Recall that the multiplicative group scheme $\mu_k:R\mapsto R^\times$ assigns to a $k$-ring $R\in M_k$ the multiplicative group consisting of the invertible elements of $R$. In generalization of this group $\mu_k$ is the following notion of multiplicative group scheme: +-- {: .num_defn} ###### Definition and Remmark A group scheme is called *multiplicative group scheme* if the following equivalent conditions are satisfied: 1. $G\otimes_k k_s$ is [[diagonalizable group scheme|diagonalizable]]. 1. $G\otimes_k K$ is diagonalizable for a field $K\in M_k$. 1. $G$ is the Cartier dual of an étale $k$-group. 1. $\hat D(G)$ is an étale $k$-formal group. 1. $Gr_k(G,\alpha_k)=0$ 1. (If $p\neq 0)$, $V_G$ is an epimorphism 1. (If $p\neq 0)$, $V_G$ is an isomorphism =-- +-- {: .num_remark} ###### Remark Let $G_const$ dnote a [[constant group scheme]], let $E$ be an [[étale group scheme]]. Then we have the following [[Cartier duality|cartier duals]]: 1. $D(G_const)$ is [[diagonalizable group scheme|diagonalizable]]. 1. $D(E)$ is [[multiplicative group scheme|multiplicative]] =--