First, it is not a cubic equation!
Yes, you can replace sqrt(x) with a new variable z, thus a transformation. But doing so can sometimes introduce spurious or false solutions. For example, if a negative value for z is one of the solutions, then it is not a solution to your problem, but it may be a solution to the transformed problem in z. You will generally need to test to see if what you find really is a solution to the original problem.
You already have the problem in the form of a cubic polynomial in z.
Can you write down the general solution to a cubic polynomial in terms of the coefficisnts? Yes. This has been known for longer than any of us have been alive.
Just apply solve to the result. Note that it will be a mess, with imaginary terms in it. And depending on the value of N, you will have exactly 1 or 3 real solutions.
syms z N
EQ = 2*N*sqrt(2*sym(pi))*z^3 + 4*N*sqrt(2*sym(pi))*z^2 - 4
zsol = solve(EQ,maxdegree = 3)
zsol =
4/(9*(((2^(1/2)/(2*N*pi^(1/2)) - 8/27)^2 - 64/729)^(1/2) + 2^(1/2)/(2*N*pi^(1/2)) - 8/27)^(1/3)) + (((2^(1/2)/(2*N*pi^(1/2)) - 8/27)^2 - 64/729)^(1/2) + 2^(1/2)/(2*N*pi^(1/2)) - 8/27)^(1/3) - 2/3
- 2/(9*(((2^(1/2)/(2*N*pi^(1/2)) - 8/27)^2 - 64/729)^(1/2) + 2^(1/2)/(2*N*pi^(1/2)) - 8/27)^(1/3)) - (((2^(1/2)/(2*N*pi^(1/2)) - 8/27)^2 - 64/729)^(1/2) + 2^(1/2)/(2*N*pi^(1/2)) - 8/27)^(1/3)/2 - (3^(1/2)*(4/(9*(((2^(1/2)/(2*N*pi^(1/2)) - 8/27)^2 - 64/729)^(1/2) + 2^(1/2)/(2*N*pi^(1/2)) - 8/27)^(1/3)) - (((2^(1/2)/(2*N*pi^(1/2)) - 8/27)^2 - 64/729)^(1/2) + 2^(1/2)/(2*N*pi^(1/2)) - 8/27)^(1/3))*1i)/2 - 2/3
- 2/(9*(((2^(1/2)/(2*N*pi^(1/2)) - 8/27)^2 - 64/729)^(1/2) + 2^(1/2)/(2*N*pi^(1/2)) - 8/27)^(1/3)) - (((2^(1/2)/(2*N*pi^(1/2)) - 8/27)^2 - 64/729)^(1/2) + 2^(1/2)/(2*N*pi^(1/2)) - 8/27)^(1/3)/2 + (3^(1/2)*(4/(9*(((2^(1/2)/(2*N*pi^(1/2)) - 8/27)^2 - 64/729)^(1/2) + 2^(1/2)/(2*N*pi^(1/2)) - 8/27)^(1/3)) - (((2^(1/2)/(2*N*pi^(1/2)) - 8/27)^2 - 64/729)^(1/2) + 2^(1/2)/(2*N*pi^(1/2)) - 8/27)^(1/3))*1i)/2 - 2/3
And again, it will depend on the value of N what will happen.
