Formally étale morphism

In commutative algebra and algebraic geometry, a morphism is called formally étale if it has a lifting property that is analogous to being a local diffeomorphism.

Formally étale homomorphisms of rings

Let A be a topological ring, and let B be a topological A-algebra. Then B is formally étale if for all discrete A-algebras C, all nilpotent ideals J of C, and all continuous A-homomorphisms u : B → C/J, there exists a unique continuous A-algebra map v : B → C such that u = pv, where p : C → C/J is the canonical projection.[1]

Formally étale is equivalent to formally smooth plus formally unramified.[2]

Formally étale morphisms of schemes

Since the structure sheaf of a scheme naturally carries only the discrete topology, the notion of formally étale for schemes is analogous to formally étale for the discrete topology for rings. That is, a morphism of schemes f : X → Y is formally étale if for every affine Y-scheme Z, every nilpotent sheaf of ideals J on Z with i : Z₀ → Z be the closed immersion determined by J, and every Y-morphism g : Z₀ → X, there exists a unique Y-morphism s : Z → X such that g = si.[3]

It is equivalent to let Z be any Y-scheme and let J be a locally nilpotent sheaf of ideals on Z.[4]

Properties

Open immersions are formally étale.[5]
The property of being formally étale is preserved under composites, base change, and fibered products.[6]
If f : X → Y and g : Y → Z are morphisms of schemes, g is formally unramified, and gf is formally étale, then f is formally étale. In particular, if g is formally étale, then f is formally étale if and only if gf is.[7]
The property of being formally étale is local on the source and target.[8]
The property of being formally étale can be checked on stalks. One can show that a morphism of rings f : A → B is formally étale if and only if for every prime Q of B, the induced map A → B_Q is formally étale.[9] Consequently, f is formally étale if and only if for every prime Q of B, the map A_P → B_Q is formally étale, where P = f⁻¹(Q).

Examples

Localizations are formally étale.
Finite separable field extensions are formally étale. More generally, any (commutative) flat separable A-algebra B is formally étale.[10]

Notes

EGA 0_IV, Définition 19.10.2.
EGA 0_IV, Définition 19.10.2.
EGA IV₄, Définition 17.1.1.
EGA IV₄, Remarques 17.1.2 (iv).
EGA IV₄, proposition 17.1.3 (i).
EGA IV₄, proposition 17.1.3 (ii)–(iv).
EGA IV₄, proposition 17.1.4 and corollaire 17.1.5.
EGA IV₄, proposition 17.1.6.
mathoverflow.net question
Ford (2017, Corollary 4.7.3)

References

Ford, Timothy J. (2017), Separable algebras, Providence, RI: American Mathematical Society, ISBN 978-1-4704-3770-1, MR 3618889
Grothendieck, Alexandre; Dieudonné, Jean (1964). "Éléments de géométrie algébrique: IV. Étude locale des schémas et des morphismes de schémas, Première partie". Publications Mathématiques de l'IHÉS. 20. doi:10.1007/bf02684747. MR 0173675.
Grothendieck, Alexandre; Dieudonné, Jean (1967). "Éléments de géométrie algébrique: IV. Étude locale des schémas et des morphismes de schémas, Quatrième partie". Publications Mathématiques de l'IHÉS. 32. doi:10.1007/bf02732123. MR 0238860.

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[1] EGA 0_IV, Définition 19.10.2.

[2] EGA 0_IV, Définition 19.10.2.

[3] EGA IV₄, Définition 17.1.1.

[4] EGA IV₄, Remarques 17.1.2 (iv).

[5] EGA IV₄, proposition 17.1.3 (i).

[6] EGA IV₄, proposition 17.1.3 (ii)–(iv).

[7] EGA IV₄, proposition 17.1.4 and corollaire 17.1.5.

[8] EGA IV₄, proposition 17.1.6.

[9] thoverflow.net question

[10] Ford (2017, Corollary 4.7.3)