I am writing up my comment as an answer.  Let $k$ be field of characteristic $p$.  Denote by $\mathbb{A}^2_k$ the $k$-scheme $\text{Spec}\ k[s,t]$ with its usual structure of group $k$-scheme, $$m:\mathbb{A}^2_k \times_{\text{Spec}\ k}\mathbb{A}^2_k \to \mathbb{A}^2_k, \ \ m^*(x) = x\otimes 1 + 1\otimes x, \ \ m^*(y) = y\otimes 1 + 1\otimes y,$$ and where the identity of this group action is the origin, i.e., the point corresponding to the maximal ideal $\mathfrak{m}=\langle x,y\rangle$.  

Denote by $\mathbb{P}^1_k$ the $k$-scheme $\text{Proj}\ k[u,v]$ where $u$ and $v$ each have degree $1$.  The group $k$-scheme $\mathbb{A}^2_k$ induces a group $\mathbb{P}^1$-scheme by pullback, $$\text{pr}_1:\mathbb{P}^1_k \times_{\text{Spec}\ k} \mathbb{A}^2_k \to \mathbb{P}^1_k, $$ $$(\text{pr}_1,m\circ \text{pr}_{2,3}):\mathbb{P}^1_k\times_{\text{Spec}\ k}\mathbb{A}^2_k \times_{\text{Spec}\ k}\mathbb{A}^2_k \to \mathbb{P}^1_k \times_{\text{Spec}\ k} \mathbb{A}^2_k.$$  Denote by $\Gamma$ the closed subscheme of $\mathbb{P}^1_k\times_{\text{Spec}\ k}\mathbb{A}^2_k$ whose ideal sheaf is generated by $\text{pr}_2^*(\mathfrak{m}^p)$ and the equation $uy-vx$.  

The closed subscheme $\Gamma$ is a subgroup $\mathbb{P}^1$-scheme of $\mathbb{P}^1_k\times_{\text{Spec}\ k}\mathbb{A}^2_k,$ that is finite and flat over $\mathbb{P}^1_k$, and there exists a unique finite, flat morphism of group $\mathbb{P}^1$-schemes, $$q:\mathbb{P}^1_k\times_{\text{Spec}\ k}\mathbb{A}^2_k \to X,$$ such that the following induced morphism is an isomorphism, $$\Gamma\times_{\mathbb{P}^1_k} \mathbb{A}^2_k \to \mathbb{A}^2_k\times_X \mathbb{A}^2_k.$$  This claim is easiest to prove Zariski locally on $\mathbb{P}^1_k$.  On the dense open subset $D_+(u)\subset \mathbb{P}^1_k$, there is an isomorphism of group $D_+(u)$-schemes, $$\phi:D_+(u)\times_{\text{Spec}\ k} \mathbb{A}^2_k \to D_+(u)\times_{\text{Spec}\ k} \mathbb{A}^2_k, \ \ \phi^*x = x, \ \phi^*y = y+(v/u)x.$$  The inverse image of $\Gamma$ is $D_+(u)\times (\alpha_p\times \{0\}),$ i.e., the copy of $\alpha_p$ in the first factor of $\mathbb{A}^2_k$.  The quotient by this inverse image group $D_+(u)$-scheme is the finite flat morphism, $$q_u:D_+(u)\times \mathbb{A}^2_k \to D_+(u)\times \mathbb{A}^2_k, \ \ q_u^*(x) = x^p, \ \ q_u^*(y) = y.$$  There is a similar description on $D_+(v)$, and the uniqueness of quotients allows to glue these quotients on $D_+(u)\cap D_+(v)$.  

The quotient group morphism $q$ induces an action of the group $\mathbb{P}^1$-scheme $\mathbb{P}^1_k\times_{\text{Spec}\ k} \mathbb{A}^2_k$ on $X$.  This is equivalent to an action of $\mathbb{A}^2_k$ on the $k$-scheme $X$ such that the projection morphism, $$\pi:X\to \mathbb{P}^1_k,$$ is $\mathbb{A}^2_k$-invariant.  Define $Y$ to be the image of the section of $\pi$ coming from the group identity.  The inverse image of $Y$ under $q$ equals $\Gamma$.  Thus, the stabilizer subgroup $k$-scheme $H$ of $Y$ equals the subgroup $k$-scheme that maps $\Gamma$ to itself.  

In particular, for the fiber $\Gamma_0$ over $\text{Zero}(v)\subset \mathbb{P}^1_k$, this is a subgroup $k$-scheme of $\mathbb{A}^2_k$ whose regular action on $\mathbb{A}^2_k$ maps $\alpha_p\times\{0\}$ to itself, i.e., a subgroup $k$-scheme of $\alpha_p\times\{0\}$.  On the other hand, for the fiber $\Gamma_\infty$ over $\text{Zero}(u)\subset \mathbb{P}^1_k$, this is a subgroup $k$-scheme of $\{0\}\times \alpha_p.$  The intersection of these two subgroup $k$-schemes of $\mathbb{A}^2_k$ is the trivial subgroup scheme $\text{Spec}\ k$.  Thus, $H$ is the trivial subgroup $k$-scheme.

The induced morphism $(Y\times G)/\Delta(H) \to X$ is simply the morphism $q$.  This morphism is a universal homeomorphism.  However, the morphism $q$ is not an isomorphism: it is finite and flat of degree $p>1$.