Introduction
Topological Hochschild homology (THH), together with its induced variant topological cyclic homology (TC), has been one of the major tools to compute algebraic $K$-theory in recent years. It also is an important invariant in its own right, due to its connection to $p$-adic Hodge theory and crystalline cohomology [Reference Bhatt, Morrow and ScholzeBMS18, Reference Bhatt, Morrow and ScholzeBMS19].
The key point is that $\operatorname {THH}_*(R)$, as opposed to algebraic $K$-theory, can be completely identified for many rings $R$. Let us list some examples here.
(i) The most fundamental result in the field is Bökstedt periodicity, which states that $\operatorname {THH}_*(\mathbb {F}_p) = \mathbb {F}_p[x]$ for a class $x$ in degree two. This is also the input for the work of Bhatt, Morrow and Scholze [Reference Bhatt, Morrow and ScholzeBMS19].
(ii) The $p$-adic computation of $\operatorname {THH}_*(\mathbb {Z}_p)$ was also done by Bökstedt and eventually lead to the $p$-adic identification of $K_*(\mathbb {Z}_p)$, see [Reference Bökstedt and MadsenBM94, Reference RognesRog99].
(iii) More generally, Lindenstrauss and Madsen identify $\operatorname {THH}_*(A)$ $p$-adically for a complete discrete valuation ring (CDVR) $A$ with perfect residue field $k$ of characteristic $p$ [Reference Lindenstrauss and MadsenLM00]. This computation was one of the key inputs for Hesselholt and Madsen's seminal computation of $K$-theory of rings of integers in $p$-adic number fields.
(iv) Brun computed $\operatorname {THH}_*(\mathbb {Z}/p^{n})$ in [Reference BrunBru00]. This gives some information about $K_*(\mathbb {Z}/p^{n})$, which is still largely unknown, see [Reference BrunBru01].
In this paper, we revisit all the $\operatorname {THH}$ computations mentioned above from scratch, and give new, easier and more conceptual proofs. We go one step further and give a complete formula for $\operatorname {THH}_*(A')$ where $A' = A/\pi ^{k}$ is a quotient of a discrete valuation ring (DVR) $A$ with perfect residue field of characteristic $p$. We identify $\operatorname {THH}_*(A')$ with the homology of an explicitly described differential graded algebra (DGA); see Theorem 5.2. This for example recovers the computation of $\operatorname {THH}_*(\mathbb {Z}/p^{k})$ by Brun and also identifies the ring structure in this case (which was unknown so far). The result shows an interesting dichotomy depending on how large $k$ is when compared with the $p$-adic valuation of the derivative of the minimal polynomial of a uniformizer of $A$ (relative to the Witt vectors of the residue field), see § 6.
The main new idea employed in this paper is to first compute $\operatorname {THH}$ of $A$ and $A/\pi ^{k}$ relative to the spherical polynomial ring $\mathbb {S}[z]$. This relative $\operatorname {THH}$ of $A$ satisfies a form of Bökstedt periodicity, which was to the best of the authors’ knowledge first observed by Lurie, Scholze and Bhatt. It appeared in work of Bhatt, Morrow and Scholze [Reference Bhatt, Morrow and ScholzeBMS19] as well as in [Reference Antieau, Mathew and NikolausAMN18]. However, the maneuver of working relative to the uniformizer is much older in the algebraic context, for example in the theory of Breuil–Kisin modules [Reference KatoKat94, Reference BreuilBre99, Reference KisinKis09].Footnote 1
Finally, having computed THH relative to $\mathbb {S}[z]$ we use a descent style spectral sequence (see §§ 4 and 5) to recover the absolute $\operatorname {THH}$. In § 10 we also deduce the computation of logarithmic $\operatorname {THH}$ of CDVRs (due to Hesselholt and Madsen) from the computation of relative $\operatorname {THH}$ using a similar spectral sequence.
Conventions
We freely use the language of $\infty$-categories and spectra. For this we use [Reference LurieLur17] as our main reference. Specifically we use the theory of algebras and modules in the symmetric monoidal $\infty$-category of spectra as discussed in § 7.1 of [Reference LurieLur17]. The sphere spectrum is denoted by $\mathbb {S}$. For a commutative ring $R$ there is an associated commutative ring spectrum called the Eilenberg–MacLane spectrum of $R$ which we abusively also denote by $R$.
In this situation we have the ring spectra $\operatorname {HH}(R)$ (‘Hochschild homology’) and $\operatorname {THH}(R)$ (‘Topological Hochschild homology’) defined as
see [Reference LurieLur17, § 5.5 and Theorem 5.5.3.11] as well as [Reference Nikolaus and ScholzeNS18, § III.2]. We denote the homotopy groups of these spectra by $\operatorname {THH}_*(R)$ and $\operatorname {HH}_*(R)$. More generally there are relative versions for a ring $R$ over a base ring (spectrum) $S$ given as $\operatorname {THH}(R / S) = R \otimes _{R \otimes _{S} R} R$ and similar for $\operatorname {HH}$. Note that Hochschild homology as defined here is equivalent to $\operatorname {THH}(R/ \mathbb {Z})$ and is automatically fully derived. It thus agrees with what is classically called Shukla homology.
We denote the $p$-completion of the spectrum $\operatorname {THH}(R)$ by $\operatorname {THH}(R;\mathbb {Z}_p)$ and the homotopy groups accordingly by $\operatorname {THH}_*(R;\mathbb {Z}_p)$. Note that these are, in general, not the $p$-completions of the groups $\operatorname {THH}_*(R)$, but in the case that the groups $\operatorname {THH}_*(R)$ have bounded order of $p^{\infty }$-torsion this is true. There is the commonly used conflicting notation $\operatorname {THH}_*(R;R')$ for THH with coefficients in an $R$-algebra $R'$, given by he homotopy groups of $\operatorname {THH}(R) \otimes _R R'$. To avoid confusion we do not use the notation $\operatorname {THH}(R;R')$ in this paper.
Finally, there are useful equivalences
and some variants which are straightforward to prove and will be used frequently.
1. Bökstedt periodicity for $\mathbb {F}_p$
We want to give a proof of the fundamental result of Bökstedt, that THH of $\mathbb {F}_p$ is a polynomial ring on a degree-two generator. The proof presented here is closely related to the Thom spectrum proof in [Reference BlumbergBlu10] based on a result of Hopkins and Mahowald, but in our opinion it is more direct, see Appendix A for a precise discussion.
Let us first give a slightly more conceptual formulation of Bökstedt's result.
Theorem 1.1 (Bökstedt)
The spectrum $\operatorname {THH}(\mathbb {F}_p)$ is as an $\mathbb {E}_1$-algebra spectrum over $\mathbb {F}_p$ free on a generator $x$ in degree two, i.e. equivalent to $\mathbb {F}_p[\Omega S^{3}]$.
Here $\mathbb {F}_p[\Omega S^{3}]$ is the group ring of the $\mathbb {E}_1$-group $\Omega S^{3}$ over $\mathbb {F}_p$, i.e. the $\mathbb {F}_p$-homology $\mathbb {F}_p \otimes _\mathbb {S} \Sigma ^{\infty }_+ \Omega S^{3}$. The equivalence between the two formulations relies on the fact that $\Omega S^{3}$ is the free $\mathbb {E}_1$-group on $S^{2}$, where $S^{2}$ is considered as a pointed space. The latter fact follows from the fact, due to Boardman-Vogt and May, that the functor $\Omega$ induces an equivalence between pointed connected spaces and $\mathbb {E}_1$-groups, see [Reference LurieLur17, Theorem 5.2.6.10]. Thus, for any pointed space $X$ (here $X = S^{2}$) maps of $\mathbb {E}_1$-groups from $\Omega \Sigma X$ to any $\mathbb {E}_1$-group $G = \Omega Y$ are indeed given by maps of pointed spaces $\Sigma X \to Y$ or equivalently maps of pointed spaces $X \to \Omega Y= G$. A similar argument using $\Omega ^{2}$ and $\mathbb {E}_2$-groups shows that $\Omega ^{2} \Sigma ^{2} X$ is the free $\mathbb {E}_2$-group on any pointed space $X$.
