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On the existence of a nodal solution for p-Laplacian equations depending on the gradient

Published online by Cambridge University Press:  31 January 2024

F. Faraci
Affiliation:
Department of Mathematics and Computer Sciences, University of Catania, 95125 Catania, Italy ([email protected], [email protected])
D. Puglisi
Affiliation:
Department of Mathematics and Computer Sciences, University of Catania, 95125 Catania, Italy ([email protected], [email protected])
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Abstract

In the present paper we deal with a quasi-linear elliptic equation depending on a sublinear nonlinearity involving the gradient. We prove the existence of a nontrivial nodal solution employing the theory of invariant sets of descending flow together with sub-supersolution techniques, gradient regularity arguments, strong comparison principle for the $p$-Laplace operator. The same conclusion is obtained for an eigenvalue problem under a different set of assumptions.

Type
Research Article
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of The Royal Society of Edinburgh

1. Introduction

In the present paper we study the following quasilinear problem

(P)\begin{equation} \left\{\begin{array}{@{}ll@{}} -\Delta_p u= f(x,u, \nabla u) & {\rm in}\ \Omega, \\ u=0 & {\rm on}\ \partial\Omega, \end{array}\right. \end{equation}

where $\Omega$ is a smooth bounded domain in $\mathbb {R}^N$, $1< p< N$ and $f:\Omega \times \mathbb {R} \times \mathbb {R}^N\to \mathbb {R}$ is a continuous function fulfilling suitable growth conditions at zero and at infinity.

Problem $(P)$ appears in connection with the study of non-Newtonian fluids, where $p$ is related to the characteristics of the medium (dilatant for $p>2$, pseudoplastic for $p<2$). The forcing term $f$ is a convection type term, i.e. it depends on the gradient of the unknown function. The dependence on the gradient in the nonlinearity does not allow to apply in a straightforward way variational methods to find solutions of $(P)$. However, the existence of constant sign solutions for $(P)$ has been obtained by means of topological degree, method of sub-supersolutions, fixed point theory and approximation techniques (see for instance [Reference Amann and Crandall1, Reference Boccardo, Gallouët and Orsina7, Reference De Figueiredo, Girardi and Matzeu12, Reference Pohožaev20, Reference Ruiz21] and the references therein). When the source term does not depend on the gradient, the study of sign changing solutions for semilinear and quasilinear elliptic problems has been addressed in a number of papers. If $p=2$ and $f=f(u)$ is superlinear and subcritical, the existence of a nodal solution (together with a positive and a negative one) has been proved for instance in [Reference Bartsch and Wang6] employing Morse theory and the strong maximum principle, or in [Reference Dancer and Du11] using topological degree technique, assuming also that $f'(0)<\lambda _1$ (being $\lambda _1$ the first eigenvalue of the negative Laplacian). In [Reference Dancer and Du11], the sublinear case is also addressed and under the condition $f'(0)>\lambda _2$ (being $\lambda _2$ the second eigenvalue of the negative Laplacian) the existence of the biggest negative solution, the smallest positive solution and of a nontrivial solution in between (thus nodal) is achieved. The theory of invariant sets of descending flow defined by a pseudogradient vector field is deeply investigated in [Reference Liu and Sun19] to localize nodal solutions of a superlinear semilinear problem in different invariant sets. For $p\not =2$ several contributions extend the quoted results to a nonlinear setting: the existence of nodal solutions is proved in [Reference Bartsch and Liu3Reference Bartsch, Liu and Weth5, Reference Sun and Sun22, Reference Zhang and Li24] where the theory of invariant sets of descending flow is exploited under various assumptions on $f$ both in the superlinear and in the sublinear case, or in [Reference Carl and Perera8] by variational and sub–supersolution techniques.

The existence of nodal solutions when $f$ depends on the gradient is still an almost unexplored issue. Motivated by [Reference Faraci, Motreanu and Puglisi13], where the existence of a positive and a negative solution (actually extremal) for problem $(P)$ has been proved, the following questions arise naturally.

Question 1.1

  1. 1. Does problem $(P)$ admit a nodal solution for $p>1$?

  2. 2. Beside the smallest positive and the biggest negative solution does there exist a non-trivial nodal solution for problem $(P)$ in between?

The first question has been partially solved in [Reference Liu, Shi and Wei18] and [Reference Faraci and Puglisi15] where the existence of a nodal solution in the presence of a nonlinearity depending on the gradient has been addressed in the case $p=2$. In [Reference Liu, Shi and Wei18], the authors assume $f$ to be a superlinear function, locally Lipschitz with respect to both the second and the third variable in a neighbourhood of zero, with some further assumptions on the gradient variable. Using the Nehari method, they obtain a sign changing solution as the limit of a sequence of ‘approximated’ nodal functions. In [Reference Faraci and Puglisi15] the sublinear case is studied and the existence of a nodal solution is ensured by suitable growth conditions at zero in the real (second) variable via the theory of invariant sets of descending flow.

In the present paper, we completely solve the first question above for any $1 < p < \infty$. In the first part of the paper we extend the results of [Reference Faraci and Puglisi15] pointing out some difficulties which arise from the quasilinear setting which prevent a straightforward generalization of the conclusions of [Reference Faraci and Puglisi15]. Combining the gradient flow theory with some essential tools as a gradient regularity result and strong comparison principle for the $p$-Laplacian we prove the existence of a nodal solution for a parametrized problem with variational structure. An iteration procedure allows to create a sequence of sign changing solutions converging to a non-trivial nodal solution.

Together with the conclusion of [Reference Faraci, Motreanu and Puglisi13] (see also [Reference Faraci and Puglisi14]), where the existence of the smallest positive solution and of the biggest negative solution for $(P)$ was proved via sub-super solution methods and fixed point arguments, we obtain a multiplicity theorem under very natural and verifiable assumptions. It still remains an open question whether the nodal solution lies in between (see remark 5.1). In the last part of the paper we give another contribution to the first question, suggesting a different set of hypotheses to prove the existence of sign changing solutions for an eigenvalue problem.

We believe that this work represents the first step in the search of nodal solutions for quasilinear problems depending on the gradient.

Denote by $\|\cdot \|$, the standard norm in $W^{1,p}_0(\Omega )$, i.e. $\|u\|=(\int _{\Omega } |\nabla u|^p\,{\rm d}x)^{1/p}$, and by $\|\cdot \|_q$, $\|\cdot \|_{\infty }$ the classical norms in $L^q(\Omega )$ and in $L^\infty (\Omega )$ respectively, i.e. $\|u\|_q=(\int _\Omega |u|^q\,{\rm d}x)^{1/q}$ and $\|u\|_\infty ={\rm supess}_\Omega |u|$. Let $\lambda _1$ be the first eigenvalue of the negative $p$-Laplacian operator on $W^{1,p}_0(\Omega )$, with first positive eigenfunction $\varphi _1$ satisfying $\|\varphi _1\|=1$. The following variational characterization holds

\[ \lambda_1=\inf\left\{ \frac{\|u\|^p}{\|u\|_p^p}: \ u\in W^{1,p}_0(\Omega), u\neq 0 \right\}. \]

It is well known that the cone of nonnegative functions

\[ C^1_0(\overline\Omega)_+{=}\{u\in C^1_0(\overline\Omega): u\geq 0 \ \text{in}\ \Omega\} \]

has a nonempty interior in the Banach space $C^1_0(\overline \Omega )$ given by

\[ \mathrm{int}(C^1_0(\overline\Omega)_+)=\left\{u\in C^1_0(\overline\Omega): u>0 \ { \rm in} \ \Omega, \ \frac{\partial u}{\partial\nu}<0 \ { \rm on}\ \partial\Omega\right\}, \]

where $\nu$ stands for the outward normal unit vector to $\partial \Omega$.

Our first set of assumptions is:

  1. (f 1) there exist positive constants $k_0,\theta _0,\theta _1$ with $\theta _0+\theta _1\lambda _1^{1/p'}<\lambda _1$ such that

    \[ |f(x,s,\xi)|\leq k_0+\theta_0|s|^{p-1}+\theta_1|\xi|^{p-1} \]
    for all $x\in \Omega$, $s\in \mathbb {R}$, and $\xi \in \mathbb {R}^N$;
  2. (f 2) for every $M>0$ there exists a constant $\eta _M>\lambda _1$ such that

    \[ \liminf_{s\to 0}\frac{f(x,s,\xi)}{|s|^{p-2}s}\geq \eta_M \]
    uniformly for all $x\in \Omega$ and all $\xi \in \mathbb {R}^N$ with $|\xi |\leq M$;
  3. (f 3) for every $M>0$ there exists a constant $\zeta _M>0$ such that

    \[ \limsup_{s\to 0}\frac{f(x,s,\xi)}{|s|^{p-2}s}\leq \zeta_M \]
    uniformly for all $x\in \Omega$ and all $\xi \in \mathbb {R}^N$ with $|\xi |\leq M$;
  4. (f 4) for every $M>0$ there exists a constant $m_M>0$ such that

    \[ s\to f(x,s,\xi)+m_M |s|^{p-2}s \]
    is increasing for all $x\in \Omega$ and all $\xi \in \mathbb {R}^N$ with $|\xi |\leq M$.

Under such assumptions we prove the following.

