds:
 $$
 {c_p}^{p}\int_{\Omega }{\left|{\nabla \zeta }\right|}^{p}\ge
 \int_{\Omega }{\left|{\zeta  \over d({\bf 
x})}\right|}^{p}.\eqno(2.2) $$

\noindent {\bf Proof:}
Since the proof follows [D1], pp. 26-28, closely, we
content ourselves with an outline, referring the reader
to that source.  If $\Omega$ is a region in ${\Bbb R}^N$, and $ {\bf u} $
 is a unit vector in ${\Bbb R} ^N$, 
we define 
$$d_{\bf u}({\bf x}) = \min\{ |t|: {\bf x }+ t {\bf u} \not\in \Omega
\}$$
and an averaged distance to the boundary $m({\bf x})$ by 
$${1 \over {m({\bf x})}^{p}}= \int_{\| 
{\bf u}\| 
=1}{dS({\bf u}) \over {{d}_{\bf u}({\bf x})}^{p}},
$$
where $dS$ is the normalized surface measure on the unit sphere of 
${\Bbb R} ^{N}$.  By averaging the estimate of Corollary II.2 over 
directions, with the origin always shifted to the edge of
$\Omega$, we obtain 
$$
\int_\Omega {|\zeta|^p\over m({\bf x})^p}\le (p')^p\int_\Omega
|\nabla\zeta|^p$$
for all $\zeta \in C_{c}^{\infty}(\Omega)$.  We now observe, 
as in [D1], that for regular
domains with a finite inradius, one has the estimate 
$$d({\bf x}) \leq m({\bf x}) \leq \gamma d({\bf x})$$
for some constant $\gamma$ computable from the 
inradius and the constants 
in the uniform sphere condition. Then we obtain Hardy's  
inequality $(2.2)$, with the constant $c_p=\gamma p'$.
By density the same inequality holds for 
$\zeta \in W_0^{1,p}(\Omega)$.
\hfill $\diamondsuit$

\noindent
{\bf Remark:} 
Our further estimates are based on the 
minimal value of $c_p$ such that $(2.2)$ holds; in fact $c_p\geq p'$ as
we have seen in the proof above.

\smallskip
We close the section with two corollaries which generalize the Rellich 
inequality for $p=2$.

\proclaim{Corollary II.4}.
Let $\Omega$ be any domain in ${\Bbb R} ^N$, and 
$N > p$.  Then for all $\zeta \in W_0^{1,p}(\Omega)$,
 $$
 {\left({{p \over N-p}}\right)}^{p-1}\int_{\Omega }{\left|{\nabla
\zeta 
}\right|}^{p}{d}^{N}x\ge \int_{\Omega }{\left|{{\zeta  \over
\left|{\bf x}\right|}}\right|}^{p}{d}^{N}x.$$

\noindent
{\bf Proof sketch:}
We apply Theorem II.1 with the choice 
$$
{\bf Q} ({\bf x} )= {\left({{N-p \over p}}\right)}^{p-1}{{\bf x}
\over 
{\left|{\bf x}\right|}^{p}}.$$
Of course, this vector field is not $AC^1$ near the origin, so it must
be regularized there, which accounts for the restriction that $N > p$.
\hfill $\diamondsuit$

\proclaim{Corollary II.5}.
Let $\Omega$ be a finite domain in ${\Bbb R} ^N$, and 
$N > p > 2$.  Then there exists a finite constant $c_0$ such that
for all $\zeta \in W_0^{1,p}(\Omega)$.
$${c}_{0}^{p}\int_{\Omega}{\left|{\nabla \zeta }\right|}^{p}\
{d}^{N}x\ge \int_{\Omega}{{\left|{\zeta }\right|}^{p} \over 
{\left|{\bf x}\right|}^{2}}{d}^{N}x$$

\noindent
{\bf Proof sketch}:
Here the choice is 
$${\bf Q}({\bf x})= {\alpha {\bf x} \over {\left|{{\bf
x}}\right|}^2 },$$
which leads to a lower bound of the form
$${\alpha \left({N-2}\right) \over {\left|{\bf x}\right|}^{\rm
2}}-
{(p-1){\alpha }^{p\prime} \over {\left|{\bf x}\right|}^{p\prime}}.$$
For $p > 2$ and $\Omega$ finite, the constant 
$\alpha$ can be chosen sufficiently small so that the 
first term dominates the second throughout $\Omega$.
\hfill $\diamondsuit$

\bigbreak
\centerline{\bf III. $L^q$ boundary behavior for functions of finite energy}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\medskip
\noindent
In this section we provide estimates of the boundary decay of 
test functions of finite energy and, consequently, the
principal eigenfunction of equations of the form
$${-\Delta }_{p}u+V({\bf x}){u}^{p-1}= \lambda_1 {u}^{p-1}. 
\eqno(3.1)$$
Recall that the energy form is defined by
$$R\left({\zeta }\right) :=
 {\int_{\Omega }\left({{\left|{\nabla \zeta }\right|}^{p} +
V({\bf x}){\left|{\zeta }\right|}^{p}}\right)d^{N}x \over 
{\| \zeta \| 
}_{L^p}^{p}}, \eqno(3.2)$$
and that i.e., the principal eigenfunction is the positive function
which minimizes this functional in $W^{1,p}_0$.
Initially we consider $V\equiv 0$, after which we shall introduce a
class of
potentials $V$ for which the minimizer exists and similar estimates
pertain.

As in [D2], we base these estimates on the Hardy constant, i.e.,
given a distance function $d({\bf x})$ as above,
the minimal value of $c_p$ such that for any $\zeta \in
W_0^{1,p}(\Omega)$,
$${c_p}^{p}\int_{\Omega }{\left|{\nabla \zeta }\right|}^{p}\ge 
 \int_{\Omega }{\left|{\zeta  \over d\left({\bf 
x}\right)}\right|}^{p}.
\eqno(3.3)$$
As remarked above, we choose $d({\bf x})$ as the distance from ${\bf x}
\in \Omega$
to the boundary of $\Omega$. The goal of this section 
is to replicate the boundary estimates 
of Section 3 of [D2]
to the extent possible, replacing estimates 
based on the spectral theorem
with integral inequalities as necessary. 

The main theorems of this section are III.4 (for $V=0$) and III.5.

The Hardy constant contains geometric information about the 
domain, and in some cases can be estimated 
exactly (e.g., [M1]; note that by convention, the constant
$c_p$ in this work is the reciprocal of ours and of [D2].).  
In Section II of this article, we established that any regular 
domain with a finite inradius has a finite Hardy constant.  
A higher value than the minimal $c_p \geq p'$ in (3.3)
may arise depending on the geometry of $\Omega$.

Here we assume that the value of $c_p$ is known and
explore the consequences for the eigenfunctions.

Our boundary estimates require an algebraic bound of the 
following form.

