Proof. The first statement follows from [Reference Bhatt, Morrow and Scholze7, Lem. 3.9].

We next check that $\varpi $ is a perfectoid element of S. Note that the conditions (2) and (3) in Definition 2.1 are independent of the choice of a perfectoid element. Since $\varpi ^p = vp$ divides p in S, it suffices to show that S is p-adically complete and this is also clear (see [Reference Česnavičius and Scholze11, §2.1.2] or [Reference Dospinescu13, Prop. 2.8]).

Proof. Fix a pair of definition $(A_0, (t))$ of A and a ring of integral elements $A_0^+$ of A such that $A_0 \subseteq A_0^+$ . By [Reference Nakazato and Shimomoto20, Lem. 2.3], we have an inclusion $t (A^+_0)^*_A \subseteq A_0^+$ , where $(A_0^+)^*_A$ is the complete integral closure of $A_0^+$ in A. By [Reference Nakazato and Shimomoto20, Prop. 2.4], the canonical map $A^{\widehat {u}} = \widehat {A^+_0}[1/t] \to \widehat {(A_0^+)^*_{A^u}}[1/t]$ is an isomorphism of Tate rings and this map induces an isomorphism of topological rings $\left (\widehat {A^+_0}\right )^{\!*}_{A^{\widehat {u}}} \to \widehat {(A_0^+)^*_{A^u}}$ . Since $A^{\widehat {u}}$ (resp., $A^u$ ) has a ring of definition $\widehat {A^+_0}$ (resp., $A_0^+$ ) and the complete integral closure is equal to the set of all power-bounded elements by [Reference Nakazato and Shimomoto20, Lem. 2.13], we have an isomorphism of topological rings $(A^{\widehat {u}})^\circ \xrightarrow {\cong } \widehat {A^{u \circ }}$ .

Proof. For any $f \in ((A^{\widehat {u}})^\circ )_*$ , we have $t^{1/p^n} f \in (A^{\widehat {u}})^\circ $ and then $t f^{p^n} \in (A^{\widehat {u}})^\circ $ for any $n \in \mathbb {Z}_{> 0}$ . Since $(A^{\widehat {u}})^\circ $ is a ring of definition of $A^{\widehat {u}}$ , we have $\lVert f^{p^n}\rVert \leq c$ for a fixed $c> 1$ by Definition 3.2. In particular, $\lVert f^{p^n}\rVert ^{1/p^n} \leq c^{1/p^n}$ for any $n \in \mathbb {Z}_{> 0}$ . Taking the limit $n \to \infty $ , we have $\lVert f\rVert _{\mathrm {sp}} \leq \lim _{n \to \infty } c^{1/p^n} = 1$ . This shows the inclusion $((A^{\widehat {u}})^\circ )_* \subseteq (A^{\widehat {u}})_{\lVert \cdot \rVert _{\mathrm {sp}} \leq 1} = (A^{\widehat {u}})^\circ $ by Lemma 3.3.

Proof. The kernel of $S \to S[1/\pi ]$ is isomorphic to the ideal $S[\pi ^\infty ]$ of all $\pi ^\infty $ -torsion elements of S. Since S is reduced, $S[\pi ^\infty ]$ is $(\pi )^{1/p^\infty }$ -almost zero. In particular, $S \to S^{\pi \mathrm {tf}}$ is (usual) surjective and $(\pi )^{1/p^\infty }$ -almost injective. Furthermore, the inclusion $S^{\pi \mathrm {tf}} \subseteq \pi ^{-1/p^\infty } S$ in $S[1/\pi ]$ is (usual) injective and $(\pi )^{1/p^\infty }$ -almost surjective by definition. This completes the proof.

Proof. If $\pi $ is a non-zero-divisor of S, this lemma is similar to [Reference Dospinescu13, Prop. 2.16(b)]. We only have to make the same proof as [Reference Scholze24, Lem. 5.6], being careful that S is not necessarily $\pi $ -torsion-free in our case.