Theorem 1.1 Let $\Omega$ be a smooth bounded domain in $\mathbb {R}^N$ and $f:\Omega \times \mathbb {R} \times \mathbb {R}^N\to \mathbb {R}$ a continuous function satisfying $(f_1)-(f_4)$. Then, problem $(P)$ has a nodal solution in $C^1_0(\overline {\Omega })$.

Combining such conclusion with [Reference Faraci, Motreanu and Puglisi13, Theorem 1.3, Corollary 1.1] we can state the following multiplicity result:

Corollary 1.1 Let $\Omega$ be a smooth bounded domain in $\mathbb {R}^N$ and $f:\Omega \times \mathbb {R} \times \mathbb {R}^N\to \mathbb {R}$ a continuous function satisfying $(f_1)-(f_4)$. Then, problem $(P)$ has the smallest positive solution $u_P \in \mathrm {int}(C^1_0(\overline \Omega )_+)$, the biggest negative solution $u_N \in -\mathrm {int}(C^1_0(\overline \Omega )_+)$ and a nodal solution $\tilde u\in C^1_0(\overline {\Omega })$.

In the last part of the paper, still exploiting the same iterative approach, we deduce the existence of a nodal solution for the quasilinear elliptic eigenvalue problem

(P λ)\begin{equation} \left\{ \begin{array}{@{}ll@{}} -\Delta_p u= \lambda f(x,u, \nabla u) & {\rm in}\ \Omega, \\ u=0 & {\rm on}\ \partial\Omega. \end{array}\right. \end{equation}

Let us introduce the following assumptions:

  1. $(\tilde f_1)$

    \[ \lim_{(s, \xi)\to \infty}\frac{f(x,s,\xi)}{|s|^{p-1}+|\xi|^{p-1}}=0 \]
    uniformly for all $x\in \Omega$;
  2. $(\tilde f_2)$ for every $M>0$,

    \[ \lim_{s\to 0}\frac{f(x,s,\xi)}{|s|^{p-1}}=0 \]
    uniformly for all $x\in \Omega$ and all $\xi \in {\mathbb {R}}^N$ with $|\xi |\leq M$;
  3. $(\tilde f_3)$ for every $M>0$,

    \[ \lim_{s\to \infty}\frac{f(x,s,\xi)}{|s|^{p-1}}=0 \]
    uniformly for all $x\in \Omega$ and all $\xi \in {\mathbb {R}}^N$ with $|\xi |\leq M$;
  4. $(\tilde f_4)$ for every $M>0$, there exists $R_M>0$ such that $s f(x,s,\xi )>0$ for all $x\in \Omega$, $|s|>R_M$ and all $\xi \in {\mathbb {R}}^N$ with $|\xi |\leq M$;

  5. $(\tilde f_5)$ there exist $s^-<0< s^+$ such that

    \begin{align*} &\inf_{(x, \xi) \in \Omega \times {\mathbb{R}}^N}F(x, s^{{\pm}}, \xi)>0, \\ &\hbox{where}\ F(x,s,\xi) =\int_0^s f(x,t,\xi) dt.\end{align*}

Our second result states the following.

Theorem 1.2 Let $\Omega$ be a smooth bounded domain in $\mathbb {R}^N$ and $f:\Omega \times \mathbb {R} \times \mathbb {R}^N\to \mathbb {R}$ a continuous function satisfying $(\tilde f_1)-(\tilde f_5)$. Then, there exists $\tilde \lambda$ such that for each $\lambda >\tilde \lambda$, problem $(P_\lambda )$ has a nodal solution in $C^1_0(\overline {\Omega })$.

The plan of the paper is the following: in Section 2 we introduce some common preliminaries. Sections 3 and 4 are devoted to prove our main theorems. Finally, in Section 5 some open questions and final remarks are discussed.

2. Preliminaries

In this section we collect some common preliminaries which will be useful in our study. We introduce the following quasilinear problem

()\begin{equation} \left\{ \begin{array}{@{}ll@{}} -\Delta_p u= g(x,u, \nabla u) & {\rm in}\ \Omega \\ u=0 & {\rm on}\ \partial\Omega. \end{array}\right. \end{equation}

where $\Omega$ is a smooth bounded domain in $\mathbb {R}^N$, $1< p< N$, $g:\Omega \times \mathbb {R} \times \mathbb {R}^N\to \mathbb {R}$ is a continuous function such that $g(x,0,\xi )=0$ for all $x,\xi$ and

  1. ($\mathcal {H}$) there exist positive constants $k_0,\theta _0,\theta _1$ with $\theta _0+\theta _1\lambda _1^{1/p'}<\lambda _1$ such that

    \[ |g(x,s,\xi)|\leq k_0+\theta_0|s|^{p-1}+\theta_1|\xi|^{p-1} \]
    for all $x\in \Omega$, $s\in \mathbb {R}$, and $\xi \in \mathbb {R}^N$.

For every $w\in C^1_0(\overline \Omega )$, let us also consider the parametrized Dirichlet problem

( w)\begin{equation} \left\{ \begin{array}{@{}ll@{}} -\Delta_p u= g(x,u, \nabla w) & {\rm in}\ \Omega \\ u=0 & {\rm on}\ \partial\Omega. \end{array}\right. \end{equation}

Notice that since $w\in C^1_0(\overline \Omega )$, classical regularity results implies that each solution $u$ of $(P_w)$ is in $L^\infty (\Omega )$, thus in $C^1_0(\overline \Omega )$ (see [Reference Ladyzhenskaya and Uraltseva16, Reference Lieberman17]).

Moreover, from $g(x,0,\xi )=0$ for all $x,\xi$ we observe that the zero function is a solution of both $(\tilde P)$ and $(\tilde P_w)$ for each $w\in C^1_0(\overline \Omega )$.

Proposition 2.1 below proves an a priori uniform boundedness which will be crucial for our purposes. It makes use of the following gradient regularity result ([Reference Cianchi and Maz'ya9, Theorem 4.3]):

Lemma 2.1 Let $\Omega$ be a smooth bounded domain in ${\mathbb {R}}^N$, $N\geq 2$, and let $u\in W^{1,p}_0(\Omega )$, $1< p< N$, be a weak solution of the problem

\[ \left\{ \begin{array}{@{}ll@{}} -\Delta_p u= h(x) & {\rm in}\ \Omega \\ u=0 & {\rm on}\ \partial\Omega. \end{array}\right. \]

with $h\in L^q(\Omega )$, $q\geq (p^\ast )'$.

  1. $(i)$ If $q< N$, then

    \[ \|\nabla u\|_{q^\ast(p-1)}\leq C\|h\|_{q}^\frac{1}{p-1}. \]
  2. $(ii)$ If $q=N$, then

    \[ \|\nabla u\|_{r}\leq C\|h\|_{q}^\frac{1}{p-1} \ \text{for any}\ r<\infty. \]
  3. $(iii)$ If $q>N$, then

    \[ \|\nabla u\|_{\infty}\leq C\|h\|_{q}^\frac{1}{p-1}. \]

In what stated above, $C$ is a constant that depends only on $p,N,q$.

Proposition 2.1 Assume $(\mathcal {H})$. Then, for every $u_0\in C^1_0(\overline \Omega )$, there exists $\alpha \in ]0,1[$ and a positive constant $M$ depending on $k_0, \theta _0,\theta _1, \|u_0\|$ such that if $u_n$ is a solution of $(P_{u_{n-1}})$ one has

\[ \|u_n\|_{C^{1,\alpha}(\overline\Omega)}\leq M \quad \text{for every}\ n\in\mathbb{N}. \]

Proof. Let us fix $u_0\in C^1_0(\overline \Omega )$. We first prove that if $u_n$ is a solution of $(\tilde P_{u_{n-1}})$, then $\|u_n\|\leq M_0$ for some constant $M_0=M_0(\|u_0\|)$ independent on $n$. Indeed, acting with $u_n$ as test function in $(\tilde P_{u_{n-1}})$,

\begin{align*} \|u_n\|^p& \leq \int_{\Omega }|g(x,u_n,\nabla u_{n-1})||u_n|\,{\rm d}x \\ & \leq k_0\|u_n\|_1+\theta_0\|u_n\|_p^p+\theta_1\|u_{n-1}\|^{p-1} \|u_n\|_p\\ & \leq k_0|\Omega|^{1/{p}}\lambda_1^{{-}1/p}\|u_n\|+\theta_0\lambda_1^{{-}1}\|u_n\|^p+\theta_1\lambda_1^{{-}1/{p}}\|u_{n-1}\|^{p-1}\|u_n\| \end{align*}

which implies

\[ \left(1-\theta_0\lambda_1^{{-}1}\right)\|u_n\|^{p-1}\leq k_0|\Omega|^{1/{p}}\lambda_1^{{-}1/p}+\theta_1\lambda_1^{{-}1/{p}}\|u_{n-1}\|^{p-1}. \]

Denote by

\[ \gamma:=\frac{k_0|\Omega|^{1/{p}}\lambda_1^{{-}1/p}}{1-\theta_0\lambda_1^{{-}1}}, \quad\ \delta:=\frac{\theta_1\lambda_1^{{-}1/{p}}}{1-\theta_0\lambda_1^{{-}1}}. \]

Notice that $\gamma >0$ and $0<\delta <1$. Thus, using the above notation, we can rewrite

\[ \|u_n\|^{p-1}\leq\gamma +\delta \|u_{n-1}\|^{p-1}. \]

