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Let G and H be groups and let \phi: G \longrightarrow H be a homomorphism. Then \ker(\phi) is a subgroup of G.

Proof. In order to show that \ker(\phi) is a subgroup of H, it must hold the subgroup criterion. For this proof, let 1_G and 1_H be the identities of G and H, respectively. Firstly, we know that \ker(\phi) is nonempty since it contains the identity element 1_G \in \ker(\phi). Secondly, let x,y \in \ker(\phi). To satisfy the subgroup criterion, we only need to show that xy^{-1} \in \ker(\phi). Since \phi(x) = \phi(y) = 1_H, we get the following: Therefore, this means that xy^{-1} \in \ker(\phi). So \ker(\phi) is a subgroup of G by the subgroup criterion.