Let $X$ be a Calabi-Yau 3-fold with Picard number one. How can one show that the automorphism group $Aut(X)$ is finite and moreover coincides with the birational automorphism group $Bir(X)$?
It seems this is a well-knwon fact, but I cannot find any reference. Since any automorphism group of $X$ preserves the ample generator of $Pic(X)$, this question should reduce to the projective geometry.
The group $\mathrm{Aut}(X)$ is finite because, as you point out, it preserves a very ample line bundle; hence it is an algebraic group (a closed subgroup of a projective group). Therefore it suffices to prove that its Lie algebra $H^0(X,T_X)$ is trivial. By Serre duality this is dual to $H^3(X,\Omega ^1_X)=H^{1,3}$, which is conjugate to $H^{3,1}=H^1(X,\mathcal{O}_X)$, which is trivial by definition of Calabi-Yau varieties.
Now since $K_X$ is trivial, any birational automorphism is an isomorphism outside sets of codimension $\geq 2$ (see for instance here, p. 2 for a much more general statement). This implies again that it preserves a very ample line bundle, hence that it is biregular.
Even though an (very good) answer was already accepted, if you want to know more on automorphism and birational groups of Calabi - Yau 3 folds you can look at papers by Keiji Oguiso.