First, we show that $S_*/\pi S_* \xrightarrow {a \mapsto a^p} S_*/\pi ^p S_*$ is injective. Let $t \in S_*$ be an element in the kernel of the p-th power map. There exists some $t' \in S_*$ such that $t^p = \pi ^p t'$ in $S_* \subseteq S[1/\pi ]$ . By definition of $S_*$ , multiplying $\pi ^{1/p^n}$ by the equation for each $n \in \mathbb {Z}_{> 0}$ , we have

(4.3) $$ \begin{align} (\pi^{1/p^{n+1}} t)^p = \pi^{1/p^n} t^p = \pi^p (\pi^{1/p^n} t') \in \pi^p S^{\pi \mathrm{tf}}. \end{align} $$

Moreover, $\pi ^{1/p^{n+1}} t$ and $\pi ^{1/p^n} t'$ are elements of $S^{\pi \mathrm {tf}}$ . Then, there exist some elements $s_{n+1}$ and $s^{\prime }_n$ in S such that $s_{n+1}/1 = \pi ^{1/p^{n+1}} t$ and $s^{\prime }_n/1 = \pi ^{1/p^n} t'$ in $S^{\pi \mathrm {tf}} \subseteq S[1/\pi ]$ . By the above equation (4.3), we have $s_{n+1}^p/1 = \pi ^p s^{\prime }_n/1$ in $S^{\pi \mathrm {tf}} \subseteq S[1/\pi ]$ and thus, $s_{n+1}^p - \pi ^p s^{\prime }_n$ is in $S[\pi ^{\infty }] \subseteq S$ , which is $(\pi )^{1/p^\infty }$ -almost zero. For any $m \in \mathbb {Z}_{> 0}$ , we have

$$ \begin{align*} S \ni 0 = \pi^{1/p^m} (s_{n+1}^p - \pi^p s^{\prime}_n) = (\pi^{1/p^{m+1}} s_{n+1})^p - \pi^p (\pi^{1/p^m} s^{\prime}_n). \end{align*} $$

In particular, $\pi ^{1/p^{m+1}} s_{n+1}$ is in the kernel of the p-th power map $S/\pi S \to S/\pi ^p S$ , which is zero by assumption of $(S, \pi )$ , and so $\pi ^{1/p^{m+1}} s_{n+1}$ is in $\pi S$ . Passing to $S^{\pi \mathrm {tf}} \subseteq S[1/\pi ]$ , we have

$$ \begin{align*} \pi S^{\pi \mathrm{tf}} \ni \pi^{1/p^{m+1}} s_{n+1}/1 = \pi^{1/p^{m+1}} \pi^{1/p^{n+1}} t \end{align*} $$

for any $n, m \in \mathbb {Z}_{> 0}$ . Then, t is in $(\pi S^{\pi \mathrm {tf}})_*$ , which is defined in Definition 4.3. The next equality (4.4) shows the injectivity of $S_*/\pi S_* \xrightarrow {a \mapsto a^p} S_*/\pi ^p S_*$ :

(4.4) $$ \begin{align} (\pi S^{\pi \mathrm{tf}})_* = \pi (S^{\pi \mathrm{tf}})_* = \pi S_* \subseteq S[1/\pi]. \end{align} $$

Proof of (4.4)

By definition, we have $(S^{\pi \mathrm {tf}})_* = S_*$ and then the second equality is clear. Any element of $\pi (S^{\pi \mathrm {tf}})_*$ can be written as $\pi t$ by using some element $t \in (S^{\pi \mathrm {tf}})_*$ . Because of $\pi ^{1/p^n} (\pi t) = \pi (\pi ^{1/p^n} t) \in \pi S^{\pi \mathrm {tf}}$ for any $n \in \mathbb {Z}_{> 0}$ , we have $\pi t \in (\pi S^{\pi \mathrm {tf}})_*$ and so $\pi (S^{\pi \mathrm {tf}})_* \subseteq (\pi S^{\pi \mathrm {tf}})_*$ .