\smallskip \noindent
{\bf Basic Algebraic Bound}
 
There are finite constants $\hat m\ge 1$ and $\hat k>0$ 
such that for all ${\bf X}\in{\Bbb R}^N$, ${\bf Z}\in{\Bbb R}^N$:
$$\| {\bf X}+{\bf Z}\|^p_2\le \hat m^p\|{\bf X}\|^p_2+\hat k\left(\|
{\bf Z}\|^p_2+p\|{\bf Z}\|^{p-2}_2{\bf Z}\cdot  {\bf X}
\right)\leqno (A)$$

In Section IV we shall identify constants $\hat m$ and
 $\hat k$ depending on $p$ and $N$ such that 
(A) is valid. For $p=2$, they reduce to $\hat m = \hat k = 1$.
More precisely, Section IV proves (A) with:
$$\matrix{
p\geq2,&N=1:   &\hat m=m =p-1                 &\quad \hat 
k=k=p^{2-p}(p-1)^{p-1}\cr 
p\geq2,&N\geq2:&\hat m=2^{(p-2)\over{2p}}(p-1)&\quad \hat 
k=2^{(p-2)\over2}p^{2-p}(p-1)^{p-1}\cr
1<p\leq2,&N=1:   &\hat m=m                      &\quad \hat k = k = 1
\cr
1<p\leq2,&N\geq2:&\hat m=2^{(2-p)\over{2p}}m    &\quad \hat k = 1 \cr
}$$
Here, for $p<2$,  $m$ is the constant defined in $(4.6)$;
by Lemma IV.2 we know that $m \geq 1.$


\proclaim{Lemma III.1}.  With $\hat m$ and $\hat k$ such that 
(A) holds, for any $\varphi \geq 0$ which is piecewise $C^1$ and
any $\zeta \in W_0^{1,p}(\Omega)$ such that $\Delta_p \zeta \in
L^{p'}(\Omega)$,
$$\int_\Omega |\nabla (\varphi\zeta)|^p\le
 \hat m^p\int_\Omega |\zeta\nabla \varphi|^p+ \hat k\int_\Omega 
\zeta \varphi^p(-\Delta_p \zeta).$$

\noindent
{\bf Proof:}  Applying (A) with ${\bf X}= \zeta\nabla \varphi$
and 
${\bf {\bf Z}}=\varphi\nabla \zeta$, we get:
$$
 \int_\Omega |\zeta \nabla \varphi + \varphi \nabla \zeta |^p 
\le \hat m^p\int_\Omega |\zeta \nabla 
\varphi|^p+ \hat k\int_\Omega
\left[|\varphi \nabla \zeta|^p+p\varphi^{p-1}\zeta|\nabla \zeta|^{p-2}
\nabla \zeta \cdot
\nabla \varphi \right].
$$
Moreover,
$$
\int_{\Omega}|\varphi \nabla \zeta|^p =\int_\Omega (\varphi^p|\nabla
\zeta|^{p-2} 
\nabla \zeta)\cdot
\nabla \zeta
= -p\int_\Omega \varphi^{p-1} \zeta|\nabla \zeta|^{p-2}\nabla 
\zeta\cdot\nabla \varphi -
\int_{\Omega}\zeta \varphi^p(\Delta_p\zeta),
$$
and we obtain:
$$\int_\Omega |\nabla (\varphi \zeta)|^p\le
 \hat m^p\int_\Omega |\zeta\nabla \varphi|^p+ \hat k\int_\Omega 
\zeta \varphi^p(-\Delta_p \zeta)$$
as claimed.
\hfill $\diamondsuit$

\smallskip
With $\hat m$ appearing in (A) and $c_p$ in (3.3), we henceforth
set 
$$c = \hat m c_p$$
and we remark that $c \geq p$ in view of (A).

\proclaim{Lemma III.2}.  Suppose that $c>p$ and that 
$\varphi$ is a piecewise 
$C^1$ function such that $0 \leq \varphi \leq d({\bf x})^{-1/c}$.
Then for any
$\zeta \in W_0^{1,p}(\Omega)$:
 $$\int_\Omega {\varphi}^{p^2} |\zeta|^p d^{N}x \leq 
 (c_p)^{p^2/c}
\left(\int_\Omega |\nabla \zeta|^p d^{N}x \right)^{p/c}
\left(\int |\zeta|^p  d^{N}x \right)^{1-p/c}.$$



\noindent
{\bf Proof:}
Because $\varphi({\bf x})\leq d({\bf x})^{-1/c}$,
$$\int_\Omega {\varphi}^{p^2} |\zeta|^p \le 
\int_\Omega d^{-p^2/c}|\zeta|^{p^2c^{-1}+p(c-p)c^{-1}},$$
which by H\"older's inequality is bounded by 
$$\left(\int_\Omega{|\zeta|^p\over d^p}\right)^{p/c}
\left(\int_\Omega |\zeta|^p\right)^{1-p/c}.$$
With the Hardy inequality (3.3), we therefore obtain:
$$\int_\Omega {\varphi}^{p^2}\zeta^p\le (c_p)^{p^2/c}
\left(\int_\Omega |\nabla \zeta|^p\right)^{p/c}
\left(\int_\Omega |\zeta|^p\right)^{1-p/c}.$$
\hfill $\diamondsuit$


\proclaim{Lemma III.3}. Let $\hat m$ and $\hat k$ be such that 
(A) holds, and let $\varphi$ be any piecewise $C^1$ function
such that $0 \leq \varphi \leq d({\bf x})^{-1/c}$. 
%and suppose that $c \geq p$. 
Then for any
$\zeta \in W_0^{1,p}(\Omega)$ such that $\Delta_p \zeta \in
L^{p'}(\Omega)$:
$$\eqalign{
\int_\Omega |\nabla (\varphi \zeta)|^p d^{N}x &\le 
\hat m^p\int_\Omega |\zeta\nabla 
\omega|^p d^{N}x 
+ \hat k(c_p)^{p/c}
\left(\int_\Omega |\nabla \zeta|^p d^{N}x  \right)^{1/c}\cr
&\qquad\times\left(\int_\Omega |\zeta|^p d^{N}x 
\right)^{p^{-1}-c^{-1}}\left(\int_\Omega 
\left|-\Delta_p \zeta\right|^{p'} d^{N}x  \right)^{1/p'}. }$$

\noindent
{\bf Proof:}  From Lemma III.1 we know that
$$\int_\Omega |\nabla (\varphi \zeta)|^p\le
 \hat m^p\int_\Omega |\zeta\nabla \varphi|^p+ \hat k\int_\Omega 
\zeta \varphi^p(-\Delta_p \zeta).$$
Recall that $c \geq p$.  If $c>p$, 
then by H\"older's inequality and Lemma III.2,
$$\eqalignno{
\left| \int_\Omega \zeta \varphi^p(-\Delta_p \zeta)\right|&\le
\left(\int_\Omega \zeta^p \varphi^{p^2}
\right)^{1/p}\left(\int_\Omega \left|-\Delta_p
\zeta\right|^{p'}\right)^{1/p'}
&(3.4)\cr
&\le
(c_p)^{p/c}\left(\int_\Omega |\nabla \zeta|^p\right)^{1/c}
\left(\int_\Omega |\zeta|^p\right)^{1/p-1/c}
\left(\int_\Omega \left|-\Delta_p \zeta\right|^{p'}\right)^{1/p'},&\cr }$$
yielding the claim.