Our proof of Theorem 1.1 relies on a structural result about the dual Steenrod algebra $\mathbb {F}_p \otimes _\mathbb {S} \mathbb {F}_p$. We consider this spectrum as an $\mathbb {F}_p$-algebra using the inclusion into the left factor.Footnote 2 It is an $\mathbb {E}_\infty$-algebra over $\mathbb {F}_p$, but has a universal description as an $\mathbb {E}_2$-algebra. This result seems to be known, at least to some experts, but we have not been able to find it written up in the literature.
Theorem 1.2 As an $\mathbb {E}_2$–$\mathbb {F}_p$-algebra, the spectrum $\mathbb {F}_p \otimes _\mathbb {S} \mathbb {F}_p$ is free on a single generator of degree $1$, i.e. it is as an $\mathbb {E}_2$-$\mathbb {F}_p$-algebra equivalent to $\mathbb {F}_p [\Omega ^{2} S^{3}]$.
We give a proof of Theorem 1.2 in the next section. However, let us first deduce Theorem 1.1 from it.
Proof of Theorem 1.1 We have an equivalence of $\mathbb {E}_1$-algebras
The third equivalence uses that $\mathbb {F}_p[-]$ sends products to tensor products and preserves colimits.
Remark 1.3 If one only wants to use that $\mathbb {F}_p \otimes _\mathbb {S} \mathbb {F}_p$ is free as an abstract $\mathbb {E}_2$-algebra and avoid space-level arguments, one can observe that in any pointed presentably symmetric monoidal $\infty$-category $\mathcal {C}$ one has for every object $X \in C$ an equivalence
This is proven in [Reference LurieLur17, Corollary 5.2.2.13] for $n=0$ and the case $n >0$ can be reduced to this case using Dunn additivity by replacing $\mathcal {C}$ with the $\infty$-category of augmented $\mathbb {E}_n$-algebras $\operatorname {Alg}_{\mathbb {E}_n}^{\operatorname {aug}}(\mathcal {C})$. This $\infty$-category satisfies the assumptions of [Reference LurieLur17, Corollary 5.2.2.13] by [Reference LurieLur17, Proposition 5.1.2.9].
1.1 Proof of Theorem 1.2
In order to prove this result we first recall from [Reference Bruner, May, McClure and SteinbergerBMMS86, III.3] that for every $\mathbb {E}_2$-ring spectrum $R$ over $\mathbb {F}_2$ there exist Dyer–Lashof operations
for $i \leq k+1$. Similarly, for an $\mathbb {E}_2$-algebra $R$ over $\mathbb {F}_p$ with odd $p$, there exist operations
for $2i \leq k +1$. They satisfy the usual relations, except that for the top operations (where $2i=k+1$) there are correction terms in terms of the Browder bracket. In particular, they are not generally additive. See [Reference Bruner, May, McClure and SteinbergerBMMS86, III.3, Theorem], where the top operations are denoted by $\xi _1$.
Note that for odd $p$, because $Q^{i} x = 0$ when $2i < |x|$ and $Q^{i} x = x^{p}$ when $2i=|x|$, the only interesting operations are the top operations $Q^{({|x|+1})/{2}} x$ for odd $|x|$. Similarly, for $p=2$, the only interesting operations are $Q^{|x|+1}x$. The iterates of these operations describe generators of the homotopy of the free $\mathbb {E}_2$-algebra.
Proposition 1.4 Let $R$ be the free $\mathbb {E}_2$-algebra over $\mathbb {F}_p$ on a generator in degree one. Then
(i) for $p=2$ we have
\[ \pi_*R \cong\mathbb{F}_2[x_1, x_2, \ldots], \]where $|x_i| = 2^{i} -1$; the element $x_{i+1}$ is given by $Q^{2^{i}}Q^{2^{i-1}} \ldots Q^{8}Q^{4}Q^{2} x_1$. In addition, $\beta x_i = x_{i-1}^{2}$.(ii) for $p$ odd we have
\[ \pi_*R \cong\Lambda_{\mathbb{F}_p}(y_0, y_1, \ldots) \otimes \mathbb{F}_p[z_1, z_2, \ldots], \]where $|y_i| = 2p^{i} - 1$, $|z_i|= 2p^{i} - 2$; the element $y_{i+1}$ is given by $Q^{p^{i}}\ldots Q^{p} Q^{1} y_0$, the element $z_i$ is given by $\beta Q^{p^{i}}\ldots Q^{p} Q^{1} y_0$.
Any $\mathbb {E}_2$-algebra $R$ over $\mathbb {F}_p$ whose homotopy ring together with the action of the Dyer–Lashof operations is of the above form, is also free on a generator in degree one.
Proof. The free $\mathbb {E}_2$-algebra over $\mathbb {F}_p$ on a generator in degree one is given by $\mathbb {F}_p[\Omega ^{2} S^{3}]$, see the discussion after Theorem 1.1. Thus, we are simply describing $H_*(\Omega ^{2} S^{3}; \mathbb {F}_p)$ with the Pontryagin ring structure. The first part is due to Araki and Kudo [Reference Kudo and ArakiKA56, Theorem 7.1], the second part is due to Dyer and Lashof [Reference Dyer and LashofDL62, Theorem 5.2]. These results are relatively straightforward computations using the Serre spectral sequence and the Kudo transgression theorem.
Now for the last statement assume that we have given any such $R$ and any non-trivial element $x_1 \in \pi _1(R)$. We get an induced map from the free algebra $\operatorname {Free}_{\mathbb {E}_2}(x_1) \to R$. As this map is an $\mathbb {E}_2$-map the induced map on homotopy groups is compatible with the ring structure as well as the indicated Dyer–Lashof operations. Everything is generated from $x_1$ under these operations in the same way, so the map is an equivalence.
Proof of Theorem 1.2 By Proposition 1.4 we only have to verify that the homotopy groups of $\mathbb {F}_p \otimes _{\mathbb {S}} \mathbb {F}_p$ have the correct ring structure and Dyer–Lashof operations. This is a classical calculation due to Milnor for the ring structure and Steinberger [Reference Bruner, May, McClure and SteinbergerBMMS86, Chapter 3, Theorems 2.2 and 2.3] for the Dyer–Lashof operations: at $p=2$, the generator $x_i$ corresponds to the Milnor basis element $\overline {\zeta }_i$, at $p$ odd $z_i$ corresponds to the element $\overline {\xi }_i$ and $y_i$ to $\overline {\tau }_i$.
Remark 1.5 We want to remark that Theorem 1.1 also implies Theorem 1.2. To see this, assume that Theorem 1.1 holds. We have that $\pi _1(\mathbb {F}_p \otimes _{\mathbb {S}} \mathbb {F}_p)$ is isomorphic to $\mathbb {F}_p$, generated by an element $b$. We can thus choose an $\mathbb {E}_2$-map
which induces an equivalence on $1$-types.Footnote 3 We can form the bar construction on these augmented $\mathbb {F}_p$-algebras, and the resulting map
is an equivalence on $\pi _2$, so by Theorem 1.1 it is an equivalence. Thus, Theorem 1.2 follows from the following lemma.
Lemma 1.6 Let $A\to B$ be a map of augmented connected $\mathbb {E}_1$-algebras over $\mathbb {F}_p$. Then if the map
is an equivalence, so is $A\to B$.
Proof. Assume $A\to B$ is not an equivalence. Let $d$ denote the connectivity of the cofiber of $A\to B$, i.e. $\pi _i(B/A) = 0$ for $i< d$, but $\pi _d(B/A)\neq 0$. The spectrum $\mathbb {F}_p\otimes _A \mathbb {F}_p$ admits a filtration (obtained by filtering the bar construction over $\mathbb {F}_p$ by its skeleta) whose associated graded is given in degree $n$ by $\Sigma ^{n} (A/\mathbb {F}_p)^{\otimes _{\mathbb {F}_p} n}$. Here $A/\mathbb {F}_p$ is the cofiber of $\mathbb {F}_p\to A$ and $1$-connective by assumption. The map
has $(d + 2n - 1)$-connective cofiber. Thus, the $(d+1)$-type of the cofiber of $\mathbb {F}_p\otimes _A \mathbb {F}_p \to \mathbb {F}_p\otimes _B \mathbb {F}_p$ receives no contribution from the terms for $n\geq 2$, and coincides with the $(d+1)$-type of the cofiber of $\Sigma (A/\mathbb {F}_p) \to \Sigma (B/\mathbb {F}_p)$, which is $\Sigma (B/A)$ and has non-vanishing $\pi _{d+1}$ by assumption. Thus, $\mathbb {F}_p\otimes _A \mathbb {F}_p \to \mathbb {F}_p\otimes _B \mathbb {F}_p$ cannot have been an equivalence.