Conversely, take any element $x \in (\pi S^{\pi \mathrm {tf}})_* \subseteq S[1/\pi ]$ . Then, there exists $t_n \in S^{\pi \mathrm {tf}}$ such that $\pi ^{1/p^n} x = \pi t_n \in \pi S^{\pi \mathrm {tf}}$ for each $n \in \mathbb {Z}_{> 0}$ . Since $S[1/\pi ]$ is $\pi ^{1/p^n}$ -torsion-free, we have

(4.5) $$ \begin{align} S[1/\pi] \ni \pi^{1/p^n} (x/\pi) = t_n \in S^{\pi \mathrm{tf}} \end{align} $$

for any $n \in \mathbb {Z}_{> 0}$ . This shows that $x/\pi \in S[1/\pi ]$ is in $(S^{\pi \mathrm {tf}})_*$ and thus $x = \pi (x/\pi )$ is in $\pi (S^{\pi \mathrm {tf}})_*$ .

Second, we show that $S_*/\pi S_* \xrightarrow {a \mapsto a^p} S_*/\pi ^p S_*$ is $(\pi )^{1/p^\infty }$ -almost surjective. Take any element $x \in S_* \subseteq S[1/\pi ]$ . For each $n \in \mathbb {Z}_{> 0}$ , we have $\pi ^{1/p^n} x \in S^{\pi \mathrm {tf}}$ and thus there exists an $s_n \in S$ such that $\pi ^{1/p^n} x = s_n/1 \in S^{\pi \mathrm {tf}}$ . Since $S/\pi S \xrightarrow {a \mapsto a^p} S/\pi ^p S$ is surjective, there exists some $s^{\prime }_n \in S$ such that $(s^{\prime }_n)^p - s_n$ is in $\pi ^p S$ . Then, we have

(4.6) $$ \begin{align} \pi^{1/p^n} x - (s^{\prime}_n/1)^p = s_n/1 - (s^{\prime}_n)^p/1 \in \pi^p S^{\pi \mathrm{tf}} \subseteq \pi^p S_* \end{align} $$

and $s^{\prime }_n/1$ is in $S^{\pi \mathrm {tf}} \subseteq S_*$ . This shows that $S_*/\pi S_* \xrightarrow {a \mapsto a^p} S_*/\pi ^p S_*$ is $(\pi )^{1/p^\infty }$ -almost surjective.

Finally, since $S_*$ is $\pi $ -torsion-free and $S_*/\pi S_* \xrightarrow {a \mapsto a^p} S_*/\pi ^p S_*$ is injective as above, by [Reference Česnavičius and Scholze11, (2.1.7.1)], we can show that $S_*$ is p-root closed in $S_*[1/\pi ]$ .

Proof. Proceeding as in [Reference Scholze24, Lem. 5.6], the p-root closedness of $S_*$ in $S_*[1/\pi ]$ proved in Lemma 4.6 shows that $(S_*[1/\pi ])^\circ = S_*$ . In fact, any element $x \in (S_*[1/\pi ])^\circ $ makes a topologically nilpotent element $\pi ^{1/p^n} x$ for each $n \in \mathbb {Z}_{> 0}$ . Thus there exists $N = N(n) \in \mathbb {Z}_{> 0}$ such that $(\pi ^{1/p^n} x)^{p^N} \in S_*$ . This shows the equality above and thus $S_*[1/\pi ]$ is a uniform Tate ring. Moreover, Lemma 3.3 shows that

(4.7) $$ \begin{align} S_* = (S_*[1/\pi])^\circ = (S_*[1/\pi])_{\lVert\cdot\rVert_{\mathrm{sp}} \leq 1} \end{align} $$

and we finish the proof.

Proof. This proof is similar to [Reference Ishizuka and Shimomoto16, Lem. 4.2]. Fix an element $y \in S_*$ . Since the p-th power map is $(\pi )^{1/p^\infty }$ -almost surjective by Lemma 4.6, there exist elements a and b in $S_*$ such that $\pi y = a^p + \pi ^p b \in S_*$ . Set . This satisfies

(4.8) $$ \begin{align} z^p = a^p/\pi = y - \pi^{p-1} b \in S_*. \end{align} $$

Since $S_*$ is p-root closed in $S_*[1/\pi ]$ by Lemma 4.6, we can show that $z \in S_*$ . The equality $\pi y = \pi z^p + \pi ^p b \in S_*$ and $\pi $ -torsion-freeness of $S_* \subseteq S_*[1/\pi ]$ show that $y = z^p + \pi ^{p-1} b \in S_*$ . In particular, every element of $S_*/\pi ^{p-1} S_*$ and $S_*/\pi S_*$ is a p-th power. The inclusion $\pi S_* \subseteq \pi ^{(p-1)/p} S_*$ induces the commutative diagram

where the rows are exact sequences and the vertical maps are the p-th power maps. Since the right-most map and left-most map are surjective, the middle map is also surjective by the five lemma.

