On the periodic Navier--Stokes equation: An elementary approach to existence and smoothness for all dimensions n≥ 2

Abstract

In this paper we study the periodic Navier--Stokes equation. From the periodic Navier--Stokes equation and the linear equation ∂t u = u + P [v∇ u] we derive the corresponding equations for the time dependent Fourier coefficients ak(t). We prove the existence of a unique smooth solution u of the linear equation by a Montel space version of Arzel\`a--Ascoli. We gain bounds on the ak's of u depending on v. With v = -u these bounds show that a unique smooth solution u of the n-dimensional periodic Navier--Stokes equation exists for all t∈ [0,T*) with T* ≥ 2· \|u0\|A,0-2. \|u0\|A,0 is the sum of the l2-norms of the Fourier coefficients without ei· 0· x of the initial data u0∈ C∞(Tn,Rn) with div\, u0=0. For \|u0\|A,0 ≤ (small initial data) we get T* = ∞. All results hold for all dimensions n≥ 2 and are independent on n.