Iterating this inequality, we obtain

\begin{align*} \|u_n\|^{p-1}& \leq \gamma \sum_{i=0}^{n-1}\delta^i+\delta^n\|u_0\|^{p-1}\\ & \leq \frac{\gamma}{1-\delta} + \|u_0\|^{p-1}, \end{align*}

which means that there exists a constant $M_0$ (depending on $\|u_0\|$) such that

\[ \|u_n\|\leq M_0 \quad \text{for every}\ n\in\mathbb{N}. \]

Denote $h_n(x)=g(x, u_n(x), \nabla u_{n-1}(x))$ and fix $q$ with $(p^\ast )'\leq q\leq p'$ such that $\frac {N}{q}\notin \mathbb {N}.$ Using the fact that $|u_n|^{p-1}, |\nabla u_{n-1}|^{p-1}\in L^q(\Omega )$ (recall that $u_n\in L^\infty (\Omega )$), and $(\mathcal {H})$, we deduce that $h_n\in L^q(\Omega )$ and its norm $\|h_n\|_q$ can be estimated by a constant which does not depend on $n$:

\begin{align*} \|h_n\|_q^q & \leq k'_0+\theta'_0\|u_n\|_{{q(p-1)}}^{q(p-1)}+\theta'_1\|\nabla u_{n-1}\|_{{q(p-1)}}^{q(p-1)}\leq\\ & \leq k'_0+\theta''_0\|u_n\|_{p}^{\frac{q}{p'}}+\theta''_1\|\nabla u_{n-1}\|_{p}^{\frac{q}{p'}} \end{align*}

Hence

\[ \|h_n\|_q\leq M'_0 \quad \text{for every}\ n\in\mathbb{N}. \]

We can assume $q\leq N$, otherwise we are done by lemma 2.1 $(iii)$.

From lemma 2.1 $(i)-(ii)$ we deduce that $|\nabla u_n|\in L^{q^\ast (p-1)}(\Omega )$ and that

\[ \|\nabla u_n\|_{{q^\ast(p-1)}}\leq C\|h_n\|_{q}^\frac{1}{p-1}\leq C_1. \]

Since $u_n\in L^\infty (\Omega )$ we have that $|u_n|^{p-1}\in L^{q^\ast }(\Omega )$. Moreover, by the previous inequality we also have $|\nabla u_{n-1}|^{p-1}\in L^{q^\ast }(\Omega )$, thus $h_n \in L^{q^\ast }(\Omega )$ and, as above $\|h_n\|_{q^\ast }\leq M'_1$.

It is easily seen by induction that $(((q^*)^*)^{\cdot \cdot \cdot })^*=q^{\overset {k}{**\cdot \cdot \cdot *}}=\frac {Nq}{N-kq}$ provided $k<\frac {N}{q}.$ We choose then $k=[\frac {N}{q}]$ (the maximum integer contained in $\frac {N}{q}$). Recall that since $\frac {N}{q}\notin \mathbb {N},$

\[ \frac{N}{q}-1< k<\frac{N}{q} \]

Iterating the previous argument $k$ times, since $\frac {Nq}{N-kq}>N$, by lemma 2.1 $(iii)$

\[ \|\nabla u_n\|_\infty\leq C \|h_n\|_{\frac{Nq}{N-kq}}^{\frac{1}{p-1}}\leq C_k. \]

The uniform boundedness of the gradient of $u_n$ in $L^{\infty }(\Omega )$, implies the uniform boundedness of $u_n$'s in $L^\infty (\Omega )$ (see [Reference Ladyzhenskaya and Uraltseva16]). Finally, from [Reference Lieberman17, Theorem 1] we obtain the existence of $\alpha \in ]0,1[$ and a positive constant $M$ independent on $n$ such that

\[ \|u_n\|_{C^{1,\alpha}(\overline\Omega)}\leq M \quad \text{for every}\ n\in\mathbb{N}. \]

We introduce now the following abstract setting. Let $X$ be a Banach space, $A:X \longrightarrow X$ continuous and compact operator, $J:X\to \mathbb {R}$ a functional of class ${C}^1(X, \mathbb {R})$, $p>1$.

Let us introduce the following conditions:

  1. $(J_1)$ There exist $1< p< 2$, $d_1, d_2>0$ such that

    \[ \langle J^{\prime}(u), u- A(u) \rangle \geq d_1\|u- A(u)\|^2 (\|u\| + \|A(u)\|)^{p-2} \]
    and
    \[ \|J^{\prime}(u)\| \leq d_2\|u- A(u)\|^{p-1}, \]
    for every $u \in X$.
  2. $(J_2)$ There exist $p\geq 2$, $d_3, d_4>0$ such that

    \[ \langle J^{\prime}(u), u- A(u) \rangle \geq d_3\|u- A(u)\|^p \]
    and
    \[ \|J^{\prime}(u)\| \leq d_4\|u- A(u)\| (\|u\| + \|A(u)\|)^{p-2}, \]
    for every $u \in X$.

Denote by $K$ the set of critical points of $J$: it is clear that under either $(J_1)$ or $(J_2)$ $K$ coincides with the set of fixed points of $A$.

The next lemma allows to replace $A$ with a locally Lipschitz operator $B$ which fulfils the same properties as $A$.

Lemma 2.2 ([Reference Bartsch, Liu and Weth5, Lemma 2.1], [Reference Bartsch and Liu4, Lemma 4.1]) Assume either $(J_1)$ or $(J_2)$. Let $D$ be a closed convex subset of $X$. Then, there exists a locally Lipschitz continuous compact operator $B: X \to X$ which is a convex combination of $A$ such that

  1. $(i)$ $A(u)=B(u)$ for each $u\in D$;

  2. $(ii)$

    \[ \frac12 \|u-B(u)\| \leq \|u-A(u)\| \leq 2 \|u-B(u)\| \]
    for all $u \in X$;
  3. $(iii)$ if $1< p< 2$ then

    \[ \langle J^{\prime}(u), u- B(u) \rangle \geq \frac{d_1}{2}\|u- A(u)\|^2 (\|u\| + \|A(u)\|)^{p-2}, \]
    and if $p\geq 2$ then
    \[ \langle J^{\prime}(u), u- B(u) \rangle \geq \frac{d_1}{2}\|u- A(u)\|^p \]
    for all $u \in X$.

Clearly, critical points of $J$ turn out to be fixed points of $B$.

In our setting $X=W^{1,p}_0(\Omega )$ endowed with the equivalent norm

\[ \|u\|_{\mu} := \left(\int_{\Omega}(|\nabla u|^p + \mu |u|^p )\,{\rm d}x\right)^{1/p}, \]

for $\mu >0$. For fixed $w\in C^{1}_0(\overline \Omega )$, put $A=A_w^{\mu }:W^{1,p}_0(\Omega ) \longrightarrow W^{1,p}_0(\Omega )$ the operator defined by

\[ A_w^{\mu}(u):= (-\Delta_p+ \mu h_p({\cdot}))^{{-}1}(g(x, u, \nabla w)+ \mu h_p(u)), \]

where $h_p(t)=|t|^{p-2}t$ for each $t\in {\mathbb {R}}$.

Let us note that

\[ A_w^{\mu}|_{C^1_0(\overline \Omega)}: C^1_0(\overline \Omega) \longrightarrow C^1_0(\overline \Omega). \]

Since problem $(\tilde P_w)$ has variational form, we can consider the associated energy functional $J_w\in C^1(W^{1,p}_0(\Omega ))$, defined by

\[ J_w(u) = \frac1p \int_{\Omega}|\nabla u|^p\,{\rm d}x - \int_{\Omega} G(x, u, \nabla w)\,{\rm d}x,\ \text{for}\ u \in W^{1,p}_0(\Omega), \]

where $G(x, t, \xi ) = \int _0^t g(x, s, \xi )\,{\rm d}s$. Because of $(\mathcal {H})$, $J_w$ is coercive, thus bounded from below.

The following inequalities (see [Reference Damascelli10]) ensure properties $(J_1)$ and $(J_2)$ above:

Proposition 2.2 There exist positive constants $c_i$, $i=1, \ldots, 4$, such that for all $\xi, \eta \in \mathbb {R}^N$

\begin{align*} & ||\xi|^{p-2} \xi - |\eta|^{p-2} \eta | \leq c_1 (|\xi| + |\eta|)^{p-2} |\xi-\eta|,\\ & (|\xi|^{p-2} \xi - |\eta|^{p-2} \eta ) \cdot (\xi - \eta) \geq c_2 (|\xi| + |\eta|)^{p-2} |\xi-\eta|^2,\\ & ||\xi|^{p-2} \xi - |\eta|^{p-2} \eta | \leq c_3 |\xi-\eta|^{p-1} \ \ \text{if}\ 1< p\leq 2,\\ & (|\xi|^{p-2} \xi - |\eta|^{p-2} \eta ) \cdot (\xi - \eta) \geq c_4 |\xi-\eta|^p \ \text{if}\ p>2. \end{align*}

Thus, lemma 2.2 applies. We will exploit it in the next sections with different choices of $D$, $\mu$ and $g$.

3. Nodal solution for a quasilinear elliptic problem

In this section we assume conditions $(f_1)-(f_4)$ and prove theorem 1.1. Using the theory of invariant sets of descending flow, we will construct first a nodal solution of a parametrized problem and then, following an iterative approach, we will exhibit the existence of a nodal solution for $(P)$.