2. Bökstedt periodicity for perfect rings
Now we also want to recover the well-known calculation of $\operatorname {THH}$ for a perfect $\mathbb {F}_p$-algebra $k$. This can directly be reduced to Bökstedt's theorem. Let us first note that there is a morphism $\operatorname {THH}(\mathbb {F}_p) \to \operatorname {THH}(k)$ induced from the map $\mathbb {F}_p \to k$. Moreover, the spectrum $\operatorname {THH}(k)$ is a $k$-module, so that we obtain an induced map
where the first term $k[x]$ denotes the free $\mathbb {E}_1$-algebra on a generator in degree two.
Proposition 2.1 For a perfect $\mathbb {F}_p$-algebra $k$ the map (1) is an equivalence.
Proof. Recall that for every perfect $\mathbb {F}_p$-algebra $k$ there is a $p$-complete $\mathbb {E}_\infty$-ring spectrum $\mathbb {S}_{W(k)}$, called the spherical Witt vectors, with $\pi _0(\mathbb {S}_{W(k)}) \cong W(k)$ and which is flat over $\mathbb {S}_p$, see, e.g., [Reference LurieLur18, Theorem 5.2.5 and Example 5.2.7]. It follows that the homology $\mathbb {Z} \otimes _{\mathbb {S}} \mathbb {S}_{W(k)}$ is given by $W(k)$ and, thus, the $\mathbb {F}_p$-homology $\mathbb {F}_p \otimes _\mathbb {S} \mathbb {S}_{W(k)}$ by $k$.
In particular we get that
where $\operatorname {HH}(k / \mathbb {F}_p)$ is the Hochschild homology of $k$ relative to $\mathbb {F}_p$. The result now follows once we know that this is given by $k$ concentrated in degree zero. This immediately follows from the vanishing of the cotangent complex of $k$ but we want to give a slightly different argument here.
It suffices to show that the positive dimensional groups $\operatorname {HH}_i(k/\mathbb {F}_p)$ are zero. To see this it is enough to show that for every $\mathbb {F}_p$-algebra $A$ the Frobenius $\varphi : A \to A$ induces the zero map $\operatorname {HH}_i(A/ \mathbb {F}_p) \to \operatorname {HH}_i(A / \mathbb {F}_p)$ for $i > 0$, because for $A = k$ perfect the Frobenius is also an isomorphism. Now for general $A$ this follows because $\operatorname {HH}(A/\mathbb {F}_p)$ is a simplicial commutative $\mathbb {F}_p$-algebra and the Frobenius $\varphi$ acts through the levelwise Frobenius. However, the levelwise Frobenius for every simplicial commutative $\mathbb {F}_p$-algebra induces the zero map in positive dimensional homotopy. This follows because for every simplicial commutative $\mathbb {F}_p$-algebra $R_\bullet$ the Frobenius can be factored as $\pi _n(R_\bullet ) \to \pi _n(R_\bullet )^{\times p} \to \pi _n(R_\bullet )$ where the latter map is induced by the multiplication $R_\bullet ^{\times p} \to R_\bullet$ considered as a map of underlying simplicial sets. For $n > 0$ it follows by an Eckmann–Hilton argument that the multiplication map $\pi _n(R_\bullet ) \times \pi _n(R_\bullet ) \to \pi _n(R_\bullet )$ is at the same time bilinear and linear, hence zero.
Remark 2.2 Note that the proof in particular shows that $\operatorname {THH}(\mathbb {S}_{W(k)})$ is $p$-adically equivalent to $\mathbb {S}_{W(k)}$ as this can be checked on $\mathbb {F}_p$-homology. We also write $\operatorname {THH}(\mathbb {S}_{W(k)};\mathbb {Z}_p)$ for the $p$-completion of $\operatorname {THH}(\mathbb {S}_{W(k)})$ so that we have
Integrally this is not quite the case, as one encounters contributions form the cotangent complex $L_{W(k)/\mathbb {Z}}$ which only vanishes after $p$-completion.
We also note that one can also deduce Proposition 2.1 from a statement similar to Theorem 1.2 which we want to list for completeness.
Proposition 2.3 For $k$ a perfect $\mathbb {F}_p$-algebra, we have
i.e. the spectrum $k\otimes _{\mathbb {S}_{W(k)}} k$ is as an $\mathbb {E}_2$-$k$-algebra free on a single generator in degree one.
Proof. As $\mathbb {S}_{W(k)} \otimes _{\mathbb {S}} \mathbb {F}_p \simeq k$, we have
so the statement follows from base-changing the statement over $\mathbb {F}_p$.
3. Bökstedt periodicity for CDVRs
Now we want to turn our attention to CDVRs. We determine their absolute $\operatorname {THH}$ later, but for the moment we focus on an analogue of Bökstedt's theorem which works relative to the $\mathbb {E}_\infty$-ring spectrum
For a CDVR $A$ we let $\pi$ be a uniformizer, i.e. a generator of the maximal ideal, and consider it as a $\mathbb {S}[z]$-algebra via $z\mapsto \pi$. Everything that follows will implicitly depend on such a choice. By assumption $A$ is complete with respect to $\pi$. As $\pi$ is a non-zero-divisor this is equivalent to $A$ being derived $\pi$-complete. Moreover, $A$ if has residue field of characteristic $p$, then $A$ is also (derived) $p$-complete because $p$ is contained in the maximal ideal.
The following result is, at least in mixed characteristic, due to Bhatt, Lurie, and Scholze, in a private communication; versions of it also appear in [Reference Bhatt, Morrow and ScholzeBMS19] and in [Reference Antieau, Mathew and NikolausAMN18].
Theorem 3.1 Let $A$ be a CDVR with perfect residue field $k$ of characteristic $p$. Then we have
for $x$ in degree two.
Proof. We distinguish the cases of equal and of mixed characteristic. In mixed characteristic we have the equation of ideals $(p) = (\pi ^{e})$ where $e$ is the ramification index. We deduce that $\operatorname {THH}(A / \mathbb {S}[z]; \mathbb {Z}_p)$ is $\pi$-complete because it is $p$-complete. We can write the mod $\pi$ reduction of the $A$-module spectrum $\operatorname {THH}(A/\mathbb {S}[z];\mathbb {Z}_p)$ as
where we in the third equivalence we used that the $\mathbb {S}[z]$-module structure on $\operatorname {THH}(A/\mathbb {S}[z];\mathbb {Z}_p)$ factors through the $A$-module structure, and in the fourth equivalence we used the fact that base-change from $\mathbb {S}[z]$-modules to $\mathbb {S}$-modules is symmetric monoidal and preserves colimits, thus commutes with relative $\operatorname {THH}$ (because it can be described as a cyclic bar construction).
By Proposition 2.1 this shows that the mod $\pi$ reduction of $\operatorname {THH}(A/\mathbb {S}[z];\mathbb {Z}_p)$ has homotopy groups given by an even-dimensional polynomial ring over $k$. Thus, from the long exact sequence associated with the cofiber sequence
we see that the odd homotopy groups of $\operatorname {THH}(A/ \mathbb {S}[z];\mathbb {Z}_p)$ have vanishing mod $\pi$ reduction. As they are also derived $\pi$-complete we deduce that they vanish. Then it follows that the even homotopy groups are $\pi$-torsion free. The result now follows by choosing a lift of the Bökstedt element $x$ to $\operatorname {THH}_2(A/ \mathbb {S}[z];\mathbb {Z}_p)$ and observing that the induced map
is an isomorphism modulo $\pi$ and, thus, an isomorphism.
