The Navier-Stokes Equation and Helmholtz Decomposition

Abstract

This work explores Navier-Stokes equation with no gravitational forces. In short, it shows that any smooth solution that decays quickly must take the form u(x,t)- 14πCurl( ∫R3Curl (u (x,t))|x-x|dV) = -∫0t1 Grad((x,s))ds. Consequently, any curl free solution must be written as u(x,t) = -1 Grad(∫0t(x,s) ds) with a known function which is related to the heat equation. Even further it shows if there exist a value k∈ N such that curlk((u· ∇ )u)(x,t)=0 for all t t then u(x,t) = Hk+1(1,2,3,t) -∫0t1 Grad((x,s))ds, ~~~~~ t∈ [t,∞) with i(x,t):= ∫R3α(x-y,t)vki(x,0)dy, ~~~~~ vki(x,0) = (curlk(u(x,0)))i, ~~~~~ 1 i 3 and Hk the kth application of Helmholtz operator. Hence, if there is another solution where the non-linear term is infinitly curlable then the solution is not unique. If the solution is unique, then this is the only possible solution.