Proof. By Lemma 4.6 and Corollary 4.8, the pair $(S_*, \pi )$ is a pre-perfectoid pair.

Assume that R is an integral perfectoid ring. By the above paragraph of [Reference Česnavičius and Scholze11, (2.1.3.1)], the image $R^{\pi \mathrm {tf}}$ of R in $R[1/\pi ]$ is a $\pi $ -torsion-free integral perfectoid ring. In particular, similar to the proof of [Reference Scholze24, Lem. 5.6], $R_* = (R^{\pi \mathrm {tf}})_*$ is also an integral perfectoid ring with a perfectoid element $\pi $ .

Proof. Since the $A_0$ -algebra structure $A_0 \to S$ is a continuous map with respect to the $\pi $ -adic topology, this can be extended to the map of Tate rings $A \to S[1/\pi ]$ . By Remark 4.4 and Lemma 4.7, the Tate ring $S[1/\pi ]$ is isomorphic to the complete uniform Tate ring $S_*[1/\pi ]$ .

The universality of uniform completion (Proposition 3.7) gives a unique map of Tate rings $A^{\widehat {u}} \to S_*[1/\pi ]$ which extends $A \to S[1/\pi ] = S_*[1/\pi ]$ . Taking the set of all power-bounded elements, we have a map of topological rings $(A^{\widehat {u}})^\circ \to S_*$ such that the above diagram commutes The uniqueness of this map is clear.

Proof. Take any map $f\colon (A_0)_{\operatorname {\mathrm {perfd}},*}\to (A_0)_{\operatorname {\mathrm {perfd}},*}$ such that the following diagram commutes

where the vertical maps are canonical ones. Since $(A_0)_{\operatorname {\mathrm {perfd}},*}$ is also an integral perfectoid ring by Theorem 4.9 and $(A_0)_{\operatorname {\mathrm {perfd}}}$ is a universal integral perfectoid ring over $A_0$ , the composite $f \circ c$ is nothing but the canonical map $c\colon (A_0)_{\operatorname {\mathrm {perfd}}}\to (A_0)_{\operatorname {\mathrm {perfd}},*}$ . For any $x \in (A_0)_{\operatorname {\mathrm {perfd}},*}$ , there exists an element $a \in (A_0)_{\operatorname {\mathrm {perfd}}}$ such that $c(a) = p x$ in $(A_0)_{\operatorname {\mathrm {perfd}},*}$ . Then, we have $p f(x) = f(p x) = f(c(a)) = c(a) = p x$ in $(A_0)_{\operatorname {\mathrm {perfd}},*}$ . Since $(A_0)_{\operatorname {\mathrm {perfd}},*}$ is p-torsion-free, we have $f(x) = x$ and we are done.

Proof of Corollary 5.3

The canonical surjective map $A_0 \twoheadrightarrow A_0^{\operatorname {\mathrm {ptf}}}$ induces a map $(A_0)_{\operatorname {\mathrm {perfd}}} \to (A_0^{\operatorname {\mathrm {ptf}}})_{\operatorname {\mathrm {perfd}}}$ . Since $(A_0^{\operatorname {\mathrm {ptf}}})_{\operatorname {\mathrm {perfd}}}$ is p-torsion-free by [Reference Ma, Schwede, Tucker, Waldron and Witaszek19, Lem. A.2], we have a unique map $\varphi \colon ((A_0)_{\operatorname {\mathrm {perfd}}})^{\operatorname {\mathrm {ptf}}}\to (A_0^{\operatorname {\mathrm {ptf}}})_{\operatorname {\mathrm {perfd}}}$ which extends the map $(A_0)_{\operatorname {\mathrm {perfd}}} \to (A_0^{\operatorname {\mathrm {ptf}}})_{\operatorname {\mathrm {perfd}}}$ .

