用户: Fyx1123581347/偏微分方程/变分方法/Hille–Yosida 定理

1Perfectoid Fields

1Perfectoid Fields

A characteristic $p$ ring $R$ (i.e., a ring $R$ such that $p \cdot 1_{R} = 0$ or synonymously an $F_{p}$ -algebra) is perfect if the Frobenius $ϕ : R \to R, x \mapsto x^{p}$ is an isomorphism; it is semiperfect if $ϕ$ is merely surjective.

定义 1.1. Let $R$ be a ring of characteristic $p$ , $I$ be the poset $N$ , $F : I \to Ring$ be the functor $F (i) = R$ , $F ((i, j)) = ϕ^{j - i}$ for $j \geq i$ , $G : I^{o p} \to Ring$ be the functor $F (i) = R$ , $F ((j, i)) = ϕ^{j - i}$ for $j \geq i$ . Define $R_{p er f} = colim F, R^{p er f} = lim G .$

Notice the colimit is filtered so one can write it down explicitly, and

R^{p er f} = {(a_{i})_{i \in N} ∣ a_{i} = a_{i + 1}^{p}} .

命题 1.2. Both $R_{p er f}$ and $R^{p er f}$ are perfect. The canonical map $R = F (0) \to R_{p er f}$ (resp. $R^{p er f} \to G (0) = R$ ) is universal for maps into (resp. from) perfect rings.

证明. One can argue directly, or notice that

ϕ

induces the same universal property of the (co)limit.

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例 1.3. The image of projection $R^{p er f} \to R$ consisting of $f \in R$ that admit a compatible system ${f^{\frac{1}{p ^{k}}}}$ . We shall sometimes call such elements perfect. It follows that $R^{p er f} \to R$ is surjective exactly when $R$ is semiperfect.

命题 1.4. Let $I$ be an ideal of characteristic $p$ ring $R$ .

1.	If $I$ is locally nilpotent, then $R_{p er f} ≃ (R / I)_{p er f}$ .
2.	If $ϕ^{n} (I) = 0$ for some $n$ , then $R^{p er f} ≃ (R / I)^{p er f}$ .

证明. colimit perfection: As filtered colimit is exact, clearly $R_{p er f} \to (R / I)_{p er f}$ is surjective. If $r \in R_{p er f}$ coming from $R_{i}$ is $0$ in $(R / I)_{p er f}$ , then $r^{p^{m}}$ is $0$ in $R / I$ for some $m$ and $r^{p^{m}} \in I$ . Thus $r^{p^{m} k} = 0$ , which implies $r = 0$ in $R_{p er f}$ .

limit perfection: clearly

lim_{ϕ} I = 0

, and

I

is Mittag – Leffler. Thus

lim_{ϕ} R = lim_{ϕ} R / I

$□$

例 1.5. If $ϕ$ is injective, then $R^{p er f}$ is the subring of perfect elements in $R$ . Thus $F_{p} [t]^{p er f} = F_{p}$ .

If $R$ is a domain, $K = Frac R$ , then $R_{p er f} = R [r^{\frac{1}{p ^{\infty}}}]_{r \in R}$ .

If $char R = p$ , and $R$ is perfect, then $(R / f)^{p er f}$ is the $f$ -adic completion of $R$ . In fact, we have the commutative diagram where each vertical arrow is an isomorphism.

定义 1.6 (Fontaine). For any ring $R$ , set $R^{♭} := (R / p)^{p er f}$ . Unless otherwise specified, this ring is endowed with the inverse limit topology.

引理 1.7. Let $R$ be a ring, and let $t \in R$ be an element such that $p \in (t)$ . Given $a, b \in R$ with $a \equiv b mod t$ , we have $a^{p^{n}} \equiv b^{p^{n}} mod t^{n + 1}$ for all $n$ .

命题 1.8. Assume $R$ is $p$ -adically complete. The projection map $R \to R / p$ induces a bijection $x \mapsto x^{p} lim R \to ϕ lim R / p =: R^{♭}$ of multiplicative monoids.

证明. Injectivity: Suppose $a_{n} \equiv b_{n} mod p$ for $n \geq 0$ . As $a_{n + k}^{p^{k}} = a_{n}$ for $k \geq 0$ , from the lemma we have $a_{n} \equiv b_{n} mod p^{k}$ . As $R$ is $p$ -adically separated, $a_{n} = b_{n}$ .

Surjectivity: For

(\overline{a_{n}}) \in lim_{ϕ} R / p

, take (arbitrary) lift

(a_{n}) \in R^{N}

. Then

a_{n + k + 1}^{p} \equiv a_{n + k} mod p

for all

n, k

. Thus

k \mapsto a_{n + k}^{p^{k}}

is Cauchy for the

p

-adic topology and thus has a limit

b_{n}

. One checks

b_{n} = b_{n + 1}^{p}

and

b_{n}

lifts

\overline{a_{n}}

.

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注 1.9. If one topologizes $R$ with the $p$ -adic topology and $R / p$ with the discrete topology, then the bijection is a homeomorphism. In fact, the map $R \to R / p$ is continuous, and thus $lim_{x \mapsto x^{p}} R \to R^{♭}$ is continous. It suffices to show it is open. (to be completed)

注 1.10. Via projection to the last term, we get multiplicative map $♯ : R^{♭} \to R$ denoted $f \mapsto f^{♯}$ . For $R = Z_{p}$ this is the Teichmüller lifting.

引理 1.11. If a $p$ -adically complete ring $R$ is a domain (resp. a valuation ring), the same is true for its tilt $R^{♭}$ . In fact, if $∣ \cdot ∣ : R \to Γ \cup {0}$ is the valuation on $R$ , then the map $R^{♭} \to ♯ R \to ∣ \cdot ∣ Γ \cup {0}$ gives the valuation on $R^{♭}$ . In particular, the rank of $R^{♭}$ is bounded by the rank of $R$ .