If $A$ is of equal characteristic $p$ then $A$ is isomorphic to the formal power series ring $k[\kern -0.1em[{z}]\kern -0.1em]$. We consider the $\mathbb {E}_\infty$-ring $\mathbb {S}_{W(k)}[\kern -0.1em[{z}]\kern -0.1em]$ obtained as the $z$-completion of $\mathbb {S}_{W(k)}[z]$. Then we have an equivalence
which uses that $\mathbb {F}_p$ is of finite type over the sphere. As a result, we obtain an equivalence
Now in order to show the claim it suffices to show that $\operatorname {HH}( k[\kern -0.1em[{z}]\kern -0.1em] / \mathbb {F}_p[z])$ is concentrated in degree zero (where it is given by $k[\kern -0.1em[{z}]\kern -0.1em]$). In order to prove this we first note that $\mathbb {F}_p[z] \to k[\kern -0.1em[{z}]\kern -0.1em]$ is (derived) relatively perfect, i.e. the square
is a pushout of commutative ring spectra, where $\varphi$ is the Frobenius. This holds because $1,z,\ldots,z^{p-1}$ is basis for $\mathbb {F}_p[z]$ as a $\varphi (\mathbb {F}_p[z]) = \mathbb {F}_p[z^{p}]$-module and also for $k[\kern -0.1em[{z}]\kern -0.1em]$ as a $\varphi (k[\kern -0.1em[{z}]\kern -0.1em]) = k[\kern -0.1em[{z^{p}}]\kern -0.1em]$-module. Now the map
induced from the square (2) is an equivalence because the square is a pushout. We claim again, as in the proof of Proposition 2.1, that this map is zero for $i>0$. As $\varphi : \mathbb {F}_p[z] \to \mathbb {F}_p[z]$ is flat, we have
as right $\mathbb {F}_p[z]$-modules. The map
is induced up from the map $\pi _i\operatorname {HH}(k[\kern -0.1em[{z}]\kern -0.1em]/\mathbb {F}_p[z]) \to \pi _i\operatorname {HH}(k[\kern -0.1em[{z}]\kern -0.1em]/\mathbb {F}_p[z])$ induced by the Frobenius of $k[\kern -0.1em[{z}]\kern -0.1em]$, which is given by the Frobenius of the simplicial commutative ring $\operatorname {HH}(k[\kern -0.1em[{z}]\kern -0.1em] / \mathbb {F}_p[z])$. Thus, it is zero on positive-dimensional homotopy groups.
Remark 3.2 The isomorphism $\operatorname {THH}_*(A / \mathbb {S}[z]; \mathbb {Z}_p) \cong A[x]$ of Theorem 3.1 depends on the choice of generator $x$ of $\operatorname {THH}_2(A / \mathbb {S}[z]; \mathbb {Z}_p)$. The proof of Theorem 3.1 determines $x$ in mixed characteristic only modulo $\pi$. We show later that there is, in fact, a preferred choice of generator $x$ which then makes the isomorphism of Theorem 3.1 canonical, see Remark 4.3.
Remark 3.3 Let $A$ be a not necessarily complete DVR of mixed characteristic $(0,p)$ with perfect residue field. Then we have that
is an equivalence where $A_p$ is the $p$-completion of $A$. This is true for every ring $A$. Moreover, for a DVR the $p$-completion $A_p$ is the same as the completion of $A$ with respect to the maximal ideal so that Theorem 3.1 applies to yield that
For every prime $\ell \neq p$ we have that
because $\ell$ is invertible in $A$. If we can show that $\operatorname {THH}(A / \mathbb {S}[z])$ is finitely generated as an A-module, the Nakayama lemma implies that $\operatorname {THH}_*(A / \mathbb {S}[z]) \cong A[x]$ without $p$-completion. This holds, for example, for $A = \mathbb {Z}_{(p)}$ or more generally for localization of rings of integers at prime ideals. However, in general, one cannot control the rational homotopy type of $\operatorname {THH}(A/\mathbb {S}[z])$, as the example of $\mathbb {Z}_p$ shows, where we receive contributions from $\mathbb {Z}_p \otimes _\mathbb {Z} \mathbb {Z}_p$.
In equal characteristic we do not know how to compute $\operatorname {THH}_*(A/\mathbb {S}[z];\mathbb {Z}_p)$ if $A$ is not complete, because, in general, the cotangent complex $L_{A / \mathbb {F}_p[z]}$ does not vanish.Footnote 4
Remark 3.4 One can also deduce the mixed characteristic version of Theorem 3.1 from an analogue of Theorem 1.2 which under the same assumptions as Theorem 3.1 and in mixed characteristic states that $A\otimes _{\mathbb {S}_{W(k)}[z]} A$ is $p$-adically the free $\mathbb {E}_2$-algebra on a single generator in degree one.
We also want to remark that there are some equivalent ways of stating Theorem 3.1 which might be a bit more canonical from a certain point of view.
Proposition 3.5 In the situation of Theorem 3.1 the map $\mathbb {S}[z] \to A$ extends to a map $\mathbb {S}_{W(k)}[\kern -0.1em[{z}]\kern -0.1em] \to A$ by completeness of $A$. The induced canonical maps
are all equivalences.
Proof. For the upper four maps this follows from the equivalences
which can all be checked in $\mathbb {F}_p$-homology (see Remark 2.2 and the proof of Theorem 3.1). The last two vertical equivalences follows because $\operatorname {THH}(A / \mathbb {S}_{W(k)}[z])$ and $\operatorname {THH}(A / \mathbb {S}_{W(k)}[\kern -0.1em[{z}]\kern -0.1em])$ are already $p$-complete. If $A$ is of equal characteristic this is clear anyhow (and in the whole diagram we did not need the $p$-completions). In mixed characteristic this follows from Lemma 3.6, because $A$ is of finite type over $\mathbb {S}_{W(k)}[z]$ and over $\mathbb {S}_{W(k)}[\kern -0.1em[{z}]\kern -0.1em]$, which can be seen by the presentation
where $E$ is the minimal polynomial of the uniformizer $\pi$.
Recall that a connective ring spectrum $A$ over a connective, commutative ring spectrum $S$ is said to be of finite type if $A$ is as an $R$-module a filtered colimit of perfect modules along increasingly connective maps (i.e. has a cell structure with finite ‘skeleta’).
Lemma 3.6 If $A$ is $p$-complete and of finite type over $R$, then $\operatorname {THH}(A / R)$ is also $p$-complete.
Proof. We first observe that all tensor products $A \otimes _R \cdots \otimes _R A$ are of finite type over $A$ (say by action from the right) which follows inductively. Thus, they are $p$-complete. Finally, the $n$-truncation of $\operatorname {THH}(A / R)$ is equivalent to the $n$-truncation of the restriction of the cyclic bar construction to $\Delta ^{\mathrm {op}}_{\leq n+1}$. This colimit is finite and the stages are $p$-complete by the above.
We now consider quotients $A'$ of a CDVR $A$ as in Theorem 3.1. Every ideal is of the form $(\pi ^{k}) \subseteq A$ and thus $A' \cong A/\pi ^{k}$ for some $k \geq 1$.
Proposition 3.7 For a CDVR $A$ with residue field of characteristic $p$, and a quotient $A' = A/(\pi ^{k})$ of $A$, where $\pi$ denotes a choice of uniformizer, we have a canonical equivalence
and on homotopy groups we obtain
where $y$ is a divided power generator in degree two.
Proof. As $\pi$ is a non-zero divisor we can write $A' \simeq A \otimes _{\mathbb {S}[z]} (\mathbb {S}[z]/z^{k})$ where $\mathbb {S}[z] / z^{k}$ is the reduced suspension spectrum of the pointed monoid $\mathbb {N} / [k, \infty )$. Thus, we find
where in the last step we have used that $p$ is nilpotent in $A'$ and, thus, we are already $p$-complete. Finally $\operatorname {HH}( (\mathbb {Z}[z]/z^{k})/\mathbb {Z}[z])$ is given by a divided power algebra $(\mathbb {Z}[z]/z^{k})\langle y \rangle$. To see this we first observe that $\mathbb {Z}[z]/z^{k} \otimes _{\mathbb {Z}[z]} \mathbb {Z}[z]/z^{k}$ is given by the exterior algebra $\Lambda _{\mathbb {Z}[z]/z^{k}}(e)$ with $e$ in degree one. Then it follows that $\operatorname {HH}( (\mathbb {Z}[z]/z^{k})/\mathbb {Z}[z])$, which is the bar construction on that, is given by
This implies the claim.