3.1. On a parametrized problem

Throughout the sequel we will take into account the results of Section 2 with $g=f$. Thus, for every $w\in C^1_0(\overline \Omega )$, the parametrized Dirichlet problem reads as follows

(P w)\begin{equation} \left\{ \begin{array}{@{}ll@{}} -\Delta_p u= f(x,u, \nabla w) & {\rm in}\ \Omega \\ u=0 & {\rm on}\ \partial\Omega. \end{array}\right. \end{equation}

Recall that each solution $u$ of $(P_w)$ is in $C^1_0(\overline \Omega )$. Also, assumptions $(f_2)$ and $(f_3)$ imply that $f(x,0,\xi )=0$ for all $x,\xi$, thus the zero function is a solution of $(P)$ and $(P_w)$ for each $w\in C^1_0(\overline \Omega )$.

In [Reference Faraci, Motreanu and Puglisi13], we have proved the following

Lemma 3.1 ([Reference Faraci, Motreanu and Puglisi13, Lemma 2.2]) Assume $(f_2)$. Then, for every $M>0$ and $w \in C^1_0(\overline \Omega )$ with $\|w\|_{C^1} \leq M$, there exists $\delta =\delta (M)>0$ such that if $0<\varepsilon <\delta$, then $\varepsilon \varphi _1$ and $-\varepsilon \varphi _1$ are subsolution and supersolution of $(P_w)$.

Theorem 3.1 ([Reference Faraci, Motreanu and Puglisi13, Theorem 2.1]) Assume $(f_1), (f_2), (f_3)$. Then, for every $w \in C^1_0(\overline \Omega )$, there exist $u_P^w \in \mathrm {int}(C^1_0(\overline \Omega )_+)$ and $u_N^w \in - \mathrm {int}(C^1_0(\overline \Omega )_+)$ the smallest positive solution and the biggest negative solution of $(P_w)$ respectively.

From the proof of [Reference Faraci, Motreanu and Puglisi13, Theorem 2.1] we deduce that

Remark 3.1 $u_P^w \geq \varepsilon \varphi _1$ and $u_N^w \leq -\varepsilon \varphi _1$ with $\varepsilon =\varepsilon (M)$ uniform with respect to $w\in C^1_0(\overline \Omega )$ with $\|w\|_{C^1} \leq M$.

We conclude this subsection recalling the strong comparison principle for the $p$-Laplace operator ([Reference Arcoya and Ruiz2]). For $h_1, h_2 \in L^\infty (\Omega )$, we say that $h_1 \prec h_2$ if for any $\Omega _0 \subseteq \Omega$ compact subset, there exists $\varepsilon >0$ such that $h_1(x) + \varepsilon < h_2(x)$ for almost every $x \in \Omega _0$. In particular, if $h_1$ and $h_2$ are continuous functions such that $h_1(x)< h_2(x)$ for all $x\in \Omega$, then $h_1 \prec h_2$.

Proposition 3.1 [Reference Arcoya and Ruiz2, Proposition 2.6] For $\lambda \geq 0$ and $f, g \in L^\infty (\Omega )$, let $v, u$ be solutions of the problems$:$

\begin{align*} & \left\{ \begin{array}{@{}ll@{}} -\Delta_p v+ \lambda |v|^{p-2} v= f & {\rm in}\ \Omega \\ u=0 & {\rm on}\ \partial\Omega, \end{array}\right. \\ & \left\{ \begin{array}{@{}ll@{}} -\Delta_p u+ \lambda |u|^{p-2} u= g & {\rm in}\ \Omega \\ u=0 & {\rm on}\ \partial\Omega, \end{array}\right. \end{align*}

If $f \prec g$ and $u \in \mathrm {int}(C^1_0(\overline \Omega )_+)$, then $u-v\in \mathrm {int}(C^1_0(\overline \Omega )_+)$.

3.2. A pseudogradient vector field

Throughout the sequel, $u_0\in C^1_0(\overline \Omega )$ is a fixed function, $M>0$ is given by proposition 2.1 and we choose $m=m_M$ in assumption $(f_4)$. Thus, following the notation of Section 2 with $g=f$ and $\mu =m$ one has

\begin{align*} \|u\|_{m} & := \left(\int_{\Omega}(|\nabla u|^p + m |u|^p )\,{\rm d}x\right)^{1/p},\\ A_w(u)& := (-\Delta_p+ m h_p({\cdot}))^{{-}1}(f(x, u, \nabla w)+ m h_p(u)),\\ J_w(u) & = \frac1p \int_{\Omega}|\nabla u|^p\,{\rm d}x - \int_{\Omega} F(x, u, \nabla w)\,{\rm d}x, \end{align*}

where $F(x, t, \xi ) = \int _0^t f(x, s, \xi )\,{\rm d}s$.

Let us introduce the set $\Lambda ^w$ which will be crucial in our argument. Let $u_P^w \in \mathrm {int}(C^1_0(\overline \Omega )_+)$ and $u_N^w \in - \mathrm {int}(C^1_0(\overline \Omega )_+)$ the smallest positive solution and the biggest negative solution of $(P_w)$ (see theorem 3.1). Let us denote by $[u_N^w, u_P^w]$ the set of all $C^1_0$-functions $u$ such that $u_N^w \leq u \leq u_P^w$.

Consider then, the following set

\[ \Lambda^w=\{ u \in C^1_0(\overline\Omega) : \ u \in \text{int}_{C^1_0} [u_N^w, u_P^w]\}. \]

Proposition 3.2

\[ A_w(\Lambda^w) \subseteq \Lambda^w \quad \text{and} \quad A_w(\mathrm{int}(C^1_0(\overline\Omega)_+)) \subseteq \mathrm{int}(C^1_0(\overline\Omega)_+). \]

Proof. First, we show that $A_w(\Lambda ^w) \subseteq \Lambda ^w$. Let $u \in \Lambda ^w$ and $v=A_w(u)$:

\begin{align*} -\Delta_p v + m h_p(v) & = f(x, u, \nabla w) + m h_p(u)\\ (\text{by}\ (f_4)\ \text{and continuity of}\ f)\ & \prec f(x, u_P^w, \nabla w) + m h_p( u_P^w)\\ & ={-}\Delta_p u_P^w + m h_p( u_P^w). \end{align*}

By proposition 3.1, we conclude that $u_P^w-v \in \mathrm {int}(C^1_0(\overline \Omega )_+)$. Analogously one obtains that $v- u_N^w \in \mathrm {int}(C^1_0(\overline \Omega )_+)$. For the other inclusion, let $u \in \mathrm {int}(C^1_0(\overline \Omega )_+)$ and $v=A_w(u)$. Thus,

\[ -\Delta_p v + m h_p(v) = f(x, u, \nabla w) + m h_p(u) >0 \]

By the strong maximum principle [Reference Vázquez23], we conclude that $v \in \mathrm {int}(C^1_0(\overline \Omega )_+)$.

Let $B=B_w$ be as in lemma 2.2 with $D=\Lambda _w$. Thus, since $B_w$ is a convex combination of $A_w$, one has

(3.1)\begin{equation} B_w(\Lambda^w) \subseteq \Lambda^w \quad \text{and} \quad B_w(\mathrm{int}(C^1_0(\overline\Omega)_+)) \subseteq \mathrm{int}(C^1_0(\overline\Omega)_+). \end{equation}

For every $u \in C^1_0(\overline \Omega ) \setminus K_w$ (where $K_w$ is the set of all fixed points of $A_w$) consider the following Cauchy problem

(3.2)\begin{equation} \left\{\begin{array}{@{}ll@{}} \displaystyle{\dfrac{{\rm d}}{{\rm d}t} \varphi(t) ={-}\varphi(t) + B_w(\varphi(t))}\\ \varphi(0) = u. \end{array}\right. \end{equation}

Since $B_w$ is locally Lipschitz, the above problem admits a unique solution $\varphi ^t(u)$ in $C^1_0(\overline \Omega )$ called descending flow curve with maximal interval of existence $[0, \tau (u)[$. Notice that $\tau (u)$ can be either a positive number or $+\infty$.

By lemma 2.2 $(iii)$,

\begin{align*} \frac{{\rm d}}{{\rm d}t} J_w(\varphi^t(u)) & = \langle J_w^\prime(\varphi^t(u)), \frac{{\rm d}}{{\rm d}t}\varphi^t(u)\rangle\\ & ={-} \langle J_w^\prime(\varphi^t(u)), \varphi^t(u) - B_w(\varphi^t(u)\rangle\\ & <0 \end{align*}

and the inequality is strict since $u \notin K_w$ so that it is not a fixed point of $B_w$. Thus, $J_w(\varphi ^t(u))$ is strictly decreasing. Recall also that $J_w$ is coercive, hence bounded from below.

Moreover from (3.2), we have

\[ \int_0^t e^s \frac{{\rm d}}{{\rm d}s} \varphi^s(u)\,{\rm d}s ={-}\int_0^t e^s\varphi^s(u)\,{\rm d}s+ \int_0^t e^sB_w(\varphi^s(u)) \,{\rm d}s, \]

or

(3.3)\begin{equation} \varphi^t(u)= e^{{-}t} u+ e^{{-}t}\int_0^t e^sB_w(\varphi^s(u))\,{\rm d}s. \end{equation}

By (3.1), one has the following (see [Reference Liu and Sun19, proof of Lemma 3.2]).