\noindent
For $c=p$, since $\varphi^{p^2}\le d^{-p^2/c}=d^{-p}$ we have
$$
\left| \int_\Omega( \zeta \varphi^p)(-\Delta_p\zeta) \right| \le
\left(\int_\Omega |\zeta|^p \varphi^{p^2}\right)^{1/p}
\left(\int_\Omega \left|-\Delta_p \zeta\right|^{p'}\right)^{1/p'},$$
 which by Lemma III.2 is bounded by
$$c_p\left(\int_\Omega |\nabla \zeta|^p\right)^{1/p}
\times \left(\int_\Omega \left|-\Delta_p
\zeta\right|^{p'}\right)^{1/p'}.$$
Hence the same inequality holds in this case.
\hfill $\diamondsuit$

\smallskip
Our next result, Theorem III.4, shows that integrals involving $\zeta$
on an  $\epsilon$-neighborhood of the boundary are bounded by
expressions of the form 
$F\cdot \epsilon^s$, where $F$ depends only on $\Omega$, $\Vert \zeta \Vert_p$,
$\Vert \nabla\zeta \Vert_p$, and $\Vert \Delta_p\zeta \Vert_{p'}$. When
$p=2$, 
and $\partial \Omega$ is smooth, our exponents $s$ reduce to the sharp
values as remarked in [D2]. 


We adopt some notation and other conventions of [D2]; in particular,
for a given  $\varepsilon >  0$, we define
$$\omega ({\bf x}) = {\left({\max\{d({\bf x}),\varepsilon \}}\right)}
^{-1/c} \eqno(3.5) $$
and
$$\tau \left({ \bf x}\right) = \cases{
\varepsilon^{-1/c} & if  $0 < d(\bf x ) \le  \varepsilon$ \cr
{c}^{ -1}{\varepsilon }^{ -1-1/c}\left({\left({ 1+c}\right)\varepsilon
 -d({\bf x} )}\right) & if $\varepsilon  < d({\bf x}) \le
  \left({1+c}\right)\varepsilon$ \cr
 0 &  otherwise.\cr}\eqno(3.6)$$
\noindent
(Recall that $c = \widehat{m} c_p$ with $\widehat{m}$ 
appearing in (A) and $c_p$ in (3.3).
We remark that both functions 
$\omega$ and $\tau$ satisfy the conditions of the functions 
$\varphi$ appearing in Lemma III.1--Lemma III.3.)


\proclaim{Theorem III.4}. 
There are (identifiable)  constants $K_{1,2}$ such that given any 
$\zeta \in W_0^{1,p}(\Omega)$ such that $\Delta_p \zeta \in
L^{p'}(\Omega)$:
$$ \int_{\{ d({\bf x})<\epsilon\}\cap \Omega} {|\zeta|^p\over d^p} d^{N}x \leq 
\leqno(i)$$
$$ K_{1}\epsilon^{p/c}
\left(\int_\Omega |\nabla \zeta|^p d^{N}x \right)^{1/c}
\left(\int_\Omega |\zeta|^p d^{N}x \right)^{p^{-1} - c^{-1}} 
\left(\int_\Omega (-\Delta_p \zeta)^{p'} d^{N}x \right)^{1/p'}$$
for all $\epsilon > 0$.
Hence also,
$$ \int_{\{ d({\bf x})<\epsilon\}\cap \Omega} {|\zeta|^p} d^{N}x \leq
\leqno(ii)$$
$$ K_{1} \epsilon^{p+p/c} 
\left(\int_\Omega |\nabla \zeta|^p d^{N}x \right)^{1/c}
\left(\int_\Omega |\zeta|^p d^{N}x \right)^{p^{-1} - c^{-1}} 
\left(\int_\Omega (-\Delta_p \zeta)^{p'} d^{N}x \right)^{1/p'}$$
for all $\epsilon > 0$.
In addition, 
$$ \int_{\left\{{d\left({\bf x}\right)\bf \le  \varepsilon 
}\right\}}{\left|{\nabla \zeta }\right|}^{p}{d}^{N}x \le 
{K}_{2} F {\varepsilon }^{p/c}, \leqno(iii)
$$
where $F$ depends only on $\Omega$, $\Vert \zeta \Vert_p$,
$\Vert \nabla\zeta \Vert_p$, and $\Vert \Delta_p\zeta \Vert_{p'}$
(and is implicitly specified by the last few lines of the proof). 
Recall that $c = {\hat m}c_{p}$.

\smallskip
\noindent
{\bf Proof:} We deduce from Lemmas III.2 and III.3 that
$$
\int_\Omega {|\omega \zeta|^p\over d^p} \le
(\hat m c_p)^p\int_\Omega | \zeta \nabla \omega|^p + I, \eqno(3.7) $$
where $$I =\hat k(pc_p)^{p+p/c}
\left(\int_\Omega |\nabla \zeta|^p\right)^{1/c}\left(\int_\Omega |\zeta|^p
\right)^{p^{-1} - c^{-1}}\left(\int_\Omega |-\Delta_p
\zeta|^{p'}\right)^{1/p'}
.$$
Let $Y({\bf x})={\omega^p\over d^p}-c^p|\nabla \omega|^p$.
For 
$d({\bf x})\ge \epsilon$, $|\nabla \omega| = {1\over c} {\omega\over d};$ 
hence $Y({\bf x})\ge 0$, and for $d({\bf x})<\epsilon$,
$\nabla \omega({\bf x})=0$, so $Y({\bf x})\ge {1\over \epsilon^{p/c}d^p}$.

Rewriting (3.7) as
$$\int_\Omega |\zeta|^p Y \le I$$
we deduce that
$$\int_{\{d({\bf x})<\epsilon\}\cap \Omega} {|\zeta|^p\over d^p}\le \hat
k(c_p)^{p+p/c}
\epsilon^{p/c}I,$$
and hence we have part (i), from which (ii) is immediate.

For part (iii), we first note that
$$
\int_{\left\{{d\left({\bf x}\right)\bf < \varepsilon
}\right\}}{\left|{\nabla \zeta }\right|}^{p}{d}^{N}x \le  
{\varepsilon }^{p/c}\int_{\Omega }{\left|{\nabla (\tau \zeta)
}\right|}^{p}
{d}^{N}x,  \eqno(3.8)
$$
and then apply Lemma III.1 to conclude that 
$$ \eqalign{
\int_{\Omega }{\left|{\nabla (\tau \zeta) }\right|}^{p}{d}^{N}x
\le& {\widehat{m}}^{p}\int_{\left\{{d\left({\bf x}\right)<(1+c)\varepsilon 
}\right\}}{\left|{\zeta \nabla \tau }\right|}^{p}{d}^{N}x 
 + \widehat{k}{c}_{p}^{p/c}{\left({\int_{\Omega 
}{\left|{\nabla \zeta }\right|}^{p}
{d}^{N}x}\right)}^{1/c} \times \cr
&{\left({\int_{\Omega }{\left|{\zeta }\right|}^{p}
{d}^{N}x}\right)}^{1/p-1/c}{\left({\int_{\Omega }{\left|{-{\Delta
}_{p}\zeta 
}\right|}^{p\prime}{d}^{N}x}\right)}^{1/p\prime}.\cr}
$$
Now, 
$$\int_{\left\{{d\left({\bf x}\right)<(1+c)\varepsilon 
}\right\}}{\left|{\zeta \nabla \tau }\right|}^{p}{d}^{N}x \le
{\left({{1 \over c{\varepsilon 
}^{1+1/c}}}\right)}^{p}\int_{\left\{{d\left({\bf
x}\right)<(1+c)\varepsilon 
}\right\}}{\left|{\zeta }\right|}^{p}{d}^{N}x,$$
which is bounded by quantities independent of $\epsilon$
according to part (ii).  Together with (3.8), this yields (iii).
\hfill $\diamondsuit$

\smallskip
Next we obtain a similar estimate for (3.1) for nonzero $V({\bf x})$,
for which the coefficient of $\epsilon^s$ is given in terms of
$\|\zeta\|_p, R(\zeta)$, and 
$\| - \Delta_p \zeta + V({\bf x}) |\zeta|^{p-2} \zeta \|_{p'}$.