Conversely, by [Reference Dospinescu13, Prop. 2.19], the p-torsion-free quotient $((A_0)_{\operatorname {\mathrm {perfd}}})^{\operatorname {\mathrm {ptf}}}$ is also an integral perfectoid ring over $A_0$ and thus there exists a unique map $A_0^{\operatorname {\mathrm {ptf}}} \to ((A_0)_{\operatorname {\mathrm {perfd}}})^{\operatorname {\mathrm {ptf}}}$ which extends the structure map $A_0 \to ((A_0)_{\operatorname {\mathrm {perfd}}})^{\operatorname {\mathrm {ptf}}}$ . The universality of perfectoidization (Theorem 2.9) shows that this map can be extended to a map $\psi \colon (A_0^{\operatorname {\mathrm {ptf}}})_{\operatorname {\mathrm {perfd}}}\to ((A_0)_{\operatorname {\mathrm {perfd}}})^{\operatorname {\mathrm {ptf}}}$ uniquely.

Then the $A_0^{\operatorname {\mathrm {ptf}}}$ -algebra map $\varphi \circ \psi $ is the identity map because of the universality of perfectoidizations (Theorem 2.9). On the other hand, the $(A_0)_{\operatorname {\mathrm {perfd}}}$ -algebra map $\psi \circ \varphi $ can be extended to the $(A_0)_{\operatorname {\mathrm {perfd}}}$ -algebra endomorphism on $(((A_0)_{\operatorname {\mathrm {perfd}}})^{\operatorname {\mathrm {ptf}}})_*$ because of the inclusion $((A_0)_{\operatorname {\mathrm {perfd}}})^{\operatorname {\mathrm {ptf}}} \subseteq (((A_0)_{\operatorname {\mathrm {perfd}}})^{\operatorname {\mathrm {ptf}}})_* \subseteq ((A_0)_{\operatorname {\mathrm {perfd}}})[1/p]$ . Then the above rigidity lemma (Lemma 5.2) shows that $\psi \circ \varphi $ is in fact the identity map on $((A_0)_{\operatorname {\mathrm {perfd}}})^{\operatorname {\mathrm {ptf}}}$ . This completes the proof.

Proof. If we know that $A^{\widehat {u}}$ is a perfectoid Tate ring, the same proof of [Reference Dine12, Th. 4.4] induces the isomorphism $A^{\widehat {u}} \cong (A_0)_{\operatorname {\mathrm {perfd}}}[1/p]$ by checking the universality of perfectoidizations and uniform completions as in Proposition 5.1. By Lemma 4.7, taking the set of all power-bounded elements induces the isomorphism $(A^{\widehat {u}})^\circ \cong (A_0)_{\operatorname {\mathrm {perfd}}, *}$ .

Proof. By Lemma 3.8, we have $(A^{\widehat {u}})^\circ \cong \widehat {A^{u \circ }}$ . Recall that $(A_0)_A^+$ becomes a ring of definition of $A^u$ and thus $A^{u \circ }$ is the complete integral closure $((A_0)_A^+)_A^*$ of $(A_0)_A^+$ in $A^u$ by [Reference Nakazato and Shimomoto20, Lem. 2.13(1)]. By assumption, $(A_0)_A^+$ is integral over some Noetherian ring and then $A^{u \circ } = (A_0)_A^+$ by [Reference Nakazato and Shimomoto21, Prop. 7.1]. This completes the proof.

