Let $k$ be a finite field, $A$ a smooth $k$-algebra.
Does there exists a smooth algebra $B$ over the Witt vectors $W(k)$, such that $B/p\simeq A$? How is it constructed?
1 Answer
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This follows from a result of Elkik in [R. Elkik Solutions d’équations à coefficients dans un anneau hensélien Annales scientifiques de l’É.N.S. 4e série, tome 6, no 4 (1973), p. 553-603.].
Theorem (Theorem 6 in Section 4 on p. 580, changed notation to fit yours). Let $(R, J)$ be a noetherian henselian couple. Then every smooth $R/J$-algebra $A$ lifts to a smooth $R$-algebra $B$.
Of course if you only want to lift formally over $R=W(k)$, that is to find a system $B_n$ over $W_{n+1}(k)$ lifting $B_{n-1}$ with $B_0 = A$, then the result follows from elementary deformation theory: the obstruction to lifting $B_{n-1}$ over $W_{n+1}(k)$ lies in $H^2({\rm Spec}(A), T_{{\rm Spec}(A)})=0$. But why should the inverse limit of the $B_n$ be the $p$-adic completion of a smooth $W(k)$-algebra?
Similarly, if $A$ is a smooth complete intersection, then it is easy to lift $A$ over $W(k)$: just lift the equations, and then maybe localize if the lifting is not smooth.
answered May 17, 2018 at 18:04
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$\begingroup$ How functorial is the formal $W(k)$-lift? How functorial is its algebraization? $\endgroup$– user92332Commented May 17, 2018 at 18:38
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$\begingroup$ Not functorial at all, the lifts have plenty of automorphisms. But at least the formal lift is unique (up to a non-unique isomorphism). Even this is false for the algebraized lift: consider $\mathbf{Z}_p[x]$ and $\mathbf{Z}_p[x,\frac{1}{px-1}] = \mathbf{Z}_p[x,y]/(y(px-1)-1)$, they both lift $\mathbf{F}_p[x]$. $\endgroup$ Commented May 17, 2018 at 18:53
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$\begingroup$ Arabia showed that smooth lifts exist for arbitrary surjections (no noetherian or henselian condition is assumed). See tag 07M8 in Stacks Project. $\endgroup$– user20948Commented May 29, 2019 at 14:57