We shall assume that 
$V({\bf x}) = V_{1}({\bf x})  + V_{2}({\bf x})$,
where $V_{1}({\bf x}) \ge 0$ and there exist
finite constants $A,B,\alpha,\beta$, with $\alpha < 1$,
such that  $|V_2|$ satisfies
$$
\int_{\Omega} |V_2|^{p'} |\zeta|^p d^Nx \leq 
	A  \int_{\Omega} |\nabla \zeta|^p d^Nx + 
	B  \int_{\Omega} | \zeta|^p d^Nx \leqno(i)
$$
and
$$ \displaylines{
 \rlap{(ii)}\hfill \int_{\Omega} |V_2| |\zeta|^p  d^Nx \leq
	\alpha  \int_{\Omega} |\nabla \zeta|^p d^Nx +
        \beta \int_{\Omega} | \zeta|^p d^Nx \hfill\llap{(3.9)} \cr}
$$
for all $\zeta \in C_{c}^{\infty}(\Omega)$.

We remark that using the results of Section II,
(3.9) will hold, for example, provided that
$|V_2|^{p'} < {C_1\over d^p} +\hbox{bounded function} \Leftrightarrow
|V_2|< C_2 d^{-(p-1)}+ \hbox{bounded function}$
for some constants $C_{1,2}$, since this implies that
$|V_2|<{1\over c^p_p} \, {1\over d^p} + \hbox{bounded function}$.


\proclaim{Theorem III.5}. 
Given Hardy's inequality $(3.3)$ with
 $c=\hat m c_p>p$,
assume that $V$ satisfies (3.9) and that $\zeta \in W_{0}^{1,p}$ with 
$-\Delta _p\zeta + V |\zeta|^{p-2} \zeta  \in W_{0}^{1,p} \cap
L^{p'}(\Omega)$.  
Then 
there are quantities $F_{1,2}$ depending only on  $\Omega$,
$\|\zeta\|_p, R(\zeta),$
and
$\| - \Delta_p \zeta + V({\bf x}) |\zeta|^{p-2} \zeta \|_{p'}$
such that
$$\int_{\{ d({\bf x})<\epsilon\}\cap \Omega} {|\zeta|^p\over d^p} d^{N}x
\leq 
F_{1}  \epsilon^{p/\hat
mc_p} \leqno(i)$$
for all $\epsilon > 0$.
Hence also,
$$\int_{\{ d({\bf x})<\epsilon \}\cap \Omega} {|\zeta|^p} d^{N}x \leq 
F_{1} \epsilon^{p+p/\hat
mc_p} \leqno(ii)
$$
for all $\epsilon > 0$. In addition, 
$$ \int_{\left\{{d\left({\bf x}\right)\bf \le  \varepsilon 
}\right\}}{\left|{\nabla \zeta }\right|}^{p}{d}^{N}x\le 
{K}_{2} F_{2} {\varepsilon }^{p/c}. \leqno(iii)$$


\noindent
{\bf Proof:}  
We proceed as in the proof of Theorem III.4 until 
the stage where we call on Lemma III.3.  Instead of dominating 
$\int\zeta \omega^p(-\Delta_p\zeta)$ as in $(3.4)$, we bound it above by
$$ \displaylines{
\int\zeta \omega^p(-\Delta _p\zeta + V_1 |\zeta|^{p-2}\zeta) \cr
\le \left(\int |\zeta|^p \omega^{p^c}\right)^{1/p}
\left(\|-\Delta_p\zeta + V|\zeta|^{p-2}\zeta\|_{p'} +
\|V_2|\zeta|^{p-2}\zeta\|_{p'}\right). }
$$
The claim requires that we control the final term, which to the $p'$
power is
$$ \eqalign{
\int |V_2|^{p'}|\zeta|^p \le& A\int|\nabla\zeta|^p + B\int|\zeta|^p \cr
\le& A\left(\int|\nabla\zeta|^p+V|\zeta|^p+|V_2\zeta^p|\right)+B\|\zeta\|^p_p \cr
\le& (A R(\zeta) + B)\|\zeta\|^p_p+A\int|V_2\zeta^p|, \cr}
$$
so it remains to control $\int|V_2\zeta^p|$.  This we do using 
part (ii) of (3.7) as follows.
$$\int|V_2\zeta^p|\le\alpha
\left(\int |\nabla\zeta|^p + V|\zeta|^p+|V_2\zeta^p|\right)
+\beta\int| \zeta|^p,$$
so
$$\int |V_2\zeta^p|\le {1\over 1-\alpha} \, (\alpha  R(\zeta)+ \beta)
\|\zeta\|^p_p.$$
\hfill $\diamondsuit$

\bigbreak
\centerline{\bf IV. Some inequalities}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\medskip
\noindent
In this section we establish a family of elementary but refined 
algebraic inequalities, needed to apply the estimates of Section III to 
the $p$-Laplacian for various values of $p$.  

First we establish some algebraic inequalities for a binomial
in a scalar real variable $x$, taken to the power $p$.  Then
we use them to derive vectorial inequalities which imply
the basic algebraic bound (A) of Section III.

\proclaim{Lemma IV.1}. For $p \ge 2$ and $x \in {\Bbb R}$, 
$${\left|{x-1}\right|}^{p}\le 
 { \left( {p-1} \right) }^{p}+{p}^{2-p}
{\left({p-1}\right)}^{p-1}\left({{\left|{x}\right|}^{p}-p {\left|{x}\right|}^{p 
-2}x}\right).\eqno(4.1)$$

\smallskip

\noindent 
{\bf Remark:}  Essentially we dominate the left side by a constant plus 
two terms from its expansion for large $|x|$.  
The inequality is sharp in the sense that the constant $(p-1)^p$
on the right is minimal.

\smallskip

\noindent {\bf Proof:}
Because of the absolute values, we need to consider separately
three cases, $1 < x$, $0 \leq x \leq 1$, and $x < 0$.

\noindent Case 1.  For $0 < x < 1$, we let
$$f_{2}(x) = (1-x)^{-p} [(p-1)^p + p^{p-2}(p-1)^{p-1}(x^p-px^{p-1})],$$ 
and calculate the derivative
$$f_{2}'(x) = p^{3-p} (p-1)^p (1-x)^{-p-1} [p^{p-2}-x^{p-2}] > 0,$$ 
so the minimal value of $f_{2}$ on this interval 
is $f_{2}(0) = (p-1)^p \ge 1$.