Lemma 3.2 If $u \in \Lambda ^w$, then $\varphi ^t(u) \in \Lambda ^w$ and if $u \in \mathrm {int}(C^1_0(\overline \Omega )_+)$, then $\varphi ^t(u) \in \mathrm {int}(C^1_0(\overline \Omega )_+)$ for all $0< t<\tau (u)$.

For $D \subseteq C^1_0(\overline \Omega )$, let us denote by

\[ \mathcal{C}(D) = D\cup \{u \in C^1_0(\overline\Omega)\setminus K_w: \ \text{there exists}\ \bar t \geq 0\ \text{such that}\ \varphi^{\bar t}(u) \in D\}. \]

We recall that $D$ is called an invariant set of descending flow for $J_w$, if whenever $u\in D\setminus K_w$, the flow $\{\varphi ^t(u):t\in [0,\tau (u)[\}\subset D$. If $D=\mathcal {C}(D)$, then $D$ is said complete.

If $D$ is invariant then, by the definition above, $\mathcal {C}(D)$ is invariant. Moreover it is easy to see that $\mathcal {C}(D)$ is complete as $\mathcal {C}(\mathcal {C}(D))=\mathcal {C}(D)$. Then $\partial \mathcal {C}(D)$ is also an invariant set of descending flow [Reference Liu and Sun19, Lemma 2.3]. If $D$ is also open then $\mathcal {C}(D)$ is open [Reference Liu and Sun19, Lemma 2.4(i)].

By lemma 3.2, $\Lambda ^w$ and $\mathrm {int}(C^1_0(\overline \Omega )_+)$ are invariant sets of descending flow for $J_w$, so $\mathcal {C}(\Lambda ^w)$ and $\mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+))$ are invariant, as well as $\partial \mathcal {C}(\Lambda ^w)$ and $\partial \mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+))$. Moreover, $\mathcal {C}(\Lambda ^w)$ is open in $C^1_0(\overline \Omega )$ and $\mathcal {C}(\Lambda ^w) \not = C^1_0(\overline \Omega )$ (indeed $u^w_P, u^w_N \in K_w\setminus \Lambda ^w$, so they cannot lie in $\mathcal {C}(\Lambda ^w)$). Also, $\mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+))$ is open in $C^1_0(\overline \Omega )$ and $\mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+)) \not = C^1_0(\overline \Omega )$ (indeed $0 \in K_w\setminus \mathrm {int}(C^1_0(\overline \Omega )_+)$). Since $C^1_0(\overline {\Omega })_+\subseteq \overline {\mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+))}$ and $\partial \mathcal {C}(\Lambda ^w) \cap C^1_0(\overline {\Omega })_+ \not =\emptyset$, we have $\partial \mathcal {C}(\Lambda ^w) \cap \overline {\mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+))} \not = \emptyset$. Because $\partial \mathcal {C}(\Lambda ^w) \cap (-C^1_0(\overline {\Omega })_+) \not = \emptyset$, we obtain that $\partial \mathcal {C}(\Lambda ^w) \cap \partial \mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+)) \not = \emptyset$. Let us fix

\[ u^* \in \partial \mathcal{C}(\Lambda^w) \cap \partial \mathcal{C}(\mathrm{int}(C^1_0(\overline\Omega)_+)). \]

Lemma 3.3 There exists $u_w \in K_w$ and an increasing sequence of positive numbers $(t_n)_n$ with $t_n \rightarrow \tau (u^*)$ such that $\lim _n \|\varphi ^{t_n}(u^*) -u_w\|_m=0$.

Proof. Let $0< t_1< t_2<\tau (u^*)$. Then,

\begin{align*} \|\varphi^{t_2}(u^*)-\varphi^{t_1}(u^*)\|_m& \leq \int_{t_1}^{t_2} \| \frac{{\rm d}}{{\rm d}t}\varphi^t(u^*)\|_m\,{\rm d}t \\ & =\int_{t_1}^{t_2}\|\varphi^t(u^*)-B_w(\varphi^t(u^*))\|_m\\ \text{(by lemma 2.2}, (ii)) & \leq 2\int_{t_1}^{t_2}\|\varphi^t(u^*)-A_w(\varphi^t(u^*))\|_m. \end{align*}

Assume that $p\geq 2$.

Applying Hölder inequality, lemma 2.2 $\it {(iii)}$, the monotonicity of the flow $t\to J_w(\varphi ^{t}(u^*))$ and the boundedness from below of $J_w$, we obtain

\begin{align*} \int_{t_1}^{t_2}\|\varphi^t(u^*)-A_w(\varphi^t(u^*))\|_m& \leq \left(\int_{t_1}^{t_2}\|\varphi^t(u^*)-A_w(\varphi^t(u^*))\|^p_m\right)^{1/p} (t_2-t_1)^{1/{p'}} \\ & \leq c_1 \left(\int_{t_1}^{t_2}\frac{{\rm d}}{{\rm d}t} J_w(\varphi^t(u^*))\,{\rm d}t\right)^{1/p} \ (t_2-t_1)^{1/{p'}} \\ & =c_1(J_w(\varphi^{t_2}(u^*))-J_w(\varphi^{t_1}(u^*)))^{1/p} \ (t_2-t_1)^{1/{p'}} \\ & \leq c_2(t_2-t_1)^{1/{p'}}. \end{align*}

Putting together the above outcomes we get that

\[ \|\varphi^{t_2}(u^*)-\varphi^{t_1}(u^*)\|_m \leq c (t_2-t_1)^{1/{p'}}. \]

Assume now $1< p< 2$. By coercivity of $J_w$, we deduce that the set $\{u: J_w(u)\leq J_w(\varphi ^0(u^*))=J_w(u^*)\}\subset \overline B(0,b)$ for some $b>0$ where $\overline B(0,b)$ denotes the closed ball in $W^{1,p}_0(\Omega )$ centred at zero of radius $b$. By the monotonicity of the flow, $J_w(\varphi ^t(u^*)\leq J_w(u^*)$, thus there exists a constant $b_1>0$, such that $\|\varphi ^t(u^*)\|_m, \|A_w(\varphi ^t(u^*))\|_m\leq b_1$ for each $t$.

Then, by Hölder inequality, lemma 2.2 $(iii)$

\begin{align*} \int_{t_1}^{t_2}\|\varphi^t(u^*)-A_w(\varphi^t(u^*))\|_m& \leq \left(\int_{t_1}^{t_2}\|\varphi^t(u^*)-A_w(\varphi^t(u^*))\|^2_m (\|\varphi^t(u^*)\|_m\right.\nonumber\\ & \quad + \left.\|A_w(\varphi^t(u^*))\|_m)^{p-2}\,{\rm d}t\right)^{1/2} \\ & \quad \cdot\left(\int_{t_1}^{t_2}(\|\varphi^t(u^*)\|_m + \|A_w(\varphi^t(u^*))\|_m)^{2-p}\,{\rm d}t\right)^{1/2}\\ & \leq c_1 \left(\int_{t_1}^{t_2}\frac{{\rm d}}{{\rm d}t} J_w(\varphi^t(u^*))\right)^{1/2} (t_2-t_1)^{1/2} \\ & =c_1(J_w(\varphi^{t_2}(u^*))-J_w(\varphi^{t_1}(u^*)))^{1/2} (t_2-t_1)^{1/2} \\ & \leq c_2(t_2-t_1)^{1/2}. \end{align*}

Thus, in both cases ($p\geq 2$ and $1< p<2$), if $\tau (u^*)<\infty$, there exists $u_w\in W^{1,p}_0(\Omega )$ such that

\[ \lim_{t\to \tau(u^*)}\|\varphi^{t}(u^*)-u_w\|_m=0. \]

Since the interval $[0,\tau (u^*)[$ is maximal it has to be $u_w\in K_w$.

If $\tau (u^*)=\infty$, the boundedness from below of $J_w$ allows us to fix an increasing sequence of positive numbers $(t_n)_n$, $t_n\to \infty$ such that

\[ \lim_n \frac{{\rm d}}{{\rm d}t} J_w(\varphi^t(u^*))|_{t=t_n}=0. \]

If $p\geq 2$, one has

\begin{align*} \frac{{\rm d}}{{\rm d}t} J_w(\varphi^t(u^*))|_{t=t_n}& ={-}\langle J_w'(\varphi^{t_n}(u^*)),\varphi^{t_n}(u^*)-B_w(\varphi^{t_n}(u^*)) \rangle\\ (\text{by lemma 2.2}, \ (iii))& \leq{-}c_1\|\varphi^{t_n}(u^*)-A_w(\varphi^{t_n}(u^*))\|_m^p, \end{align*}

which says that

\[ \lim_n \|\varphi^{t_n}(u^*)-A_w(\varphi^{t_n}(u^*))\|_m=0. \]

Now, let us observe that $(\varphi ^{t_n}(u^*))_n$ is bounded in $W^{1,p}_0(\Omega )$. Indeed, by the monotonicity of the flow, $J_w(\varphi ^{t_n}(u^*)\leq J_w(u^*)$ for every $n\in \mathbb {N}$, that means that $\varphi ^{t_n}(u^*)\in J_w^{-1}(]-\infty, J_w(u^*)])$ for every $n\in \mathbb {N}$, and the latter is a bounded set because of the coercivity of $J_w$. Moreover, since $A_w$ is a compact operator, it follows (eventually passing to a subsequence) that there exists $u_w\in W^{1,p}_0(\Omega )$ such that

\[ \lim_n \|\varphi^{t_n}(u^*)-u_w\|_m=\lim_n \|A_w(\varphi^{t_n}(u^*))-u_w\|_m=0. \]

In particular, $u_w\in K_w$. Also, for some $b_2>0$, one has $\|\varphi ^{t_n}(u^*)\|_m,\|A_w(\varphi ^{t_n}(u^*))\|_m \leq b_2$.