4. Absolute $\operatorname {THH}$ for CDVRs
For $A$ a CDVR with perfect residue field of characteristic $p$ we have computed $\operatorname {THH}$ relative to $\mathbb {S}[z]$. In order to compute the absolute $\operatorname {THH}$ we are going to employ a spectral sequence which works very generally (see Proposition 7.1).
Proposition 4.1 For every commutative algebra $A$ (over $\mathbb {Z}$) with an element $\pi \in A$ considered as a $\mathbb {S}[z]$-algebra there is a canonical multiplicative, convergent spectral sequence
Proof. This is a special case of the spectral sequence of Proposition 7.1.
Now for $A$ a CDVR we want to use this spectral sequence to determine $\operatorname {THH}_*(A; \mathbb {Z}_p)$. From Theorem 3.1 we see that this spectral sequence takes the form
with $|x| = (2,0)$ and $|dz| = (0,1)$:
Using the multiplicative structure one only has to determine a single differential
In the equal characteristic case this has to vanish since $x$ can be chosen to lie in the image of the map $\operatorname {THH}(\mathbb {F}_p) \to \operatorname {THH}(A; \mathbb {Z}_p) \to \operatorname {THH}(A / \mathbb {S}[z]; \mathbb {Z}_p)$ and, thus, has to be a permanent cycle. Thus, the spectral sequence degenerates and we get $\operatorname {THH}_*(A) \cong A[x] \otimes \Lambda (dz)$ as there can not be any extension problems for degree reasons.Footnote 5
Let us now assume that $A$ is a CDVR of mixed characteristic. Once we have chosen a uniformizer $\pi$ we get a minimal polynomial $E(z) \in W(k)[z]$ which we normalize such that ${E(0) = p}$. Note that usually $E$ is taken to be monic, of the form $E(z) = z^{e} + p\theta (z)$. This differs from our convention by the unit $\theta (0)$.
Lemma 4.2 There is a choice of generator $x \in \operatorname {THH}_2(A / \mathbb {S}[z]; \mathbb {Z}_p)$ such that $d^{2}(x) = E'(\pi ) \,dz$.
Proof. Here $\operatorname {THH}(A;\mathbb {Z}_p)$ agrees with $\operatorname {THH}(A / \mathbb {S}_{W(k)}; \mathbb {Z}_p)$, because $\operatorname {THH}(\mathbb {S}_{W(k)};\mathbb {Z}_p) = \mathbb {S}_{W(k)}$. As $A$ is of finite type over $\mathbb {S}_{W(k)}$ we use Lemma 3.6 to see that $\operatorname {THH}(A / \mathbb {S}_{W(k)}; \mathbb {Z}_p) \simeq \operatorname {THH}(A/\mathbb {S}_{W(k)})$. For connectivity reasons,
As $A \cong W(k)[z]/E(z)$, we have
Comparing with the spectral sequence, this means that the image of $d^{2}: E^{2}_{2,0}\to E^{2}_{0,1}$ is precisely the submodule of $A\{dz\}$ generated by $E'(\pi ) \,dz$. As $A$ is a domain, any two generators of a principal ideal differ by a unit and, thus, for any generator $x$ in degree $(2,0)$, $d^{2}(x)$ differs from $E'(\pi ) \,dz$ by a unit. In particular, we can choose $x$ such that $d^{2}(x) = E'(\pi ) \,dz$.
Remark 4.3 The generator $x\in \operatorname {THH}_2(A / \mathbb {S}[z]; \mathbb {Z}_p)$ determined by Lemma 4.2 maps under base-change along $\mathbb {S}[z]\to \mathbb {S}$ to a generator of $\operatorname {THH}_2(A/\pi ; \mathbb {Z}_p) \cong \operatorname {THH}_2(k)$. The choice of normalization of $E$ with $E(0) = p$ is chosen such that this is compatible with the generator obtained from the generator of $\operatorname {THH}_2(\mathbb {F}_p)$ under the map $\operatorname {THH}_2(\mathbb {F}_p)\to \operatorname {THH}_2(k)$ induced by $\mathbb {F}_p\to k$.
Lemma 4.2 implies that $\operatorname {THH}_*(A, \mathbb {Z}_p)$ is isomorphic to the homology of the DGA
with differential $\partial x = E'(\pi )\cdot d\pi$ and $\partial (d\pi ) = 0$ as there are no multiplicative extensions possible. Here we have named the element detected by $dz$ by $d\pi$ as it is given by the Connes operator $d: \operatorname {THH}_*(A, \mathbb {Z}_p) \to \operatorname {THH}_*(A, \mathbb {Z}_p)$ applied to the uniformizer $\pi$. This follows from the identification of the degree $1$ part with $\Omega ^{1}_{A/W(k)}$ as in the proof of Lemma 4.2. We warn the reader that we have obtained this description for $\operatorname {THH}_*(A; \mathbb {Z}_p)$ from the relative $\operatorname {THH}$ which depends on a choice of uniformizer. As a result the DGA description is only natural in maps that preserve the chosen uniformizer.
The homology of this DGA can easily be additively evaluated to yield the following result, which was first obtained in [Reference Lindenstrauss and MadsenLM00, Theorem 5.1], but with completely different methods.
Theorem 4.4 (Lindenstrauss–Madsen)
For a CDVR $A$ of mixed characteristic $(0,p)$ with perfect residue field we have non-natural isomorphismsFootnote 6
where $\pi$ is a uniformizer with minimal polynomial $E$.
In this case the multiplicative structure is necessarily trivial, so that we do not really get more information from the DGA description. However, we also obtain a spectral sequence analogous to that of Proposition 4.1 for $p$-completed $\operatorname {THH}$ of $A$ with coefficients in a discrete $A$-algebra $A'$, which is $\operatorname {THH}(A;\mathbb {Z}_p) \otimes _A A'$. This takes the same form, just base-changed to $A'$. Thus, we obtain the following result, which was of course also known before.
Proposition 4.5 For a CDVR $A$ of mixed characteristic and any map of commutative algebras $A \to A'$ we have a non-natural ring isomorphism
with $\partial x = E'(x)\,d\pi$ and $\partial (d\pi )=0$.
5. Absolute $\operatorname {THH}$ for quotients of DVRs
Now we return to the case of quotients of DVRs. Thus, let $A' = A/\mathfrak {m}^{k} \cong A/\pi ^{k}$ where $A$ is a DVR with perfect residue field of characteristic $p$. Recall that in Proposition 3.7 we have shown that
We want to consider the spectral sequence of Proposition 4.1, which in this case takes the form
with $|x| = (2,0)$, $|y| = (2,0)$ and $|dz| = (0,1)$:
Here we write $y^{[n]}$ for the $n$th divided power of $y$. The reader should think of $y^{[n]}$ as ‘$y^{n}/n!$’.
Lemma 5.1 We can choose the generator $y$ and its divided powers in such a way that in the associated spectral sequence, $d^{2}(y^{[i]}) = k \pi ^{k-1} \cdot y^{[i-1]} \,dz$. In particular, the differential is a PD-derivation, i.e. satisfies $d^{2}(y^{[i+1]}) = d^{2}(y) y^{[i]}$ for all $i \geq 0$.Footnote 7
Proof. The construction of the spectral sequence of Proposition 4.1 (given in the proof of Proposition 7.1) applies generally to any $\operatorname {HH}(\mathbb {Z}[z]/\mathbb {Z})$-module $M$ to produce a spectral sequence
As we can write $A' \simeq A\otimes _{\mathbb {S}[z]} (\mathbb {S}[z]/z^{k})$, we have
As we also have a $\mathbb {Z}$-module structure on $\operatorname {THH}(A)$, we can further identify this with
where the $\operatorname {HH}(\mathbb {Z}[z])$-action on $\operatorname {THH}(A)$ is somewhat curious, and arises simply as a combination of the $\mathbb {Z}$-action and the $\operatorname {THH}(\mathbb {S}[z])$-action on $\operatorname {THH}(A)$.