\noindent Case 2.  For $1 < x $, we claim that 
$$f_{1}(x) = (x-1)^{-p} [(p-1)^p + p^{p-2}(p-1)^{p-1}(x^p-px^{p-1})]$$
achieves its unique minimum for $x=p$. This is because a 
calculation reveals that 
$$f_{1}'(x) = p^{3-p} (p-1)^p (x-1)^{-p-1} [x^{p-2}-p^{p-2}],$$ 
which is zero uniquely for $x=p$ and otherwise has the same 
sign as $x-p$.


\noindent Case 3.  For convenience, for the case when $x < 0$, we replace $x$ 
by $-x$.  Thus we need to show that for $x > 0$,
$$(1+x)^{p}\le { (p-1)}^{ p}  + {p}^{2-p}{(p-1)}^{p-1}\left({x^  
{p}+px^{p-1}}\right),\eqno(4.2)$$
or in other words that
$$f_{3}(x) := {{ (p-1)^p + p^{2-p}
(p-1)^{p-1}(x^p+px^{p-1})}\over{(1+x)^p}} 
\geq 1.
\eqno(4.3)$$ 
Again we differentiate, finding
$$f_{3}'(x)=p^{3-p}(p-1)^p(1+x)^{-p-1}(x^{p-2}-p^{p-2}),$$
which reveals that $f_{3}'$ vanishes uniquely at p and 
elsewhere has the same sign as $x-p$.   
Hence $f_{3} (x) \geq f_{3} (p)= (2p-1) 
\left({{p-1}\over{p+1}}\right)^{p-1}$.


It remains to show that $f_3(p)\geq 1$, or equivalently that
$f_4(y)\geq 1$ for $y\geq 2$ where
$$f_4(y) = (2y-1)\left({{y-1}\over{y+1}}\right)^{y-1}.$$
We note that $f_4(2)=1$.
We prove now that $f_4'>0$:
$$f_4'(y)= f_4(y) B(y),$$
where $B(y)={{2}\over{2 y - 1}} + {{2}\over{y+1}} +
Ln\left({{y-1}\over{y+1}}\right)$.
Hence we wish to prove that $B(y) > 0$, which is true for $y=2$.  Now,
$$B'(y)=4 {{N(y)}\over{D(y}},$$
with $D(y)=(2y-1)^2(y+1)^2(y-1)>0$ and $N(y)=-y^3+3y^2-3y+2$.
Since $N'(y)=-3(y-1)^2<0$, $N\leq 0$ and thus $B'(y)<0$,  i.e., B is a
decreasing
function.
As $y$ tends to $\infty$, $B(y)\rightarrow 0$. Hence $B > 0$ and $f_4'>
0$ for $y > 2$.
Therefore $f_4(y)\geq 1$ for all $y \geq 2$.
\hfill $\diamondsuit$

\proclaim{Lemma IV.2}. For $p \le 2$ and $x \in {\Bbb R}$, 
$${\left|{x-1}\right|}^{p} \le m_{p}^{p}+ \left({{\left|{x}\right|}^{p}
 - p{\left|{x}\right|}^{p -2}x}\right),    \eqno(4.5)$$
where $ m_{p}^{p}$ is defined by
$$m^p_p=\max_{0\le x\le 1}((p-x)x^{p-1}+(1-x)^p).  \eqno(4.6)$$


{\bf Remarks:}  In comparison with Lemma IV.1, for $p \ge 2$, the 
second constant on the right has been simplified to $1$, while 
the first one has a different form.  Both sharp inequalities trivialize 
to the same identity for $(x-1)^2$ when $p$ becomes $2$.

\noindent 
Observe that $m_2^2=\max(1)=1$, and that if 
${h}_{p}\left({x}\right):=(p-x){x}^{p-1}+{(1-x)}^{p},$
then 
$m_{p}^{p} \ge \max (h(0), h(1)) = \max (1, p-1)$.


\smallskip
\noindent {\bf Proof:}
We need to show $|x-1|^p\le m^p_p+
(|x|^p-p|x|^{p-2}x)$ for $x\in {\Bbb R}$. 
As before, we consider three cases.

\noindent Case 1.  $0\le x\le 1$.  The desired bound holds by 
the definition of $m^p_p$.

\noindent Case 2, $x \ge 1$.  Let
$$\phi=(x-1)^p, \qquad\psi=m^p_p+x^p-px^{p-1}.$$
We see that 
$\phi (1)=0 < \psi (1)$ and define
$$r:={\psi'\over \phi'}={(x-(p-1))x^{p-2}\over (x-1)^{p-1}}.$$
It is easy to see that
$\lim\limits_{x\downarrow 1}r(x)= +\infty$ and
$\lim\limits_{x\rightarrow \infty }r(x)= 1$,
and to calculate that 
$r'(x) =\hbox{(positive)} \times (p-2)<0$ on this interval.  Thus $r>1$,
which implies the bound in this case.


\noindent Case 3.  $x < 0.$  As before, it is convenient to 
redefine $x\leftrightarrow -x$ and compare the functions
$$\phi=(1+x)^p \hbox{ and }\psi=m^p+x^p+px^{p-1}$$
for $x > 0$.  We define
$r = \psi'/\phi'$, and calculate as for case 2 that
$r'=\hbox{positive} \times (p-2) < 0$.  By examining the limits
$\lim\limits_{x\downarrow 0}r(x)= +\infty$ and
$\lim\limits_{x\rightarrow \infty }r(x)= 1$,
we conclude that $r(x) > 1$ on this interval, implying the desired
bound.
\hfill $\diamondsuit$

We now proceed to deduce vectorial inequalities from the scalar
inequalities of Lemma IV.1 and Lemma IV.2.

\proclaim{Lemma IV.3}. For $p>q>1$, the following inequalities hold
$\forall$ ${\bf Y}\in{\Bbb R}^N$, 
$$\|{\bf Y}\|_p \underbrace{\le}_{(1)} 
\|{\bf Y}\|_q\underbrace{\le}_{(2)}
N^{(p-q)/pq}\|{\bf Y}\|_p.$$
where $\|{\bf Y}\|_p = \left\{ \sum\limits^N_{i=1}
|y_i|^p\right\}^{1/p}$.

\noindent
{\bf Proof:} (1) By a homothety, it is sufficient to consider the case 
$$\displaylines{
\sum\limits^N_{i=1} |y_i|^q\ge 1\quad\hbox{with}\quad 
|y_i|\le 1,\forall \, i=1,\dots, N \cr
\sum^N_{i=1} |y_i|^p\le \sum^N_{i=1} |y_i|^q \cr}
$$
so that
$$\left(\sum^N_{i=1} |y_i|^p\right)^q\le
\left(\sum^N_{i=1}|y_i|^q\right)^q
\le \left(\sum^N_{i=1} |y_i|^q\right)^p\Rightarrow \|{\bf
Y}\|_p\le\|{\bf Y}\|_q$$

\noindent (2) Letting $x_i=|y_i|^q$, by convexity we have
$$ \displaylines{
{x_1+\cdots + x_N\overwithdelims ()N}^{p/q}\le {1\over N}\left(
x_1^{p/q} + \cdots + x_N^{p/q}\right) \cr
{1\over N^{p/q}}\, (|y_1|^q+\cdots + |y_N|^q)^{p/q}\le {1\over N}
(|y_1|^p+\cdots + |y_N|^p) \cr
\| {\bf Y}\|_q \le (N^{p/q-1})^{1/p} \| {\bf Y}\|_p=N^{(p-q)/pq}\|
{\bf Y}\|_p. \cr}$$
\hfill $\diamondsuit$

\noindent 
{\bf Remarks:} The constant $1$ in (1) is optimal: take $y_2=\cdots =
y_N=0$.
The constant $N^{(p-q)/pq}$ in (2) is likewise optimal: 
take $y_1=y_2=\cdots =y_N=1$;
in that case, (2) becomes $N^{1/q}\le N^{(p-q)/pq}N^{1/p}$.