If $1< p<2$,

\begin{align*} \frac{{\rm d}}{{\rm d}t} J_w(\varphi^t(u^*))|_{t=t_n}& ={-}\langle J_w'(\varphi^{t_n}(u^*)),\varphi^{t_n}(u^*)-B_w(\varphi^{t_n} (u^*)) \rangle\\ (\text{by lemma 2.2}, (iii))& \leq{-}c_1\|\varphi^{t_n}(u^*)-A_w(\varphi^{t_n}(u^*))\|_m^2 (\|\varphi^{t_n}(u^*)\|_m\\ & \quad +\|A_w(\varphi^{t_n}(u^*))\|_m)^{p-2}\\ & \leq{-}c_2\|\varphi^{t_n}(u^*)-A_w(\varphi^{t_n}(u^*))\|_m^2 \end{align*}

which says that

\[ \lim_n \|\varphi^{t_n}(u^*)-A_(\varphi^{t_n}(u^*))\|_m=0 \]

and we conclude as above.

In the next lemma we refine the previous result.

Lemma 3.4 With the notation of lemma 3.3, one has that $u_w\in C^1_0(\overline \Omega )$ and $\lim _n \|\varphi ^{t_n}(u^*) -u_w\|_{C^1_0}=0$.

Proof. As in the proof of lemma 3.3, we first observe that the set $\{\varphi ^t(u^*) \ : \ t\in [0,\tau (u^*)[\}$ is bounded in $W^{1,p}_0(\Omega )$. Recalling (3.3),

\[ \varphi^t(u^*)= e^{{-}t} u^*+ e^{{-}t}\int_0^t e^sB_w(\varphi^s(u^*))\,{\rm d}s. \]

Since $B_w: C^{1}_0(\overline {\Omega }) \to C^{1}_0(\overline {\Omega })$ is a compact operator, the set

\[ \left\{e^{{-}t}\int_0^t e^sB_w(\varphi^s(u^*))\,{\rm d}s \ : \ t\in [0,\tau(u^*)[\right\} \]

is bounded in $C^{1,\alpha }(\overline {\Omega })$, thus relatively compact in $C^1_0(\overline \Omega )$. This clearly implies that $\{\varphi ^t(u^*) \ : \ t\in [0,\tau (u^*)[\}$ is relatively compact in $C^1_0(\overline \Omega )$. The thesis follows from lemma 3.3.

We are ready to prove the main result of this subsection.

Theorem 3.2 $u_w$ is a nodal solution of $(P_w)$.

Proof. Clearly $u_w$ is a solution of $(P_w)$ since it belongs to $K_w$. Since the initial point $u^*$ belongs to $\partial \mathcal {C}(\Lambda ^w)\cap \partial \mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+))$, and both sets $\partial \mathcal {C}(\Lambda ^w)$, $\partial \mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+))$ are invariant sets of descending flow, then $(\varphi ^{t_n}(u^*))_n \subseteq \partial \mathcal {C}(\Lambda ^w) \cap \partial \mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+))$. Moreover, $\partial \mathcal {C}(\Lambda ^w) \cap \partial \mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+))$ is a closed set, so that $u_w \in \partial \mathcal {C}(\Lambda ^w) \cap \partial \mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+))$. Being $u_w \in \partial \mathcal {C}(\Lambda ^w)$, we obtain that $u_w \not \in \text {int}_{C^1_0} [u_N^w, u_P^w]$, in particular $u_w \not = 0$. Actually, by remark 3.1, $u_w\not \in \text {int}_{C^1_0} [-\varepsilon \varphi _1, \varepsilon \varphi _1]$. On the other hand, since $u_w \in \partial \mathcal {C}(\mathrm {int}(C^1_0(\overline \Omega )_+))$, we also have $u_w \not \in \mathrm {int}(C^1_0(\overline \Omega )_+) \cup (-\mathrm {int}(C^1_0(\overline \Omega )_+))$. This ensures that $u_w$ can not have constant sign. Indeed, if $u_w\geq 0$, it would be a non negative, non trivial solution of

\[ \left\{ \begin{array}{@{}ll@{}} -\Delta_p u+mh_p(u)= f(x,u, \nabla w) +mh_p(u) & \text{in}\ \Omega \\ u=0 & {\rm on}\ \partial\Omega. \end{array}\right. \]

and by assumption $(f_4)$ and the strong maximum principle by Vazquez [Reference Vázquez23], we would deduce $u_w\in \mathrm {int}(C^1_0(\overline \Omega )_+)$. Thus, $u_w$ is a nodal solution of $(P_w)$.

3.3. Existence of a nodal solution for $(P)$

In this subsection through an iteration procedure we prove our first main result.

Proof of theorem 1.1. In theorem 3.2 choose $w=u_0$, where $u_0$ is the function we fixed at the beginning of Section 3.2. Thus, the existence of a nodal solution $u_1$ of $(P_{u_0})$ follows. Proceeding in such way, for each $n\in \mathbb {N}$ denote by $u_n$ the nodal solution of $(P_{u_{n-1}})$ given by theorem 3.2. Hence, we construct a sequence of functions $u_n\in C^1_0(\overline \Omega )$ such that

(3.4)\begin{gather} u_n\not\in \text{int}_{C^1_0} [-\varepsilon\varphi_1, \varepsilon \varphi_1] \end{gather}
(3.5)\begin{gather} u_n \not \in\mathrm{int}(C^1_0(\overline\Omega)_+) \cup (-\mathrm{int}(C^1_0(\overline\Omega)_+)) \end{gather}

By proposition 2.1, $\|u_n\|_{C^{1, \alpha }(\overline {\Omega })} \leq M$, and by the compactness of the embedding ${C^{1, \alpha }}(\overline {\Omega })\hookrightarrow C^1_0(\overline \Omega )$, $(u_n)_n$ is relatively compact in $C^1_0(\overline \Omega )$. Unless to pass to a subsequence, let

\[ \tilde u:=\lim_{n \rightarrow \infty} u_n \ \text{in}\ C^1_0(\overline \Omega). \]

Let us prove that $\tilde u$ is the solution of $(P)$ we are looking for. Since $u_n$ is a solution of $(P_{u_{n-1}})$, for every $\varphi \in W^{1,p}_0({\Omega })$ we have

\[ \int_{\Omega} |\nabla u_n|^{p-2}\nabla u_n \nabla \varphi\,{\rm d}x= \int_{\Omega }f(x, u_n, \nabla u_{n-1})\varphi\,{\rm d}x. \]

Since $u_n\to \tilde u$ in $C^1_0(\overline \Omega )$, we have that $f(x, u_n, \nabla u_{n-1})\rightarrow f(x, \tilde u, \nabla \tilde u)$ in $L^{p'}(\Omega )$ and passing to the limit in the above equality we get

\[ \int_{\Omega} |\nabla \tilde u|^{p-2}\nabla \tilde u \nabla \varphi\, {\rm d}x=\int_{\Omega }f(x, \tilde u, \nabla \tilde u)\varphi\,{\rm d}x, \]

which is our claim. By (3.4) and (3.5), it follows that $\tilde u\not \in \text {int}_{C^1_0} [-\varepsilon \varphi _1, \varepsilon \varphi _1]$ and $\tilde u \not \in \mathrm {int}(C^1_0(\overline \Omega )_+) \cup (-\mathrm {int}(C^1_0(\overline \Omega )_+))$. Thus, $\tilde u \not = 0$, and as in the proof of theorem 3.2, $\tilde u$ can not have constant sign.

4. Nodal solution for a quasilinear eigenvalue problem

The goal of the present section is to prove the existence of a nodal solution for $(P_\lambda )$ under assumptions $(\tilde f_1) - (\tilde f_5)$. While in theorem 1.1 the construction of the nodal solution was based on the existence of the extremal solutions for the parametrized problem $(P_w)$, here, exploiting the dependence on the parameter $\lambda$, we apply an abstract theorem by [Reference Bartsch, Liu and Weth5], which still relies on the theory of invariant sets of descending flow. After deducing the existence of a sign changing solution for the parametrized problem, we conclude as in the previous section.