Thus, we have a map of $\operatorname {HH}(\mathbb {Z}[z])$-algebras $\operatorname {HH}(\mathbb {Z}[z]/z^{k}) \to \operatorname {THH}(A')$, and thus a multiplicative map of the corresponding spectral sequences. The spectral sequence for $\operatorname {HH}(\mathbb {Z}[z]/z^{k})$ is of the form
We have that $\operatorname {HH}_*((\mathbb {Z}[z]/z^{k}) / \mathbb {Z}[z]) \simeq (\mathbb {Z}[z]/z^{k})\langle y \rangle$. As the spectral sequence is multiplicative, we obtain
and because the $E^{2}$-page consists of torsion-free abelian groups, we can divide this equation by $i!$ to obtain
i.e. the differential is compatible with the divided power structure.
Now, $\operatorname {HH}_1((\mathbb {Z}[z]/z^{k}) / \mathbb {Z}[z]) \cong \Omega ^{1}_{(\mathbb {Z}[z]/z^{k})/\mathbb {Z}[z]} \cong (\mathbb {Z}[z]/z^{k})\{dz\} / kz^{k-1}\,dz$. In particular, in the spectral sequence
$d^{2}(y)$ is a unit multiple of $kz^{k-1}\,dz$. We can thus choose our generator $y$ of $\operatorname {HH}_2((\mathbb {Z}[z]/z^{k}) / \mathbb {Z}[z])$ in such a way that $d^{2}(y) = k z^{k-1} \,dz$, and by compatibility with divided powers, $d^{2}(y^{[i]}) = k z^{k-1} \cdot y^{[i-1]} \,dz$. After base-changing along $\mathbb {Z}[z]\to A$, this implies the claim.
Theorem 5.2 Let $A' \cong A/\pi ^{k}$ be a quotient of a DVR $A$ with perfect residue field of characteristic $p$. Then $\operatorname {THH}_*(A')$ is as a ring non-naturally isomorphic to the homology of the DGA
with differential $\partial$ given by $\partial (d\pi ) = 0$ and $\partial (y^{[i]}) = k \pi ^{k-1} \cdot y^{[i-1]} \,d\pi$ and
Here $\pi \in A$ is a uniformizer and $E$ its minimal polynomial.
Proof. This follows immediately from Lemma 5.1 together with the fact that there are no extension problems for degree reasons.
6. Evaluation of the result
In this section we want to make the results of Theorem 5.2 explicit. We start by considering the case of the $p$-adic integers $\mathbb {Z}_p$, in which Theorem 5.2 reduces additively to Brun's result, but gives some more multiplicative information. We note that all the computations in this section depend on the presentation $A' = A/\pi ^{k}$ and are, in particular, highly non-natural in $A'$.
Example 6.1 We start by discussing the case $A = \mathbb {Z}_p$ and $k \geq 2$. We pick the uniformizer $\pi =p$. The minimal polynomial is $E(z)=z-p$, and $A' = \mathbb {Z}/p^{k}$. The resulting groups $\operatorname {THH}_*(\mathbb {Z}/p^{k})$ were additively computed by Brun [Reference BrunBru00].
We have $\partial (y^{[i]}) = kp^{k-1} y^{[i-1]} \,d\pi$, and because the minimal polynomial is given by $z-p$ we obtain $\partial x = d\pi$. If $k\geq 2$, then $y' = y-k p^{k-1} x$ still has divided powers, given by
which makes sense because $v_p(l!) < {l}/({p-1})\leq l(k-1)$ by Lemma 6.6.
Now $\partial ((y')^{[i]}) = 0$, and we get a map of DGAs
which is an isomorphism by a straightforward filtration argument. By Proposition 4.5, the homology of $((\mathbb {Z}/p^{k})[x] \otimes \Lambda (d\pi ), \partial )$ coincides with $\pi _*(\operatorname {THH}(\mathbb {Z}_p)\otimes _{\mathbb {Z}_p} \mathbb {Z}/p^{k})$. Thus, applying the Künneth theorem we obtain
as rings. Concretely, we obtain
Thus, in the case $k\geq 2$, we can replace the divided power generator of our DGA by one in the kernel of $\partial$. We contrast this with the case $k=1$. In this case, of course, we expect to recover Bökstedt's result $\operatorname {THH}_*(\mathbb {Z}/p) \cong (\mathbb {Z}/p)[x]$, but it is nevertheless interesting to analyze this result in terms of Theorem 5.2 and observe how this differs from Example 6.1.
Example 6.2 For $A=\mathbb {Z}_p$ with uniformizer $p$ and $k=1$, i.e. $A'=\mathbb {Z}/p$, we have $\partial x = d\pi$ and $\partial y = d\pi$. Here, we can set $x' = x - y$ to obtain an isomorphism of DGAs
As $\partial y^{[i]} = y^{[i-1]}\,dz$, and thus the homology of the second factor is just $\mathbb {Z}/p$ in degree zero, Künneth applies to show that $\operatorname {THH}_*(\mathbb {Z}/p) \cong (\mathbb {Z}/p)[x']$.
The two qualitatively different behaviors illustrated in Examples 6.1 and 6.2 also appear in the general case: for sufficiently big $k$, we can modify the divided power generator $y$ to a $y'$ that splits off, and obtain a description in terms of $\operatorname {THH}(A; A')$ (Proposition 6.7). For sufficiently small $k$, we can modify the polynomial generator to an $x'$ that splits off, and obtain a description in terms of $\operatorname {HH}(A')$ (Proposition 6.4). In the general case, as opposed to the case of the integers, these two cases do not cover all possibilities, and for $k$ in a certain region the homology groups of the DGA of Theorem 5.2 are possibly without a clean closed form description.
Recall that, in the DGA of Theorem 5.2, we have $\partial x = E'(\pi )\,d\pi$ and $\partial y = k\pi ^{k-1}\,d\pi$. Keep in mind that the description depends on a choice of uniformizer and Eisenstein polynomial, but then everything is unambiguously defined, in particular the elements $x$ and $y$. The behavior of the DGA depends on which of the two coefficients has greater valuation.
Lemma 6.3 In mixed characteristic, we have
(i) If $p|k$ and $\pi ^{k} | E'(\pi )$, we can take as generators
\[ \operatorname{THH}_2(A') \cong A'\{x,y\}. \](ii) If $p|k$ and $E'(\pi ) | \pi ^{k}$, we can take as generators
\[ \operatorname{THH}_2(A') \cong A'\{y\} \oplus (A/E'(\pi))\biggl\{\frac{\pi^{k}}{E'(\pi)}x\biggr\}. \](iii) If $p\nmid k$ and $E'(\pi ) | \pi ^{k-1}$, we can take as generators
\[ \operatorname{THH}_2(A') \cong A'\biggl\{y'= y - \frac{k\pi^{k-1}}{E'(\pi)} x\biggr\} \oplus (A/E'(\pi))\biggl\{\frac{\pi^{k}}{E'(\pi)} x\biggr\}. \](iv) If $p\nmid k$ and $\pi ^{k-1} | E'(\pi )$, we can take as generators
\[ \operatorname{THH}_2(A') \cong A'\biggl\{x'= x - \frac{E'(\pi)}{k\pi^{k-1}} y\biggr\} \oplus (A/\pi^{k-1})\{\pi y\}. \]
Proof. By Theorem 5.2, $\operatorname {THH}_2(A')$ is isomorphic to the kernel of the map
where $\partial x = E'(\pi )\,d\pi$, $\partial y = k\pi ^{k-1} \,d\pi$. In the first case, both coefficients vanish in $A'$, because both are divisible by $\pi ^{k}$, so in that case the kernel is free on $x,y$ as claimed.
In the second case, $\partial y = 0$ in $A'$, and $\partial x\in A'\{d\pi \}$ has annihilator ideal generated by ${\pi ^{k}}/{E'(\pi )}$. Thus, the kernel is generated by $y$ and $({\pi ^{k}}/{E'(\pi )})x$, and they generate a submodule of the form $A'\oplus (A/E'(\pi ))$.
In the third case, observe first that the indicated $y'$ and $x$ together form another basis of $A'\{x,y\}$. We have $\partial y' = 0$, so it is contained in the kernel. The annihilator ideal of $\partial x \in A'\{d\pi \}$ is as in the second case, so we again see that the kernel is of the form $A'\oplus (A/E'(\pi ))$, but this time the first summand is generated by $y'$.