证明. For $a, b \in R^{♭}$ , let $(a_{n}), (b_{n}) \in lim_{x \mapsto x^{p}} R$ be the corresponding lift. Then one checks $a ∣ b$ precisely when $a_{0} ∣ b_{0}$ , or equivalently $∣ a_{0} ∣ \geq ∣ b_{0} ∣$ .

For the last statement, notice that a subgroup

Γ^{'}

of a totally ordered abelian group

Γ

has smaller rank. In fact, for any convex subgroup

H^{'}

of

Γ^{'}

, let

H

be the subset of

Γ

defined by

{γ \in Γ ∣ h_{1}^{'} \leq γ \leq h_{2}^{'} for some h_{1}^{'}, h_{2}^{'} \in H^{'}},

then

H

is a convex subgroup of

Γ

, and different

H^{'}

corresponds to different

H

.

$□$

Fix a prime number $p$ .

定义 1.12. A perfectoid field $K$ is a NA field with residue characteristic $p$ such that

•	The value group $∣ K^{*} ∣ \subset R_{> 0}$ is not discrete.
•	$K^{\circ} / p$ is semiperfect.

例 1.13.

1.	$K = Q_{p} (p^{\frac{1}{p ^{\infty}}})$ .
2.	$K = Q_{p} (μ_{p^{\infty}})$ .
3.	$K = C_{p}$ .
4.	If $char K = p$ , then $K$ is perfectoid if and only if it is perfect.

引理 1.14. Let $K$ be a perfectoid field.

1.	The value group $∣ K^{*} ∣$ is $p$ -divisible.
2.	We have $(K^{\circ\circ})^{2} = K^{\circ\circ}$ . Moreover, $K^{\circ\circ}$ is flat.
3.	The ring $K^{\circ}$ is not Noetherian.

For the rest of section, we fix a pseudouniformizer $p \in K^{\circ}$ with $∣ p ∣ \leq ∣ π ∣ < 1$ , so $p \in (π)$ . If $char K = p$ , then $(K^{\circ} / π)^{p er f}$ is the $π$ -adic completion of $K^{\circ}$ , which is agian $K^{\circ}$ since we assumed $K$ is complete. If $char K = 0$ , we still have $(K^{\circ} / p)^{p er f} ≃ (K^{\circ} / π)^{p er f}$ . To summurize, we have the commutative diagram We want to show that $K^{\circ ♭}$ is the valuation ring of a perfectoid field $K^{♭}$ . To this end, we first find a pseudouniformizer:

引理 1.15. There exists some $t \in K^{\circ ♭}$ such that $∣ t^{♯} ∣ = ∣ π ∣$ . Moreover, $t$ maps to $0$ in $K^{\circ} / π$ , and this gives an isomorphism $K^{\circ ♭} / t ≃ K^{\circ} / π$ .

证明. By $p$ -divisibility of the value group, we may choose some $f \in K^{\circ}$ such that $∣ f ∣^{p} = ∣ π ∣$ , and hence $∣ f ∣ > ∣ π ∣$ . Choose $g \in K^{\circ ♭}$ lifting $f$ under the map $K^{\circ ♭} \to K^{\circ} / π$ . Then $g^{♯} = f mod π$ from the diagram. By the NA property, $∣ g^{♯} ∣ = ∣ f ∣$ . Setting $t = g^{p}$ we are done.

The kernel of the surjection

K^{\circ ♭} \to K^{\circ} / π

is precisely

g \in K^{\circ ♭}

such that

g^{♯} \in (π) = (t^{♯})

, or equivalently

t^{♯} ∣ g^{♯}

. But this is equivalent to

t ∣ g

. Thus

K^{\circ ♭} / t ≃ K^{\circ} / π

.

$□$

推论 1.16. With $t$ as above, $K^{\circ ♭}$ is $t$ -adically complete, and that the $t$ -adic topology coincides with the given topology.

证明.

K^{\circ ♭} ≃ (K^{\circ} / π)^{p er f} ≃ (K^{\circ ♭} / t)^{p er f} ≃ K^{\circ ♭} .

$□$

命题 1.17. Fix an element $t$ as in the lemma above.

1.	The ring $K^{\circ ♭}$ is a valuation ring, and the ring $K^{♭} := K^{\circ ♭} [\frac{1}{t}]$ is a perfect field.
2.	The ideal $(t^{\frac{1}{p ^{\infty}}})$ is maximal, and the Krull dimension of $K^{\circ ♭}$ is $1$ .
3.	The valuation topology on $K^{♭}$ comming from (1) coincides with the one induced by the $t$ -adic topology on $K^{\circ ♭}$ . In this topology, $K^{♭}$ is a perfectoid field, and $K^{♭, \circ} = K^{\circ ♭}$ .
4.	The value groups and residue fields of $K$ and $K^{♭}$ are canonically identified.

证明. We know that $K^{\circ ♭}$ is a valuation ring of rank $\leq 1$ . As $∣ t ∣^{♭} = ∣ t^{♯} ∣ = ∣ π ∣$ is not trivial, the rank is exactly $1$ . Thus $K^{\circ ♭}$ is microbial with $t$ as as a pseudouniformizer. Thus $K^{♭} = K^{\circ ♭} [\frac{1}{t}]$ , which is perfect as $K^{\circ ♭}$ is.

Since $(t^{\frac{1}{p ^{\infty}}})$ is radical, it is prime and thus maximal.

$□$

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用户: Fyx1123581347/偏微分方程/变分方法/Hille–Yosida 定理

1Perfectoid Fields