Proof. Since $(A_0)_{\operatorname {\mathrm {perfd}}}$ is an integral perfectoid ring whose perfectoid element is $\varpi $ , the ring $(A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}}$ is also an integral perfectoid ring by [Reference Dospinescu13, Prop. 2.19]. In particular, $(A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}}$ is p-root closed in $(A_0)_{\operatorname {\mathrm {perfd}}}[1/p]$ because of the injectivity of the p-th power map $(A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}}/\varpi (A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}} \xrightarrow {a \mapsto a^p} (A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}}/p (A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}}$ (see [Reference Česnavičius and Scholze11, (2.1.7.1)]). The map of Tate rings $R[1/p] \to (A_0)_{\operatorname {\mathrm {perfd}}}[1/p]$ induced by $R \to A_0 \to (A_0)_{\operatorname {\mathrm {perfd}}}$ gives a unique map $\varphi \colon \widehat {C(R^{\operatorname {\mathrm {ptf}}})}\to (A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}}$ such that the following diagram commutes

(5.1)

Taking the p-adic completion of $R \to C(R^{\operatorname {\mathrm {ptf}}})$ , we have a map $A_0 \to \widehat {C(R^{\operatorname {\mathrm {ptf}}})}$ . By assumption, $\widehat {C(R^{\operatorname {\mathrm {ptf}}})}$ is an integral perfectoid ring and then, there exists a unique map $(A_0)_{\operatorname {\mathrm {perfd}}} \to \widehat {C(R^{\operatorname {\mathrm {ptf}}})}$ which extends $A_0 \to \widehat {C(R^{\operatorname {\mathrm {ptf}}})}$ as follows.

(5.2)

Since $\widehat {C(R^{\operatorname {\mathrm {ptf}}})}$ is p-torsion-free, there exists a unique map $\psi \colon (A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}})\to \widehat {C(R^{\operatorname {\mathrm {ptf}}})}$ which extends $(A_0)_{\operatorname {\mathrm {perfd}}} \to \widehat {C(R^{\operatorname {\mathrm {ptf}}})}$ .

Combining (5.1) and (5.2), the composite map $(A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}} \xrightarrow {\psi } \widehat {C(R^{\operatorname {\mathrm {ptf}}})} \xrightarrow {\varphi } (A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}}$ is an R-algebra map and thus an $A_0 = \widehat {R}$ -algebra map. Furthermore, this extends to an $A_0$ -algebra map of perfectoid Tate rings $(A_0)_{\operatorname {\mathrm {perfd}}}[1/p] \to (A_0)_{\operatorname {\mathrm {perfd}}}[1/p]$ and thus extends to an $A_0$ -algebra map $(A_0)_{\operatorname {\mathrm {perfd}},*} \to (A_0)_{\operatorname {\mathrm {perfd}},*}$ by Lemma 4.7. This must be the identity map because of Lemma 5.2 above, and then $\psi \circ \varphi $ is also the identity map.

On the other hand, consider the R-algebra map $\widehat {C(R^{\operatorname {\mathrm {ptf}}})} \xrightarrow {\varphi } (A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}} \xrightarrow {\psi } \widehat {C(R^{\operatorname {\mathrm {ptf}}})}$ . Inverting p, we have a map of Tate rings $\widehat {C(R^{\operatorname {\mathrm {ptf}}})}[1/p] \to \widehat {C(R^{\operatorname {\mathrm {ptf}}})}[1/p]$ over $R[1/p]$ via $R[1/p] \hookrightarrow C(R^{\operatorname {\mathrm {ptf}}})[1/p] \to \widehat {C(R^{\operatorname {\mathrm {ptf}}})}[1/p]$ . Since $C(R^{\operatorname {\mathrm {ptf}}}) \subseteq R[1/p]$ is contained in the integral closure $\widetilde {R}$ of R in $R[1/p]$ , the uniform completion $C(R^{\operatorname {\mathrm {ptf}}})[1/p]^{\widehat {u}}$ of $C(R^{\operatorname {\mathrm {ptf}}})[1/p]$ can be written as a Tate ring $\widehat {\widetilde {R}}[1/p]$ by Definition 3.6. Similarly, the uniform completion $R[1/p]^{\widehat {u}}$ of $R[1/p]$ also coincides with the Tate ring $\widehat {\widetilde {R}}[1/p]$ . So these two uniform completions $C(R^{\operatorname {\mathrm {ptf}}})[1/p]^{\widehat {u}}$ and $R[1/p]^{\widehat {u}}$ are isomorphic each other via the canonical map of Tate rings $R[1/p] \to C(R^{\operatorname {\mathrm {ptf}}})[1/p]$ .Footnote ⁴ Furthermore, since $\widehat {C(R^{\operatorname {\mathrm {ptf}}})}$ is a p-torsion-free integral perfectoid ring, the uniform completion of $\widehat {C(R^{\operatorname {\mathrm {ptf}}})}[1/p]$ is isomorphic to itself by Lemma 2.8. These arguments show that