In the fourth case, we again observe that the indicated $x'$ and $y$ form another basis of $A'\{x,y\}$, and $\partial x' = 0$. The annihilator ideal of $\partial y\in A'\{d\pi \}$ is (due to $p\nmid k$) generated by $\pi$, and so the kernel is generated by $x'$ and $\pi y$. They generate a submodule of the form $A' \oplus (A/\pi ^{k-1})$.
We now want to discuss the structure of $\operatorname {THH}_*(A')$ in the cases appearing in Lemma 6.3. We start with the simplest case, which is analogous to Example 6.2.
Proposition 6.4 Assume we are in the situation of Theorem 5.2 and that either $A$ is of equal characteristic, or $A$ is of mixed characteristic and we are in case (i) or (iv) of Lemma 6.3, i.e. $p|k$ and $\pi ^{k} | E'(\pi )$, or $p\nmid k$ and $\pi ^{k-1} | E'(\pi )$. Then, we have
which evaluates additively to
Proof. We set $x'=x$ if $A$ is of equal characteristic or if $p|k$ and $\pi ^{k} | E'(\pi )$, and $x' = x - ({E'(\pi )}/{k\pi ^{k-1}})y$ if $p\nmid k$ and $\pi ^{k-1} | E'(\pi )$. Then $\partial x'=0$. We obtain a map of DGAs
which is an isomorphism by a straightforward filtration argument. By Künneth, we obtain an isomorphism
The additive description of the homology is easily seen from the fact that $\partial y^{[i]} = k\pi ^{k-1} (d\pi ) y^{[i-1]}$.
Remark 6.5 In fact, we can identify $H_*(A'\langle y \rangle \otimes \Lambda (d\pi ), \partial )$ with the Hochschild homology $\operatorname {HH}_*(\mathbb {Z}[z]/z^{k}\otimes A' / A')$. Compare with § 8.
Essentially, the takeaway of Proposition 6.4 is that in cases (i) and (iv) of Lemma 6.3 we can modify the polynomial generator $x$ to a cycle which splits a polynomial factor off $\operatorname {THH}(A')$.
One would hope that, complementarily, in cases (ii) and (iii), we can split off a divided power factor. This is only true under more restrictive conditions. To formulate those, we require the following lemma on the valuation of factorials.
Lemma 6.6 (Legendre)
For a natural number $l \geq 1$ and a prime $p$ we have
Proof. We count how often $p$ divides $l!$. Every multiple of $p$ not greater than $l$ provides a factor of $p$, every multiple of $p^{2}$ provides an additional factor of $p$, and so on. We obtain the following formula, due to Legendre:
where $\lfloor -\rfloor$ denotes rounding down to the nearest integer. In particular,
Proposition 6.7 Assume we are in the situation of Theorem 5.2, and for $A$ of equal characteristic $p|k$, and for $A$ of mixed characteristic either $p|k$ (i.e. we are in case (i) or (ii) of Lemma 6.3), or we have the following strengthening of case (iii):
Then we have an isomorphism of rings
In particular, we get additively
Proof. If $p|k$, all $y^{[i]}$ are cycles, and we set $y' := y$. If
we set $y' = y - ({k\pi ^{k-1}}/{E'(\pi )})x$. In either case, $(y')$ admits divided powers, defined in the first case just by $(y')^{[i]} = y^{[i]}$, and in the second case by
which is well-defined because
by assumption and Lemma 6.6.
We obtain a map of DGAs
which is an isomorphism by a straightforward filtration argument. By Proposition 4.5 and Künneth, we then obtain
Finally, we want to illustrate that the case ‘in between’ Propositions 6.7 and 6.4 is more complicated and probably does not admit a simple uniform description.
Example 6.8 For a mixed characteristic CDVR $A$ with perfect residue field and $A'=A/\mathfrak {m}^{k}=A/\pi ^{k}$, Theorem 5.2 implies that the even-degree part of $\operatorname {THH}_*(A')$ is given by the kernel of $\partial$ in the DGA $(A'[x]\langle y\rangle \otimes \Lambda (d\pi ),\partial )$. We can thus consider $\bigoplus \operatorname {THH}_{2n}(A')$ as a subring of $A'[x]\langle y\rangle$.
Suppose we are in the situation of case (iii) of Lemma 6.3. Then a basis for $\operatorname {THH}_2(A')$ is given by
Now suppose the valuations of the coefficients ${k\pi ^{k-1}}/{E'(\pi )}$ and ${\pi ^{k}}/{E'(\pi )}$ are positive, but small, say smaller than $ {1}/{p}$. Then observe that
in particular, under our assumptions, $(y- ({k\pi ^{k-1}}/{E'(\pi )}) x)^{p}$ is divisible by $\pi$ but not $p$. Similarly,
is divisible by $\pi$ but not $p$. Thus, both of our generators of $\operatorname {THH}_2(A')$ are nilpotent, but cannot admit divided powers. It is not hard to see that this holds more generally for any element of $\operatorname {THH}_2(A')$ that is non-zero mod $\pi$. Thus, in this situation, $\operatorname {THH}_*(A')$ cannot admit a description similar to Proposition 6.4 or 6.7.
One example for $A'$ fulfilling the requirements used here is given by $A=\mathbb {Z}_p[\sqrt [e]{p}]$ with uniformizer $\pi =\sqrt [e]{p}$, and $k=e+1$, as long as $p\nmid e$, $k$ and $e>2p$.
7. The general spectral sequences
We now want to establish a spectral sequence to compute absolute $\operatorname {THH}$ from relative ones of which Proposition 4.1 is a special case. This will come in two slightly different flavors. We let $R \to A$ be a map of commutative rings and let $\mathbb {S}_R$ be a lift of $R$ to the sphere, i.e. a commutative ring spectrum with an equivalence
The example that will lead to the spectral sequence of Proposition 4.1 is $R = \mathbb {Z}[z]$ and $\mathbb {S}_R = \mathbb {S}[z]$.
Recall that for every commutative ring $R$ we can form the derived de Rham complex $L\Omega _{R/\mathbb {Z}}$, which has a filtration whose associated graded is in degree $* = i$ given by a shift of the non-abelian derived functor of the $i$-term of the de Rham complex $\Omega ^{i}_{R/\mathbb {Z}}$ (considered as a functor in $R$). Concretely this is done by simplicially resolving $R$ by polynomial algebras $\mathbb {Z}[x_1,\ldots,x_k]$, taking $\Omega ^{i}_{\bullet /\mathbb {Z}}$ levelwise and considering the result via Dold–Kan as an object of $\mathcal {D}(\mathbb {Z})$. This derived functor agrees with the $i$th derived exterior power $\Lambda ^{i} L_{R/\mathbb {Z}}$ of the cotangent complex $L_{R/\mathbb {Z}}$. For $R$ smooth over $\mathbb {Z}$ this just recovers the usual terms in the de Rham complex. In general one should be aware that $L\Omega _{R/\mathbb {Z}}$ is a filtered chain complex, hence has two degrees, one homological and one filtration degree. We only need its associated graded $L\Omega ^{*}_{R/\mathbb {Z}}$ which is a graded chain complex. We warn the reader that the homological direction comes from deriving and has nothing to do with the de Rham differential.
Proposition 7.1 In the situation described above there are two canonical multiplicative, convergent spectral sequences
Here we use homological Serre grading, i.e. the displayed bigraded ring is the $E_2$-page and the $d^{r}$-differential has $(i,j)$-bidegree $(-r, r-1)$. A similar spectral sequence with all terms $p$-completed (including the tensor products) exists as well.
Proof. We consider the lax symmetric monoidal functor
where we have used the equivalence $\operatorname {HH}(R/\mathbb {Z}) \simeq \operatorname {THH}(\mathbb {S}_R) \otimes _\mathbb {S} \mathbb {Z}$ to obtain the $\operatorname {HH}(R/\mathbb {Z})$-module structure on $\operatorname {THH}(A)$.