\proclaim{Lemma IV.4}. Suppose that for $m\ge 1$ and $k>0$  it has been
established that
$$\forall y,z\in{\Bbb R}: |y-z|^p\le m^p|z|^p+k|y|^p-kp|y|^{p-2}yz.
\eqno(4.7)$$
Then the following inequalities hold for any ${\bf Y}$ and ${\bf
Z}\in{\Bbb R}^n$:
\item{(i)} For $p\ge 2$, $\| {\bf Y}-{\bf Z}\|^p_2\le 2^{(p/2)-1}
\left\{ m^p\| {\bf Z}\|^p_2+k\|{\bf Y}\|^p_2-kp\|{\bf Y}\|^{p-2}_2{\bf Y}
 \cdot  {\bf  Z}\right\}$
\item{(ii)} For $1<p\le 2$, $\| {\bf Y}-{\bf Z}\|^p_2\le 2^{1-(p/2)} m^p\|
{\bf Z}\|^p_2+
k\|{\bf Y}\|^p_2-kp\| {\bf Y}\|^{p-2}_2{\bf Y} \cdot {\bf Z}$.


\noindent
{\bf Proof:} Since the formulae (i) and (ii) are not changed by rotation
or if we replace ${\bf X}$ and ${\bf Y}$ by any homothetic vectors, 
it is sufficient to consider the case where
$${\bf Y}=(1,0,\dots, 0)\hbox{ and } {\bf Z}=(z_1,z_2,0,\dots, 0).$$
(i)   Observe that from Lemma IV.3 we have
$$|z_1|^p+|z_2|^p\le \{|z_1|^2+|z_2|^2\}^{p/2}.\eqno(4.8)$$
We get
$$\eqalign{
\| {\bf Y}-{\bf Z}\|^p_2&= \left\{ (z_1-1)^2+z^2_2\right\}^{p/2}=
2^{p/2}{(z_1-1)^2+z^2_2\overwithdelims \{\} 2}^{p/2}\cr
&\le 2^{(p/2)-1}\left\{ (z_1-1)^p+z^p_2\right\}\qquad\hbox{by
convexity}\cr
&\le 2^{(p/2)-1}\left\{m^p|z_1|^p+k-kpz_1+m^p|z_2|^p\right\}
\qquad \hbox{from (4.7)}\cr
&\le 2^{(p/2)-1}\left\{m^p(|z_1|^2+|z_2|^2)^{p/2}+k-kpz_1\right\}
\qquad \hbox{from (4.8)}\cr
&\le 2^{(p/2)-1} \left\{ m^p\|{\bf Z}\|^p_2+k\|{\bf Y}\|^p_2-kp\|{\bf 
Y}\|^{p-2}_2{\bf Y} \cdot {\bf Z}
\right\}. }$$
(ii)  Since $2>p$, from Lemma IV.3 we find
$$\eqalign{
\| {\bf Y}-{\bf Z}\|^p_2&=\left\{ (z_1-1)^2+z^2_2\right\}^{p/2}\le
|z_1-1|^p+|z_2|^p\cr
&\le m^p(|z_1|^p+|z_2|^p)+k-kpz_1\qquad\hbox{from (4.7)}\cr
&\le m^p2^{1-(p/2)} (z^2_1+z^2_2)^{p/2} + k-kpz_1.}$$
 From the second relation of Lemma IV.3, we obtain here:
$$(|z_1|^p+|z_2|^p)^{1/p}\le 2^{(1/p)-(1/2)}(z^2_1+z^2_2)^{1/2},$$
and hence
$$\|{\bf Y}-{\bf Z}\|^p_2\le m^p2^{1-(p/2)} \| {\bf Z}\|^p_2+k\|{\bf 
Y}\|^p_2-kp\|{\bf Y}\|^{p-2}
{\bf Y} \cdot {\bf Z}.$$
\hfill $\diamondsuit$

By combining the lemmas of this section, we obtain the 
estimates needed for Section III.

\proclaim{Proposition IV.5}. For any ${\bf X}$ and ${\bf Z}\in{\Bbb R}^n$,

\noindent (i) For $p\ge 2$: $$\| {\bf X}+{\bf Z}\|^p_2\le 2^{(p/2)-1}
\left\{ (p-1)^p\| {\bf X}\|^p_2+p^{2-p}(p-1)^{p-1}
\left({\|{\bf Z}\|^p_2 + p \|{\bf Z}\|^{p-2}_2{\bf Z} 
\cdot {\bf X}}\right) \right\}.$$

\noindent (ii) For $1<p\le 2$:$$\| {\bf X}+{\bf Z}\|^p_2\le 2^{1-(p/2)}
m_{p}^{p}\| {\bf X}\|^p_2+
\|{\bf Z}\|^p_2+p\| {\bf Z}\|^{p-2}_2{\bf Z} \cdot {\bf X},$$
where $m_{p}^{p}$ is defined in (4.6).

\bigbreak
\centerline{\bf V. Perturbation of the boundary}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\medskip  
\noindent
In this section we use the results stated in Section III to estimate
how the first eigenvalue of 
the $p$-Laplacian, or the $p$-Laplacian plus a potential,
depends on the domain.  
Again we follow ideas of [E2] and [D2].
More precisely, we wish to compare the fundamental eigenvalues
for $\Omega$ and for the retracted domain 
$\Omega_{\varepsilon} = \{{\bf x} \in \Omega/ d({\bf
x})>\varepsilon\}$.  We
shall find it convenient to define
$\Gamma_{\varepsilon} = \{{\bf x} \in \Omega/ d({\bf x})<\varepsilon\}$
and
$S_{\varepsilon} =  \Omega_{\varepsilon} \cap \Gamma_{2\varepsilon}.$
 \par \noindent
 We denote by
 $\lambda_1(\Omega) $ the first eigenvalue of the Dirichlet
$p$-Laplacian on 
 $\Omega$. By the variational principle, we have
 $$ \lambda_1(\Omega) \leq \lambda_1(\Omega_{\varepsilon}) .$$
Our main result in this section is the following
 
 
\proclaim{Theorem V.1}.
There exists a positive constant $k$ depending only 
 on $p$, $N$, and $\Omega$, such that for $\varepsilon$ sufficiently
small,
 $$\lambda_1(\Omega_{\varepsilon}) \leq \lambda_1(\Omega) + 
 k \varepsilon^{{p\over{\hat m c_p}}}.$$
 
