Minimal periods for semilinear parabolic equations

Pub Date : 2024-04-12 DOI:10.1007/s00013-024-01970-6

Gerd Herzog, Peer Christian Kunstmann

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Abstract

We show that, if \(-A\) generates a bounded holomorphic semigroup in a Banach space X, \(\alpha \in [0,1)\), and \(f:D(A)\rightarrow X\) satisfies \(\Vert f(x)-f(y)\Vert \le L\Vert A^\alpha (x-y)\Vert \), then a non-constant T-periodic solution of the equation \({\dot{u}}+Au=f(u)\) satisfies \(LT^{1-\alpha }\ge K_\alpha \) where \(K_\alpha >0\) is a constant depending on \(\alpha \) and the semigroup. This extends results by Robinson and Vidal-Lopez, which have been shown for self-adjoint operators \(A\ge 0\) in a Hilbert space. For the latter case, we obtain - with a conceptually new proof - the optimal constant \(K_\alpha \), which only depends on \(\alpha \), and we also include the case \(\alpha =1\). In Hilbert spaces H and for \(\alpha =0\), we present a similar result with optimal constant where Au in the equation is replaced by a possibly unbounded gradient term \(\nabla _H{\mathscr {E}}(u)\). This is inspired by applications with bounded gradient terms in a paper by Mawhin and Walter.

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半线性抛物方程的最小周期

我们证明，如果 \(-A\) 在一个巴拿赫空间 X 中产生一个有界全形半群， \(\alpha \in [0,1)\), 并且 \(f. D(A)\rightarrow X\) 满足 \(\Vert f(x)-f(y)\Vert\le L\Vert A^\alpha (x-y)\)D(A)\rightarrow X\) 满足（\Vert f(x)-f(y)\Vert \le L\Vert A^alpha (x-y)\Vert \）、那么方程 \({\dot{u}}+Au=f(u)\) 的非恒定 T 周期解满足 \(LT^{1-\alpha }\ge K_\alpha \) 其中 \(K_\alpha >；0) 是一个常数，取决于 \(\alpha \) 和半群。这扩展了罗宾逊（Robinson）和维达尔-洛佩兹（Vidal-Lopez）的结果，这些结果已经在希尔伯特空间中的自（\ge 0\ ）算子中得到了证明。对于后一种情况，我们用一个新的概念证明得到了最优常数\(K_\alpha \)，它只取决于\(\alpha \)，我们还包括\(\alpha =1\)的情况。在希尔伯特空间 H 中，对于 \(\alpha =0\)，我们提出了一个具有最优常数的类似结果，其中方程中的 Au 被一个可能无约束的梯度项 \(\nabla_H{mathscr{E}}(u)\)所取代。这是受 Mawhin 和 Walter 的论文中有界梯度项应用的启发。

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