(5.3) $$ \begin{align} R[1/p]^{\widehat{u}} \xrightarrow{\cong} C(R^{\operatorname{\mathrm{ptf}}})[1/p]^{\widehat{u}} \xrightarrow{\cong} \widehat{C(R^{\operatorname{\mathrm{ptf}}})}[1/p]^{\widehat{u}} \cong \widehat{C(R^{\operatorname{\mathrm{ptf}}})}[1/p]. \end{align} $$

This shows that the above $R[1/p]$ -algebra map of Tate rings $\widehat {C(R^{\operatorname {\mathrm {ptf}}})}[1/p] \to \widehat {C(R^{\operatorname {\mathrm {ptf}}})}[1/p]$ coincides with an $R[1/p]$ -algebra map of Tate rings $R[1/p]^{\widehat {u}} \to R[1/p]^{\widehat {u}}$ and this is the identity map by the universality of uniform completion.

We next check that $\varphi \colon \widehat {C(R^{\operatorname {\mathrm {ptf}}})}\to (A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}}$ is a restriction of the unique map $(A^{\widehat {u}})^\circ \to (A_0)_{\operatorname {\mathrm {perfd}},*}$ taken in Proposition 5.1. Similarly as above, the uniform completion of $A_0[1/p]$ is

(5.4) $$ \begin{align} A^{\widehat{u}} = A_0[1/p]^{\widehat{u}} = \widehat{R}[1/p]^{\widehat{u}} \cong R[1/p]^{\widehat{u}} \cong \widehat{C(R^{\operatorname{\mathrm{ptf}}})}[1/p]^{\widehat{u}}. \end{align} $$

The uniform completion $\widehat {C(R^{\operatorname {\mathrm {ptf}}})}[1/p]^{\widehat {u}}$ of $\widehat {C(R^{\operatorname {\mathrm {ptf}}})}[1/p]$ has a universality which gives a unique extension $A^{\widehat {u}} \to (A_0)_{\operatorname {\mathrm {perfd}}}[1/p]$ of $\varphi $ as follows (see Proposition 3.7):

Since $A_0$ is the p-adic completion of R, $\eta \colon A^{\widehat {u}}\to (A_0)_{\operatorname {\mathrm {perfd}}}[1/p]$ is a unique extension of $A_0 \to (A_0)_{\operatorname {\mathrm {perfd}}}^{\operatorname {\mathrm {ptf}}}$ . By Lemma 4.7 and the proof of Proposition 5.1, $\eta $ induces the unique map $(A^{\widehat {u}})^\circ \to (A_0)_{\operatorname {\mathrm {perfd}},*}$ taken in Proposition 5.1 and this extends $\varphi $ .

If R is p-torsion-free, $A_0 = \widehat {R}$ is also p-torsion-free and so is $(A_0)_{\operatorname {\mathrm {perfd}}}$ by [Reference Ma, Schwede, Tucker, Waldron and Witaszek19, Lem. A.2]. Then $\widehat {C(R^{\operatorname {\mathrm {ptf}}})} = \widehat {C(R)}$ is isomorphic to $(\widehat {R})_{\operatorname {\mathrm {perfd}}}$ .

Proof. First, the semiperfectoid ring $\widehat {R}$ has a surjective map from some integral perfectoid ring by the definition of semiperfectoid rings (Definition 2.4). Second, The perfectoidization $(\widehat {R})_{\operatorname {\mathrm {perfd}}}$ of $\widehat {R}$ is an (honest) integral perfectoid ring by [Reference Bhatt and Scholze8, Cor. 7.3 and Prop. 8.5]. Finally, the p-adic completion $\widehat {C(R^{\operatorname {\mathrm {ptf}}})}$ of the p-root closure $C(R^{\operatorname {\mathrm {ptf}}})$ is an integral perfectoid ring by Remark 5.8. So R satisfies all assumptions of Theorem 5.7, and this completes the proof.