\noindent
{\bf Proof:} We introduce $\mu: \Omega \longrightarrow [0; +\infty)$ 
 defined by
 $$  \mu({\bf x}) = \cases{
 0  & if ${\bf x} \in  \Gamma_{\varepsilon}$, \cr
 \varepsilon^{-1} (d({\bf x})-\varepsilon) &
    if ${\bf x} \in   S_{\varepsilon}$, \cr
 1  & if ${\bf x} \in \Omega_{2\varepsilon}$. \cr}
 $$ 
Let $\phi_1$ be the first eigenfunction of the Dirichlet  $p$-Laplacian 
  on $\Omega$ such that $\Vert \phi_1\Vert_{L^p}=1$.   We have
$$\eqalign{
\int_{\Omega} \left(|\nabla (\mu\phi_1)|^p -  |\nabla \phi_1|^p\right)
=& \int_{\Gamma_{2\varepsilon}} \left(|\nabla (\mu\phi_1)|^p
   - |\nabla \phi_1|^p\right) \cr
\leq&  \int_{S_{\varepsilon}}\left(|\nabla (\mu\phi_1)|^p 
  -  |\nabla \phi_1|^p \right)  \cr
\leq&  \int_{S_{\varepsilon}}\left[\left(|\nabla \phi_1| + 
  |{\phi_1\over \varepsilon} | \right)^p - |\nabla \phi_1|^p \right] \cr
\leq & p \int_{S_{\varepsilon}} |{\phi_1\over \varepsilon} | 
  \left(|\nabla \phi_1| + 
  |{\phi_1\over \varepsilon} | \right)^{p-1} \cr
\leq &
  K\int_{S_{\varepsilon}} |{\phi_1\over \varepsilon} |^p + 
  K \left(\int_{S_{\varepsilon}} 
  |{\phi_1\over \varepsilon} |^p\right)^{{1\over p}}
  \left(\int_{S_{\varepsilon}}|\nabla \phi_1|^p\right)^{{1\over p'}}.\cr
}$$
From Theorem III.4, we deduce that
  $$\int_{\Omega} \left(|\nabla (\mu\phi_1)|^p -  |\nabla \phi_1|^p
\right)
  \leq  K' \varepsilon^{{p\over {\hat m c_p}}} + 
  K''\varepsilon^{{p\over {\hat m c_p}}\left({1\over p}+ {1\over
p'}\right)} \leq 
  K \varepsilon^{{p\over {\hat m c_p}}}.$$
  Hence 
  $$\int_{\Omega} |\nabla (\mu\phi_1)|^p \leq 
  \lambda_1(\Omega) + K\varepsilon^{{p\over {\hat m c_p}}}.$$
 From the variational principle we conclude that
  $$\int_{\Omega} |\nabla (\mu\phi_1)|^p \geq
\lambda_1(\Omega_{\varepsilon})
  \int_{\Omega}|\mu\phi_1|^p .
  $$
Now,
  $$\eqalign{ \int_{\Omega}|\phi_1|^p
  =& \int_{\Omega}|\mu\phi_1+(1-\mu)\phi_1|^p \cr
  \leq& \int_{\Omega}|\mu\phi_1|^p + 
  \int_{\Omega}(1-\mu)^p|\phi_1|^p \cr
\leq& \int_{\Gamma_{2\varepsilon}}|\phi_1|^p +
   \int_{\Omega}|\mu\phi_1|^p \cr
\leq& K \varepsilon^{{p\over {\hat m c_p}}+p}+
   \int_{\Omega}|\mu\phi_1|^p .\cr}
$$
Thus
  $$ \int_{\Omega} |\nabla (\mu\phi_1)|^p \geq
\lambda_1(\Omega_{\varepsilon})
  \left[1-K\varepsilon^{{p\over {\hat m c_p}}+p}\right],$$
and hence for $\varepsilon$ sufficiently small
  $$\eqalign{ \lambda_1(\Omega_{\varepsilon})
 \leq & {{\lambda_1(\Omega)+K\varepsilon^{{p\over {\hat m c_p}}}}
  \over {1 - K\varepsilon^{p+{p\over {\hat m c_p}}}}} \cr
\leq & \lambda_1(\Omega)+K(1+2\lambda_1(\Omega))
  \varepsilon^{{p\over {\hat m c_p}}} \cr
\leq & \lambda_1(\Omega) + k \varepsilon^{{p\over{\hat m c_p}}}.
} $$
\hfill $\diamondsuit$ 

Estimates of this type apply, with the same power of $\varepsilon$ under
conditions as in Section III, to the
$p$-Laplacian with a potential. 

\bigbreak
\centerline{\bf VI. $L^s(\Omega)$ estimates for solutions of 
$|u|^{p-2}{u}_{t}= {\Delta }_{p}u-V({\bf x})|u|^{p-2} u$}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
\medskip 
\noindent
In this section we turn our attention to the Cauchy problem 
for evolution equations of the form 
$$|u|^{p-2}{u}_{t}= {\Delta }_{p}u-V({\bf x})|u|^{p-2} u. 
 \eqno(6.1)
$$
The reason for the factor $|u|^{p-2}$ on the left side is that 
it guarantees that the equation is homogeneous 
(see the definition $(1.3)$ of the $p$-Laplacian).

In this section, we assume that 
$V({\bf x}) = V_{1}({\bf x})  + V_{2}({\bf x})$,
where $V_{1}({\bf x}) \ge 0$ and $|V_2|$ satisfies a 
bound of the form                  
$$\int_{\Omega }\left|{V_2}\right|{\left|{\zeta }\right|}^{p}\
{d}^{N}x 
\le \alpha \int_{\Omega }{\left|{\nabla \zeta
}\right|}^{p}
{d}^{N}x+\beta \int_{\Omega }{\left|{\zeta }\right|}^{p}\
{d}^{N}x,  \eqno(6.2)
$$
with $\alpha < \infty$.
We recall that in Section II we provided some 
criteria for this bound; for instance, by Corollary II.4,
if $N>p$, then the negative part 
of $V({\bf x})$ may be bounded in magnitude by a sufficiently small 
constant, proportional to $\alpha$, 
times a sum of terms with local divergences of the form
${1 \over {\left|{\bf x-{\bf x}_{0}}\right|}^{p}}$.

Belyi and Semenov [B2] and Liskevich [L1] 
have shown that for certain linear differential
operators the growth in time $t$ of $\|u(t,x)\|_{L^p(\Omega)}$  
can be estimated when the negative part of $V$ is 
relatively form bounded.
In this section we show that similar estimates are valid
for solutions of $(6.1)$.  We consider only classical solutions 
of $(6.1)$ on regular domains, with
vanishing Dirichlet boundary conditions, and content ourselves with 
two theorems, which sufficiently well illustrate the idea.

