Answer to Question #151528 in Functional Analysis for anjali

Suppose that "X'" is separable. By definition, "\\exists (f_n)_{n\\in\\mathbb{N}} \\in (X')^{\\mathbb{N}}, \\overline{(f_n)} = X'" . For all "f_n\\neq 0" we can find an "x_n \\in X, f(x_n)\\geq \\frac{1}{2} ||f_n||" . We claim that "F = Vect_{\\mathbb{Q}} ((x_n)_{n\\in\\mathbb{N}})" ("Vect_{\\mathbb{Q}+i\\mathbb{Q}}" if "K" is complex) is dense in "X". Suppose that it is not true, then "\\exists x\\in X, x\\neq0, \\epsilon>0, \\forall y\\in Vect_{\\mathbb{Q}}((x_n)), ||x-y|| \\geq \\epsilon" . By Hahn-Banach theorem, "\\exists f\\in X', f(x) = 1 = ||f||, f(\\overline{F})=f(F) = \\{ 0\\}" , as "f|_{\\overline{Vect(x, (x_n))}}" is a continuous linear operator. Now let's consider "||f-f_n||" for "f_n\\neq 0" :

"||f-f_n|| \\geq \\frac{|f(x_n)-f(x_n)|}{||x_n||} \\geq \\frac{1}{2}||f_n||"

But as "(f_n)" is dense, "\\forall \\epsilon'>0, \\exists n" tel que "||f-f_n||<\\epsilon' \\Rightarrow ||f_n||<2\\epsilon', ||f||<3\\epsilon'". It is a contradiction, as "||f||=1."

For "f_n=0, ||f-f_n||=||f|| = 1 >0"

It is a contradiction, because "f \\notin \\overline{f_n}, f\\in X'" . Therefore "F" is dense in "X" and thus "X" is separable.