4.1. On a parametrized problem

Throughout the sequel we will take into account the results of Section 2 with $g=\lambda f$ and $\mu = \lambda m$ for some $m$ to be chosen later. For every $w\in C^1_0(\overline \Omega )$, let us consider the parametrized Dirichlet problem

(P λ, w)\begin{equation} \left\{ \begin{array}{@{}ll@{}} -\Delta_p u= \lambda f(x,u, \nabla w) & {\rm in}\ \Omega \\ u=0 & {\rm on}\ \partial\Omega. \end{array}\right. \end{equation}

From hypothesis $(\tilde f_1)$, it follows that for each $\lambda >0$ we can fix $\varepsilon =\varepsilon (\lambda )>0$ with $\varepsilon (1+\lambda _1^{\frac {1}{p'}})\lambda <\lambda _1$ and $k_0(\lambda ) \in \mathbb {R}$ such that

\[ \lambda|f(x,s,\xi)|\leq k_0(\lambda)+\varepsilon \lambda|s|^{p-1}+\varepsilon \lambda|\xi|^{p-1} \]

for all $x\in \Omega$, $s\in \mathbb {R}$, and $\xi \in \mathbb {R}^N$. This ensures that under the above conditions, the function $g=\lambda f$ fulfils assumption $(\mathcal {H})$ of Section 2 and proposition 2.1 applies, i.e. for every $\lambda >0$ and $u_0\in C^1_0(\overline \Omega )$, there exists $\alpha \in ]0,1[$ and a positive constant $M$ depending on $\lambda$ and $\|u_0\|$ such that if $u_n$ is a solution of $(P_{\lambda, u_{n-1}})$, $\|u_n\|_{C^{1,\alpha }(\overline \Omega )}\leq M$.

Remark 4.1 Notice that assumption $(\tilde f_2)$ implies that $f(x,0,\xi )=0$ for all $x,\xi$. Thus the zero function is a solution of both $(P_{\lambda, w})$ and $(P_\lambda )$.

We will need the following abstract result.

Let $X$ be a Banach space, ${D}^\pm$ closed convex subsets of $X$, $A:X \longrightarrow X$ continuous and compact operator and $J:X\to \mathbb {R}$ a functional of class ${C}^1(X, \mathbb {R})$. Introduce the following conditions.

  1. $(D_1)$ $\mathcal {O}=$int$({D}^+) \cap \text {int}({D}^-) \not =\emptyset$.

  2. $(D_2)$ $A({D}^\pm )\subseteq \hbox {int}({D}^\pm )$.

  3. $(J_3)$ For any $b \in \mathbb {R}$ there exists a constant $a=a(b)>0$ such that if $u \in \{u \in X: J(u) \leq b\}$ then

    \[ \|u\| + \|A(u)\| \leq a (1+ \|u-A(u)\|). \]
  4. $(J_4)$ There exists a path $h:[0,1]\longrightarrow X$ such that $h(0) \in \text {int}({D}^+)\setminus {D}^-$ and $h(1) \in \text {int}({D}^-)\setminus {D}^+$ and

    \[ \max_{0\leq t\leq1} J(h(t)) < \alpha_0:=\inf_{{D}^+{\cap} {D}^-}J(u). \]

The next theorem is the abstract tool we will exploit to deduce the existence of a nodal solution for the parametrized problem $(P_{\lambda, w})$, which we state here in a convenient form for our purposes.

Theorem 4.1 [Reference Bartsch, Liu and Weth5, Theorem 2.2] Assume $(D_1)$, $(D_2)$, $(J_3)$, $(J_4)$ and either $(J_1)$ or $(J_2)$ from Section 2. Then $J$ has a critical point in $\partial \mathcal {C}(\mathcal {O}) \setminus ({D}^+ \cup {D}^-)$.

Following the notation of Section 2, $X=W^{1,p}_0(\Omega )$ endowed with the equivalent norm

\[ \|u\|_m^\lambda := \left(\int_{\Omega}(|\nabla u|^p + \lambda m |u|^p )\,{\rm d}x\right)^{1/p}, \]

where $\lambda$ and $m$ will be chosen later in a convenient way,

\[ A_w^\lambda(u):= (-\Delta_p+ \lambda m h_p({\cdot}))^{{-}1}(\lambda f(x, u, \nabla w)+ \lambda m h_p(u)), \]

and $B_w^\lambda$ as in lemma 2.2. Denote also by $J_w^\lambda : W^{1,p}_0(\Omega ) \longrightarrow {\mathbb {R}}$

\[ J_w^\lambda(u) = \frac1p \int_{\Omega}|\nabla u|^p\,{\rm d}x - \lambda\int_{\Omega} F(x, u, \nabla w)\,{\rm d}x, \]
\[ P=\{u\in W^{1,p}_0(\Omega): u\geq 0 \ \text{a.e. in} \ \Omega\} \]

and for $\varepsilon >0$

\[ D_\varepsilon^{{\pm}}=\{u \in W^{1,p}_0(\Omega): {\rm dist}_m(u,\pm P)\leq \varepsilon\}. \]

Proposition 4.1 For $\varepsilon >0$ small enough,

\[ A_w^\lambda(D_\varepsilon^{{\pm}}) \subseteq {\rm int} D_\varepsilon^{{\pm}}. \]

Proof. Let us prove $A_w^\lambda (D_\varepsilon ^+) \subseteq {\rm int} D_\varepsilon ^+$. Notice that by assumptions $(\tilde f_2)-(\tilde f_4)$, for any $M\geq \|w\|_{C^1}$ there exists $m_M>0$ such that

(4.1)\begin{equation} s f(x,s,\xi)+m_M s h_p(s)>0 \ \text{for each}\ x\in\Omega, s\neq0, |\xi|\leq M. \end{equation}

In the sequel put $m:=m_M$.

By $(\tilde f_2)$ and $(\tilde f_3)$, for each $\varepsilon >0$ and $q>p$ there exists another constant $c_M>0$ such that

(4.2)\begin{equation} |f(x,s,\xi)+m h_p(s)|\leq (\varepsilon +m)|s|^{p-1}+c_M|s|^{q-1},\end{equation}

for each $x\in \Omega, s\neq 0, |\xi |\leq M$.

Let $u \in D_\varepsilon ^+$ and $v=A_w^\lambda (u)$. Thus,

\[ -\Delta_p v + \lambda m h_p(v) = \lambda f(x, u, \nabla w) + \lambda m h_p(u) \]

and so testing the above equation with $-v^-$, where $v^-=\max \{-v, \ 0\}$, we deduce

\begin{align*} \|v^-\|_m^p& =\lambda \int_\Omega (f(x,u,\nabla w)+m h_p(u))(- v^-)\\ \text{[by (4.1), (4.2)]} \ & \leq \lambda(\varepsilon+m)\int_\Omega (u^{-})^{p-1}v^-{+}\lambda c_M\int_\Omega (u^{-})^{q-1} v^-\\ & \leq \lambda(\varepsilon+m)\|u^-\|_p^{p-1}\|v^-\|_p+\lambda c_M \|u^-\|_q^{q-1}\|v^-\|_q\\ & \leq \frac{\lambda(\varepsilon+m)}{(\lambda_1 + \lambda m)^{1/p}}\|u^-\|_p^{p-1}\|v^-\|_m+ \frac{\lambda c_M}{(\lambda_1 + \lambda m)^{1/p}} \|u^-\|_q^{q-1}\|v^-\|_m. \end{align*}

Hence,

\[ d_m(v, P)^{p-1} \leq \|v^-\|_m^{p-1} \leq \frac{\lambda(\varepsilon+m)}{(\lambda_1 + \lambda m)^{1/p}}\|u^-\|_p^{p-1}+ \frac{\lambda c_M}{(\lambda_1 + \lambda m)^{1/p}} \|u^-\|_q^{q-1}. \]

Since $\|u^-\|_p \leq \|u-w\|_p$ for all $w \in P$, we get

\begin{align*} d_m(v, P)^{p-1} & \leq \frac{\lambda(\varepsilon+m)}{(\lambda_1 + \lambda m)^{1/p}} \|u-w\|_p^{p-1}+ \frac{\lambda c_M}{(\lambda_1 + \lambda m)^{1/p}} \|u-w\|_p^{q-1} \\ & \leq \frac{\lambda(\varepsilon+m)}{(\lambda_1 + \lambda m)} \|u-w\|_m^{p-1}+ \frac{\lambda c_M}{(\lambda_1 + \lambda m)^{\frac{q}{p}}} \|u-w\|_m^{q-1}. \end{align*}

Thus,

\[ d_m(v, P)^{p-1} \leq \frac{\lambda(\varepsilon+m)}{(\lambda_1 + \lambda m)} d_m(u,P)^{p-1}+ \frac{\lambda c_M}{(\lambda_1 + \lambda m)^{\frac{q}{p}}} d_m(u,P)^{q-1}. \]

Thus, since $q>p$, there exists $\varepsilon _0>0$ such that

(4.3)\begin{equation} d_m(v, P) < d_m(u, P) \quad\ \text{if} \ 0< d_m(u, P) \leq \varepsilon_0, \end{equation}

and the proof is concluded.

Remark 4.2 From the above construction, $\varepsilon >0$ depends on $\lambda$ and $M \geq \|w\|_{C^1}$. In the sequel, our choice of $M$ will be uniform with respect to $w$ (see proposition 2.1).

Theorem 4.2 Let $\Omega$ be a smooth bounded domain in $\mathbb {R}^N$ and $f:\Omega \times \mathbb {R} \times \mathbb {R}^N\to \mathbb {R}$ a continuous function satisfying $(\tilde f_1)-(\tilde f_5)$. Then, there exists $\tilde \lambda$ such that for each $\lambda >\tilde \lambda$, and $w\in C^1_0(\overline \Omega )$, problem $(P_{\lambda,w})$ has a nodal solution in $C^1_0(\overline {\Omega })$.

Proof. Fix $w \in C^1_0(\overline \Omega )$. Let us show that all the hypotheses of theorem 4.1 are verified with $A=A_w^\lambda$, $J=J_w^\lambda$, $D^+={D}_\varepsilon ^+$, $D^-={D}_\varepsilon ^-$ and $\lambda$ big enough.