\proclaim{Theorem VI.1}. Assume that u is a classical solution of
equation (6.1), $u$ belongs to $W_{0}^{1,p}(\Omega) \cap L^s(\Omega)$,
$s \geq p$, and $-\Delta_p u \in L^{\infty}(\Omega)$.  Assume moreover that
the potential $V({\bf x})$ satisfies (6.2) with
$\alpha \le \left({s+1-p}\right){\left({{p \over s}}\right)}^{p}$. 
Let  ${f}_{s,u}\left({t}\right):={\| u\left({t;\bf x}\right)\|
}_{{L}^s\left({\Omega }\right)}$.
Then 
$${f}_{s,u}\left({t}\right)\le {f}_{s,u}\left({0}\right)\exp
\left({\beta t}\right).$$


\noindent
{\bf Proof:} 
We write $r = s - p$ and 
multiply (6.1) by $|u|^{r}u$ and integrate.  
We find
$$\eqalign{
{1\over p+r} \, {d\over dt}\int_\Omega|u|^{p+r} &=
\int\left\{ |u|^ru\nabla\cdot (|\nabla u|^{p-2}\nabla
u)-V|u|^{p+r}\right\}\cr
&\le -\int\left\{\nabla (|u|^ru)\cdot|\nabla u|^{p-2}\nabla u\right\}
+\int|V_2| |u|^{p+r}\cr
&= -(r+1)\int\left\{ |u|^r|\nabla u|^p\right\} +
\int |V_2| |u|^{p+r}\cr
&\le -(r+1)\int |u|^r|\nabla u|^p + \alpha\int\left|
\nabla \left( u^{(p+r)/p}\right)\right|^p + \beta \int |u|^{(p+r)} \cr
&=\left(\alpha {p+r\overwithdelims () p}^p-(r+1)\right)\int |u|^r|\nabla
u|^p + \beta \int |u|^{(p+r)}}.
$$
The assumption on $\alpha$ makes the first term in the
final line $\le 0$, so we drop it, obtaining
$$
{d \over dt}{\| u\| }_s^s\le \beta s{\| u\| }_s^s,$$
which implies the claim.
\hfill $\diamondsuit$

\proclaim{Theorem VI.2}. 
Assume that u is a positive solution of a differential 
equation for which the differential inequality
$$|u|^{p-2}{u}_{t}\leq {\Delta }_{p}u-V({\bf x})|u|^{p-2} u.
\eqno(6.3)$$
holds, that
$u \in W_{0}^{1,p}(\Omega) \cap L^s(\Omega)$, $s \geq p$, and 
$-\Delta_p u \in L^{\infty}(\Omega)$.  Assume moreover that
the potential $V({\bf x})$ satisfies (6.2) with
$\alpha \le \left({s+1-p}\right){\left({{p \over s}}\right)}^{p}$. 
Let 
$${f}_{s,u}\left({t}\right):={\| u\left({t;\bf 
x}\right)\| 
}_{{L}^s\left({\Omega }\right)}.$$
Then
$${f}_{s,u}\left({t}\right)\le {f}_{s,u}\left({0}\right) \exp
\left({\beta t}\right).$$


\noindent
{\bf Proof:} 
Exactly as for Theorem VI.1; positivity matters because the proof
requires the inequality to be multiplied by a power of $u$.
\hfill $\diamondsuit$
\medskip

\noindent{\bf Acknowledgments.}
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
The authors wish to thank W. D. Evans, D. J. Harris, V. Liskevich, and P. 
Tak\'a\v{c}  for their useful conversations and references.

\bigbreak
\centerline{\bf References}

\item{[B1]}
J. Barta, 
Sur la vibration fondamentale d'une membrane, 
{\it C.R. Acad. Sci. Paris} 204(1937), 472-473.

\item{[B2]}
A.G. Belyi and Yu.A. Semenov,
On the $L^p$-theory of Schr\"odinger semigroups, 
{\it Sibirsk. Mat. J.} {\bf 31}(1990), 16-26; English
translation in 
{\it Siberian. Math. J.} {\bf 31}(1991), 540-549.

\item{[B3]} T. Boggio, 
Sull'equazione del moto vibratorio delle 
membrane elastiche,
{\it Accad. Lincei, sci. fis.}, ser. 5a{\bf 16}(1907), 386-393.

\item{[D1]} E.B. Davies,
{\it Heat kernels and spectral theory},
Cambridge, University Press, 1989.

\item{[D2]} E.B. Davies, 
Sharp boundary estimates for elliptic operators, preprint 1998.

\item{[D3]} P. Dr\'abek, P. Krej\v{c}\'\i , and P. Tak\'a\v{c}, 
{\it Nonlinear Differential Equations},
Boca Raton, FL,  CRC Press, to appear.

\item{[D4]} R.J. Duffin, 
Lower bounds for eigenvalues, 
{\it Phys. Rev.} {\bf 71}(1947), 827-828.

\item{[E1]} D.E. Edmunds and W.D. Evans,
{\it Spectral theory and differential operators},
Oxford, Clarendon Press, 1987.

\item{[E2]} W.D. Evans, D.J. Harris, and R. Kauffman,
Boundary behaviour of Dirichlet eigenfunctions of second 
order elliptic equations,
{\it Math. Z.} {\bf 204}(1990), 85-115.

\item{[H1]} G.H. Hardy, J.E. Littlewood, and G. P\'olya,
{\it Inequalities}. 
Cambridge,  University Press, 1959.

\item{[L1]} V. Liskevich, 
On $C_0$-semigroups generated by elliptic second order differential
expressions on $L^p$-spaces,
{\it Diff. and Int. Eqns.} {\bf 9}(1996), 811-826.

\item{[M1]}  
M. Marcus, V. J. Mizel, and Y. Pinchover, 
On the best constant for Hardy's inequality in ${\Bbb R}^n$,
{\it Trans. Amer. Math. Soc.} 350(1998), 3237-3255.

\item{[M2]}
E. Mitidieri,
A simple approach to Hardy's inequalities, preprint.


\item{[P1]}
M.M.H. Pang,
Approximation of ground state eigenvalues of eigenfunctions 
of Dirichlet Laplacians.
{\it Bull. London Math. Soc.} {\bf 29}(1997), 720-730.


\item{[S1]} 
B. Simon, Schr\"odinger semigroups, 
{\it Bull. Amer. Math. Soc.} 7(1982), 447-526.


\bigskip 

% Erratum for   Vol. 1999 No.  38

\centerline{{\bf ERRATUM}: Submitted on April 28, 2003.} 
\smallskip

\noindent
In Corollary II.4, the formula
 $$
 \Big({p \over N-p}\Big)^{p-1}
 \int_{\Omega }\big|\nabla \zeta|^p d^N x\ge \int_\Omega \Big|{\zeta  \over |{\bf x}|} 
 \Big|^p d^N x.
$$
should be replaced by
 $$
 \Big({p \over N-p}\Big)^p
 \int_{\Omega }\big|\nabla \zeta|^p d^N x\ge \int_\Omega \Big|{\zeta  \over |{\bf x}|} 
 \Big|^p d^N x.
$$
\medskip


\noindent Jacqueline Fleckinger \hfill\break
CEREMATH \& UMR MIP, Universit\'e Toulouse-1 \hfill\break
21 all\'ees de Brienne \hfill\break
31000 Toulouse, France  \hfill\break
e-mail address: jfleck@univ-tlse1.fr 

\noindent Evans M. Harrell II \hfill\break
School of Mathematics, Georgia Tech \hfill\break
Atlanta, GA 30332-0160, USA, and \hfill\break 
UMR MIP, Universit\'e Paul Sabatier \hfill\break
31062 Toulouse, France  \hfill\break
e-mail address:  harrell@math.gatech.edu


\noindent  Fran\c cois de Th\'elin \hfill\break
UMR MIP, Universit\'e Paul Sabatier\hfill\break
31062 Toulouse, France \hfill\break
e-mail address: dethelin@mip.ups-tlse.fr 

\bye