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Well-posedness and the Łojasiewicz-Simon inequality in the asymptotic analysis of a nonlinear heat equation with constraints of finite codimension

Ashish Bawalia, Zdzisław Brzeźniak, Manil T. Mohan, Piotr Rybka

Abstract

We establish the global well-posedness of the $D(A)-$valued strong solution to a nonlinear heat equation with constraints on a \textit{Poincaré domain} $\bO\subset \R^d$ whose boundary is of class $C^2$. Consider the following nonlinear heat equation \begin{align*} \frac{\partial u}{\partial t} - Δu + |u|^{p-2}u = 0, \end{align*} projected onto the tangent space $T_u\bM$, where $\mathcal{M}:=\left\{u\in L^2(\bO):\|u\|_{L^2(\bO)}=1\right\}$ is a submanifold of $L^2(\bO)$. The nonlinearity exponent satisfies $2\le p < \infty$ for $1\leq d\leq 4$ and $2 \le p \le \frac{2d-4}{d-4}$ for $d \ge 5$. The solution is constrained to lie within $\mathcal{M}$ which encodes the norm-preserving constraint. By modifying the nonlinearity and exploiting the abstract theory for \textit{$m-$accretive }evolution equations, we prove the existence of a global strong solution. Using {resolvent-idea } and the \textit{Yosida approximation} method, we derive regularity results. In the asymptotic analysis, $\bO$ is restricted to bounded domains with even $p$ and $1\le d \le 3$. For any initial data in $D(A) \cap \mathcal{M}$, we apply the \textit{Łojasiewicz-Simon gradient inequality} on a Hilbert submanifold [F. Rupp, \textit{J. Funct. Anal.}, 279(8), 2020], to demonstrate that the unique global strong solution converges in $W^{2,q}(\bO) \cap W^{1,q}_0(\bO)$ to a stationary state, where $2 \le q < \frac{2d}{d + 4 - 4β}$ and $1 < β< \frac{3}{2}$. This work proposes an alternative method for establishing the global existence and analyzing long-term behavior of the unique strong solution to an $L^2-$norm preserving nonlinear heat equation.

Well-posedness and the Łojasiewicz-Simon inequality in the asymptotic analysis of a nonlinear heat equation with constraints of finite codimension

Abstract

We establish the global well-posedness of the valued strong solution to a nonlinear heat equation with constraints on a \textit{Poincaré domain} whose boundary is of class . Consider the following nonlinear heat equation \begin{align*} \frac{\partial u}{\partial t} - Δu + |u|^{p-2}u = 0, \end{align*} projected onto the tangent space , where is a submanifold of . The nonlinearity exponent satisfies for and for . The solution is constrained to lie within which encodes the norm-preserving constraint. By modifying the nonlinearity and exploiting the abstract theory for \textit{accretive }evolution equations, we prove the existence of a global strong solution. Using {resolvent-idea } and the \textit{Yosida approximation} method, we derive regularity results. In the asymptotic analysis, is restricted to bounded domains with even and . For any initial data in , we apply the \textit{Łojasiewicz-Simon gradient inequality} on a Hilbert submanifold [F. Rupp, \textit{J. Funct. Anal.}, 279(8), 2020], to demonstrate that the unique global strong solution converges in to a stationary state, where and . This work proposes an alternative method for establishing the global existence and analyzing long-term behavior of the unique strong solution to an norm preserving nonlinear heat equation.
Paper Structure (31 sections, 41 theorems, 335 equations)

This paper contains 31 sections, 41 theorems, 335 equations.

Key Result

Theorem 1.1

Let $D\subset \mathbb{R}^d$ be open set. If $f: D \to \mathbb{R}$ is an analytic function and $\mathrm{a}\in D$ is a critical point of $f$, i.e., $\nabla f(\mathrm{a}) =0$, then there exist $C,\sigma >0$ and $\theta\in (0,\frac{1}{2}]$ such that where $\|\cdot\|$ denotes the Euclidean norm in $\mathbb{R}^d$.

Theorems & Definitions (99)

  • Theorem 1.1: Łojasiewicz inequality, SL-63
  • Remark 1.2
  • Definition 1.3
  • Theorem 1.4
  • Remark 1.5
  • Theorem 1.6
  • Corollary 1.7
  • proof
  • Remark 1.8
  • Definition 2.1: VB-93
  • ...and 89 more