Condition $(D_1)$ is trivial, $(D_2)$ follows by proposition 4.1 and $(J_1)$, $(J_2)$ by proposition 2.2. Moreover, the map $A_w^\lambda$ is compact (see [Reference Faraci, Motreanu and Puglisi13, Lemma 2.3]) and assumption $(J_3)$ is implied by the coercivity of $J_w^\lambda$. It remains to check the validity of condition $(J_4)$. By (4.3), we have that

\[ K \cap ({D}_\varepsilon^+{\cap} {D}_\varepsilon^-)=\{0\}. \]

Since $J_w^\lambda$ is decreasing over the flow and ${D}_\varepsilon ^+ \cap {D}_\varepsilon ^-$ is an invariant set, it follows that for every $u \in {D}_\varepsilon ^+ \cap {D}_\varepsilon ^-$

\[ J_w^\lambda(u) \geq J_w^\lambda(\varphi_t(u)) \geq J_w^\lambda(u^*) \]

where $u^*=\lim _{t \rightarrow \tau (u)} \varphi _t(u) \in K \cap ({D}_\varepsilon ^+ \cap {D}_\varepsilon ^-)=\{0\}$. Therefore

\[ J_w^\lambda(u) \geq J_w^\lambda(0)=0 \quad \text{for every}\ u \in {D}_\varepsilon^+{\cap} {D}_\varepsilon^-. \]

Let us show that there exists $\tilde \lambda$ such that for all $\lambda \geq \tilde \lambda$ $(J_4)$ holds; we follow the construction of [Reference Bartsch and Liu4, Lemma 3.2]. Let

\[ a:=\inf\{x_1: x=(x_1, \ldots, x_N) \in \Omega\} \ \text{and} \ b :=\sup\{x_1: x=(x_1, \ldots, x_N) \in \Omega\}. \]

we consider

\[ \Omega_t:=\{ x \in \Omega: \ (1-t)a + tb < x_1< b\} \ \text{for}\ t \in [0,1]. \]

Thus $\Omega _0=\Omega$ and $\Omega _1=\emptyset$. We define

\[ h^*(t) = s^+ \chi_{\Omega_t} + s^- \chi_{\Omega \setminus \Omega_t}. \]

Let

\[ \delta:=|\Omega| \inf_{(x, \xi) \in \Omega\times \mathbb{R}^N} F(x, s^{{\pm}}, \xi)>0 \]

(see $(\tilde {f}_5)$). We can approximate $h^*$ by a function $h \in C([0,1], W^{1,p}_0(\Omega )\cap C^1(\overline {\Omega )})$ such that

\[ \int_{\Omega} F(x, h(t), \nabla w)\,{\rm d}x \geq \delta/2>0. \]

We choose $\varepsilon >0$ such that $s^- < - \varepsilon <0<\varepsilon < s^+$, so that $h(0) \in \text {int}(\mathcal {D}_{\varepsilon }^+) \setminus \mathcal {D}_{\varepsilon }^-$ and $h(1) \in \text {int}(\mathcal {D}_{\varepsilon }^-) \setminus \mathcal {D}_{\varepsilon }^+$. Finally

\[ J_w^\lambda(h(t) \leq \frac1p \|\nabla h(t)\|_p^p - \frac12 \lambda \delta \leq C - \frac12 \lambda \delta. \]

Choose $\tilde \lambda =2C/\delta$. Notice that $\tilde \lambda$ does not depend on $w$. The existence of a nodal solution for $(P_{\lambda,w})$ follows at once by theorem 4.1.

4.2. Nodal solution of $(P_\lambda )$

In this subsection we prove theorem 1.2 using an iterative procedure.

Proof of theorem 1.2. Let us choose $\lambda > \tilde \lambda$, where $\tilde \lambda$ is as in theorem 4.2. Fix $u_0$ and let $M>0$, depending on $\lambda$ and $u_0$, be as in proposition 2.1. For each $n\in \mathbb {N}^+$ denote by $u_n$ the nodal solution in $C^1_0(\overline \Omega )$ of $(P_{\lambda, u_{n-1}})$ given by theorem 4.2. From its proof,

(4.4)\begin{equation} u_n\in \partial \mathcal{C}(\hbox{int}({D}^+_\varepsilon) \cap \text{int}({D}^+_\varepsilon))\setminus (\text{int}({D}^+_\varepsilon) \cup \hbox{int}({D}^-_\varepsilon)). \end{equation}

Let us stress that $\varepsilon$ depends on $M$ which is independent on $n$ (remark 4.2). Thus the set $\partial \mathcal {C}(\text {int}({D}^+_\varepsilon ) \cap \text {int}({D}^+_\varepsilon ))\setminus (\text {int}({D}^+_\varepsilon ) \cup \text {int}({D}^-_\varepsilon ))$ is a closed invariant set and does not depend on $n$.

By proposition 2.1, $\|u_n\|_{C^{1, \alpha }} \leq M$, and by the compactness of the embedding ${C^{1, \alpha }}(\overline {\Omega })\hookrightarrow C^1_0(\overline \Omega )$, $(u_n)_n$ is relatively compact in $C^1_0(\overline \Omega )$. Unless to pass to a subsequence, let

\[ \tilde u:=\lim_{n \rightarrow \infty} u_n \ \text{in}\ C^1_0(\overline \Omega). \]

As in the proof of theorem 1.1, $\tilde u$ is a solution of $(P_\lambda )$. By the closedness of the set $\partial \mathcal {C}(\text {int}({D}^+_\varepsilon ) \cap \text {int}({D}^+_\varepsilon ))\setminus (\text {int}({D}^+_\varepsilon ) \cup \text {int}({D}^-_\varepsilon ))$, it follows from (4.4) that $\tilde u$ is a sign changing function as we claimed.

5. Examples and open questions

This section is devoted to some examples of applications of our main theorems and a few open questions.

Example 5.1 Let $k_0,\theta _0,\theta _1$ positive numbers with $\theta _0+\theta _1\lambda _1^{1/p'}<\lambda _1$, $g:\overline \Omega \times \mathbb {R}^N\to \mathbb {R}$ a continuous, positive function such that $g(x,\xi )\leq k_0+\theta _1|\xi |^{p-1}$. Define $f: \overline \Omega \times \mathbb {R} \times \mathbb {R}^N\to \mathbb {R}$ such that

\[ f(x,s,\xi)=\left\{\begin{array}{@{}ll@{}} (\lambda_1+ g(x,\xi))|s|^{p-2}s & \text{if}\ |s|\leq 1\\ \left[\lambda_1+ g(x,\xi)) + \theta_0(|s|-1)\right]\dfrac{|s|^{p-2}}{s} & \text{if}\ |s|>1 \end{array} \right. \]

Then, theorem 1.1 applies.

Example 5.2 Let $r, q, t\geq 1$ such that $\max \{ r, q\}< p< t$, $r+q< p+1$, and $g:\overline \Omega \times \mathbb {R}^N\to \mathbb {R}$ a continuous function such that $\inf _{\Omega \times \mathbb {R}^N} g(x, \xi )>0$ and

\[ \lim_{|\xi| \rightarrow +\infty} \frac{g(x, \xi)}{|\xi|^{q-1}}=\ell\not=0. \]

Define $f: \overline \Omega \times \mathbb {R} \times \mathbb {R}^N\to \mathbb {R}$ such that

\[ f(x,s,\xi)=\left\{\begin{array}{@{}ll@{}} |s|^{r-2} s \ g(x,\xi) & \text{if} \ |s|> 1\\ |s|^{t-2} s \ g(x,\xi) & \text{if}\ |s|\leq1 \end{array} \right. \]

Then, theorem 1.2 applies.

Question 5.1 Because of the extremality of $u_N$ and $u_P$ in corollary 1.1, a non trivial solution of $(P)$ in between, would be a nodal solution. It still remains an open question whether this situation occurs. We believe that in order to prove that such solution exists, extra assumptions would be needed. Indeed, in [Reference Dancer and Du11] for $p=2$ it has been proved that, when $f$ does not depend on the gradient, is sublinear, and its derivative at zero is greater than $\lambda _2$ (being $\lambda _2$ the second eigenvalue of the negative Laplacian), the problem admits the biggest negative and the smallest positive solution which turn out to be also minimizers of the energy functional. The existence of a mountain pass critical point in between follows at once. The variational characterization of $\lambda _2$ allows finally to prove that such critical value is non zero (see also [Reference Carl and Perera8] for an extension to $p$-Laplace equations for $p\neq 2$).

Question 5.2 Is it possible to find a positive and a negative solution of $(P_\lambda )$? We underline that, under our assumption, for fixed $w\in C^1_0(\overline \Omega )$ the energy functional $J_{w}^\lambda$ has the mountain pass geometry for big $\lambda$, and a positive /negative solution follows for problem $(P_{\lambda, w})$. It should then be proved that the limit of the approximated sequence is not zero.

Acknowledgements

The authors have been supported by Università degli Studi di Catania, PIACERI 2020-2022, Linea di intervento 2, Progetto ‘MAFANE.’ F. Faraci has been also supported by PRIN 2022BCFHN2 ‘Advanced theoretical aspects in PDEs and their applications’ and she is a member of GNAMPA (INdAM). D. Puglisi is a member of GNSAGA (INdAM).

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