Well-posedness and the ojasiewicz-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 D(A)-valued strong solution to a nonlinear heat equation with constraints on a Poincar\'e domain ⊂ d whose boundary is of class C2. Consider the following nonlinear heat equation align* ∂ u∂ t - u + |u|p-2u = 0, align* projected onto the tangent space Tu, where M:=\u∈ L2():\|u\|L2()=1\ is a submanifold of L2(). The nonlinearity exponent satisfies 2 p < ∞ for 1≤ d≤ 4 and 2 p 2d-4d-4 for d 5. The solution is constrained to lie within M which encodes the norm-preserving constraint. By modifying the nonlinearity and exploiting the abstract theory for m-accretive evolution equations, we prove the existence of a global strong solution. Using resolvent-idea and the Yosida approximation method, we derive regularity results. In the asymptotic analysis, is restricted to bounded domains with even p and 1 d 3. For any initial data in D(A) M, we apply the ojasiewicz-Simon gradient inequality on a Hilbert submanifold [F. Rupp, J. Funct. Anal., 279(8), 2020], to demonstrate that the unique global strong solution converges in W2,q() W1,q0() to a stationary state, where 2 q < 2dd + 4 - 4β and 1 < β < 32. This work proposes an alternative method for establishing the global existence and analyzing long-term behavior of the unique strong solution to an L2-norm preserving nonlinear heat equation.
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