Let $A$ be an abelian variety of dimension $g$ over an algebraically closed field $k$.
Assume $k$ has characteristic $p$ and denote by $A(p)$ the $p$-divisible group of dimension $g$ associated with $A$. Then the map $$ End(A) \to End(A(p)) $$ is injective and, if $k = \overline{\mathbb{F}}_p$, even a bijection after $p$-completion (by a theorem of Tate). In particular, every automorphism of $A$ inducing the identity on the p-divisible group is already the identity.
In dimension $1$, i.e. for elliptic curves something significantly stronger is true. Every automorphism of an elliptic curve inducing the identitiy on the formal group is the identity. Indeed, the following stronger statement is true and proven in Notes by Charles Rezk, Proposition 12.2: A choice of coordinate of the formal group up to terms of order 5 is equivalent to the choice of Weierstrass coordinates (and no non-trivial automorphism fixes the Weierstrass coordinates).
Is it true in general that automorphisms of abelian varieties are detected by the formal group in the sense that every automorphism of an abelian variety $A$ inducing the identity on the formal group of $A$ is already the identity?
Note that the corresponding result is clearly true if $k=\mathbb{C}$ as already every automorphism fixing the Lie algebra is the identity.
In some situations, it is possible to assign to an abelian variety $A$ of dimension $g$ a $1$-dimensional instead of a $g$-dimensional formal group/$p$-divisible group. To that purpose assume (as in the statement of a PEL-Shimura moduli problem):
- A is ($\mathbb{Z}_{(p)}$)-principally polarized.
- For a quadratic imaginary extension $F$ of $\mathbb{Q}$, we have a morphism $\mathcal{O}_F \to End(A)$ such that complex conjugation is sent to the Rosatti involution.
- $p$ splits in $F$ so that $\mathcal{O}_F \otimes \mathbb{Z}_p \cong \mathbb{Z}_p\times \mathbb{Z}_p$. Denote a corresponding non-trivial idempotent in $\mathcal{O}_F \otimes \mathbb{Z}_p$ by $e$.
- eA(p) is $1$-dimensional.
Also here it is true that every automorphism of $A$, fixing the polarization and the endomorphism structure, that induces the identity on $eA(p)$ is already the identity.
Is it true in the situation above that every automorphism of $A$, fixing the polarization and the endomorphism structure, that induces the identity on the formal group of $eA(p)$ is already the identity?
