Let $\mathbb{K}$ be a field of characteristic $0$, $\overline{\mathbb{K}}$ its algebraic closure and $L$ a central simple $\mathbb{K}$-Lie algebra. Then there is a classical $\mathbb{K}$-Lie algebra $X$ and an automorphisms $B\in Aut_{\overline{\mathbb{K}}}(\overline{\mathbb{K}}\otimes_{\mathbb{K}} X)$ of vector spaces, such that \begin{align*} L=B(X). \end{align*} Moreover, $B$ is unique up to the class $B\circ Aut_{\mathbb{K}}X$.
Is that true? This representation is certainly not well-defined, i.e. for many automorphisms $B$ the image $B(X)$ does not state any sensible algebraic structure. I just claim the existence and uniqueness of this representation.
My arguments: The central simple $\mathbb{K}$-Lie algebras are exactly the classical ones. If $L$ is central simple over $\mathbb{K}$, then $L':=\overline{\mathbb{K}}\otimes_{\mathbb{K}}L$ is central simple over $\overline{\mathbb{K}}$, and so classical. Let $X$ the classical $\mathbb{K}$-Lie algebra which satisfies $\overline{\mathbb{K}}\otimes_{\mathbb{K}}X=L'$. Then $L$ and $X$ both have embeddings into L'. By the properties of the tensor product any $\mathbb{K}$-base$B_X$ of $X$ or $B_L$ of $L$ is also a $\overline{\mathbb{K}}$-base of $L'$. Hence there is a a base change transformation automorphism $B\in Aut_{\overline{\mathbb{K}}}L'$, such that $B(B_X)=B(B_L)$. This implies $B(X)=L$.