Construction 6.1. Let $(R_0,\mathfrak {m},k)$ be a complete Noetherian local domain of mixed characteristic $(0, p)$ with perfect residue field k and let $p, x_2, \dots , x_n$ be any system of generators of the maximal ideal $\mathfrak {m}$ such that $p, x_2, \dots , x_d$ forms a system of parameters of $R_0$ . Choose compatible sequences of p-power roots

(6.1) $$ \begin{align} \{p^{1/p^j}\}_{j \ge 0},\{x_2^{1/p^j}\}_{j \ge 0},\ldots,\{x_n^{1/p^j}\}_{j \ge 0} \end{align} $$

inside the absolute integral closure $R_0^+$ . Set

(6.2) $$ \begin{align} R_{\infty} := \bigcup_{j \ge 0} R_0[p^{1/p^j},x_2^{1/p^j},\ldots,x_n^{1/p^j}] \subseteq R_0^+. \end{align} $$

Let $\widetilde {R}_{\infty }$ be the integral closure of $R_{\infty }$ in $R_{\infty }[1/p]$ and let $\widehat {\widetilde {R}}_{\infty }$ (resp., $\widehat {R}_{\infty }$ ) be the p-adic completion of $\widetilde {R}_{\infty }$ (resp., $R_{\infty }$ ).

By Cohen’s structure theorem, there exists a surjective map $S_0 \twoheadrightarrow R_0$ such that $S_0$ is a complete unramified regular local ring $W(k)[|t_2, \dots , t_n|]$ and $t_i$ maps to $x_i$ respectively. In particular, $R_0$ is a finite extension of a subring of $S_0$ . Then, proceeding as in [Reference Ishizuka and Shimomoto16], we have a surjective map $S_{\infty } \twoheadrightarrow R_{\infty }$ and its p-adic completion $\widehat {S}_{\infty } \to \widehat {R}_{\infty }$ . Remark that $\widehat {S}_{\infty }$ is an integral perfectoid ring which has a compatible sequence of p-power roots $\{p^{1/p^j}\}_{j \geq 0}$ of p. Therefore, $\widehat {R}_{\infty }$ is a semiperfectoid ring.

In [Reference Ishizuka and Shimomoto16], we show that $\widehat {C(R_{\infty })}$ and $\widehat {\widetilde {R}}_{\infty }$ are integral perfectoid rings and are $(pg)^{1/p^\infty }$ -almost flat and $(pg)^{1/p^\infty }$ -almost faithful $T_0$ -algebra where g is a non-zero element of $\widehat {R}_{\infty }$ that becomes a non-zero-divisor in $\widehat {\widetilde {R}}_{\infty }$ .

Proof. As above, $\widehat {R}_{\infty }$ is a semiperfectoid ring and has a compatible sequence of p-power roots $\{p^{1/p^j}\}_{j \geq 0}$ of p. So the second statement is already proved in Corollary 5.9.

In particular, the perfectoidization $(\widehat {R}_{\infty })_{\operatorname {\mathrm {perfd}}}$ is an honest integral perfectoid ring by [Reference Bhatt and Scholze8, Prop. 8.5]. Also $\widehat {\widetilde {R}}_{\infty }$ is an integral perfectoid ring by [Reference Ishizuka and Shimomoto16, Lem. 4.2]. Note that the proof of [Reference Ishizuka and Shimomoto16, Prop. 5.9] shows that the uniform completion of $\widehat {R}_{\infty }[1/p]$ is isomorphic to the uniform completion $R_{\infty }[1/p]^{\widehat {u}}$ of $R_{\infty }[1/p]$ . Since $\widehat {R}_{\infty }$ is a semiperfectoid ring, the uniform completion $\widehat {R}_{\infty }[1/p]^{\widehat {u}} \cong R_{\infty }[1/p]^{\widehat {u}}$ is a perfectoid Tate ring by Remark 5.5. In particular, we have $(R_{\infty }[1/p]^{\widehat {u}})^\circ = \widehat {\widetilde {R}}_{\infty }$ by Lemma 5.6 and deduce the first statement by Theorem 5.4.