Global well-posedness and optimal decay rates of classical solutions to the compressible Navier-Stokes-Fourier-P1 approximation model in radiation hydrodynamics
Abstract
In this paper, the compressible Navier-Stokes-Fourier-P1 (NSF-P1) approximation model in radiation hydrodynamics is investigated in the whole space R3. This model consists of the compressible NSF equations of fluid coupled with the transport equations of the radiation field propagation. Assuming that the initial data are a small perturbation near the equilibrium state, we establish the global well-posedness of classical solutions for this model by performing the Fourier analysis techniques and employing the delicate energy estimates in frequency spaces. Here, we develop a new method to overcome a series of difficulties arising from the linear terms n1 in (3.2)2 and n0 in (3.3)3 related to the radiation intensity. Furthermore, if the L1-norm of the initial data is bounded, we obtain the optimal time decay rates of the classical solution at Lp-norm (2≤ p≤ ∞). To the best of our knowledge, this is the first result on the global well-posedness of the NSF-P1 approximation model.
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