Now we filter $\operatorname {HH}(R/\mathbb {Z})$ by two different filtrations: either by the Whitehead tower
or by the Hochschild–Kostant–Rosenberg (HKR) filtration [Reference Nikolaus and ScholzeNS18, Proposition IV.4.1]
The HKR filtration is, in fact, the derived version of the Whitehead tower, in particular for $R$ smooth (or more generally ind-smooth) the filtrations agree. Both filtrations are complete and multiplicative, in particular they are filtrations through $\operatorname {HH}(R/\mathbb {Z})$ modules. On the associated graded pieces the $\operatorname {HH}(R/\mathbb {Z})$-module structure factors through the map $\operatorname {HH}(R/\mathbb {Z}) \to R$ of ring spectra. This is obvious for the Whitehead tower and thus also follows for the HKR filtration. Thus the graded pieces are only $R$-modules and as such given by $\operatorname {HH}_i(R)$ in the first case and by $\Lambda ^{j} L_{R/ \mathbb {Z}}$ in the second case.
After applying the functor (3) to this filtration we obtain two multiplicative filtrations of $\operatorname {THH}(A)$:
which are complete because the connectivity of the pieces tends to infinity. Let us identify the associated gradeds for the HKR filtration, the case of the Whitehead tower works the same:
Thus by the standard construction we obtain conditionally convergent, multiplicative spectral sequences which are concentrated in a single quadrant and, therefore, convergent.
If $R$ is smooth (or more generally ind-smooth) over $\mathbb {Z}$ then the spectral sequences of Proposition 7.1 agree and take the form
In general, the HKR spectral sequence seems to be slightly more useful even though the other one looks easier (at least easier to state). We explain the difference in the example of a quotient of a DVR in § 8 where $R = \mathbb {Z}[z]/z^{k}$ and $\mathbb {S}_R = \mathbb {S}[z]/z^{k}$.
Remark 7.2 With basically the same construction as in Proposition 7.1 (and if $R\otimes _\mathbb {Z} A$ is discrete in the first case) one obtains variants of these spectral sequences which take the form
These spectral sequences agree with those of Proposition 7.1 as soon as $A$ is flat over $R$ or $R$ is smooth over $\mathbb {Z}$, which covers all cases of interest for us. These modified spectral sequences are probably, in general, the ‘correct’ ones, but we have decided to state Proposition 7.1 in the more basic form.
Finally we end this section by constructing a slightly different spectral sequence in the situation of a map of rings $A \to A'$. This was constructed in Theorem 3.1 of [Reference LindenstraussLin00]. See also Brun [Reference BrunBru00], which contains the special case $A=\mathbb {Z}_p$. We explain how it was used by Brun to compute $\operatorname {THH}_*(\mathbb {Z}/ p^{n})$ in the next section and compare that approach with ours.
Proposition 7.3 In general, for a map of rings $A \to A'$ there is a multiplicative, convergent spectral sequence
Proof. We filter $\operatorname {THH}(A) \otimes _A A' =: T$ by its Whitehead tower $\tau _{\geq \bullet } T$ and consider the associated filtration
This filtration is multiplicative, complete and the colimit is given by $\operatorname {THH}(A')$. The associated graded is given by
where we have again used various base change formulas for $\operatorname {THH}$.
8. Comparison of spectral sequences
Let us consider the situation of § 5, i.e. $A' = A/\pi ^{k}$ is a quotient of a DVR $A$ with perfect residue field of characteristic $p$. We want to compare four different multiplicative spectral sequences converging to $\operatorname {THH}(A')$ that can be used in such a situation. They all have absolutely isomorphic (virtual) $E^{0}$-pages give by $A[x]\langle y \rangle \otimes \Lambda (dz)$ but totally different grading and differential structure.
(i) In § 5 we have constructed a spectral sequence which ultimately identifies $\operatorname {THH}_*(A')$ as the homology of a DGA $(A'[x]\langle y\rangle \otimes \Lambda (d\pi ),\partial )$, see Theorem 5.2. This spectral sequence takes the form
i.e. we have both $x$ and $y$ along the lower edge, and they both support differentials hitting certain multiples of $dz$ (here $dz$ corresponds to $d\pi$). The main point is that it suffices to determine the differential on $x$ and $y$ and the rest follows using multiplicative and divided power structures. There is no space for higher differentials.
(ii) We now consider Brun's spectral sequence, see Proposition 7.3. It also computes $\operatorname {THH}_*(A')$ but has $E^{2}$-term
As $\operatorname {HH}_*(A'/A)$ is a divided power algebra $A'\langle y\rangle$, and $\pi _*( \operatorname {THH}_*(A) \otimes _A A')$ can be computed as the homology of the DGA $(A'[x]\otimes \Lambda (dz),\partial )$ by Proposition 4.5, one can introduce a virtual zeroth page of the form
We interpret $\partial$ as the $d^{0}$-differentialFootnote 8 and obtain the following picture:
This spectral sequence behaves well and degenerates in the ‘big $k$’ case discussed in Proposition 6.7, because then we have divided power elements $(y')^{[i]}\in \operatorname {THH}_*(A')$ that are detected by the $y^{[i]}$, but this is not obvious from this spectral sequence, and Brun [Reference BrunBru00] has to do serious work to determine its structure in the case $A'=\mathbb {Z}/p^{k}$ for $k\geq 2$.
In fact, for $A'=\mathbb {Z}/p^{k}$ with $k=1$ the spectral sequence becomes highly non-trivial. After $d^{0}$, determined by $d^{0}(x) = dz$, the leftmost column consists of elements of the form $x^{ip}$ and $x^{ip-1} \,dz$. From Example 6.2, we know that $\operatorname {THH}_*(\mathbb {F}_p)$ is polynomial on $x' = x-y$. This is detected as $y$ in this spectral sequence. As $y$ is a divided power generator, its $p$th power is zero on the $E_\infty$-page. However, $p^{k-1}(x-y)^{p} = p^{k-1}x^{p}$ and, thus, there is a multiplicative extension. In addition, the elements $x^{kp-1} \,dz$ and the divided powers of $y$ cannot exist on the $E_\infty$-page, so there are also longer differentials.
Although these phenomena might seem like a pathology in the case $A=\mathbb {Z}_p$ (after all, we knew $\operatorname {THH}(\mathbb {Z}/p)$ before) qualitatively, they generally appear whenever we are not in the ‘big $k$’ case discussed in Proposition 6.4.
(iii) We can also consider the first spectral sequence constructed in Proposition 7.1, which takes the form
One obtains $\operatorname {THH}_*(A' / (\mathbb {S}[z]/z^{k}) ) \cong A'[x]$ by a version of Theorem 3.1, and $\operatorname {HH}((A'[z]/z^{k})/A')$ is computed as the homology of the DGA $(A'\langle y\rangle \otimes \Lambda (dz),\partial )$ where $y$ sits in degree two and $dz$ in degree one. Thus we again introduce a virtual $E^{0}$-term
and consider $\partial$ as a $d^{0}$ differential. Then the spectral sequence visually looks as follows:
This spectral sequence behaves well and degenerates in the ‘small $k$’ case discussed in Proposition 6.4, because then we have a polynomial generator $x'\in \operatorname {THH}_*(A')$ whose powers are detected by the $x^{i}$. If we are not in this case, we generally have non-trivial extensions. For example, let $A'$ be chosen such that $p\nmid k$, and $\pi E'(\pi ) | \pi ^{k-1}$. In this case, $\operatorname {THH}_2(A')$, using Theorem 5.2, is of the form
with
In this spectral sequence, the $E^{\infty }$ page consists in total degree $2$ of a copy of $(A/\pi ^{k-1})\{\pi y\}$ in degree $(0,2)$, and a copy of $(A/\pi E'(\pi ))\{({\pi ^{k-1}}/{E'(\pi )})x\}$ in degree $(2,0)$. The element $y'\in \operatorname {THH}_2(A')$ is detected as a generator of the degree $(2,0)$ part, but it is not actually annihilated by $\pi E'(\pi )$. Rather, $\pi E'(\pi )y'$ agrees with $\pi E'(\pi )y$, detected as a $E'(\pi )$-multiple of the generator in degree $(0,2)$ and non-zero under our assumption $\pi E'(\pi ) | k\pi ^{k-1}$.
(iv) Finally we can consider the second spectral sequence constructed in Proposition 7.1 which takes the form
One again has $\operatorname {THH}_*(A' / (\mathbb {S}[z]/z^{k}) ) \cong A'[x]$ and $L\Omega _{A'/A}$ is computed as the homology of the DGA $(A'\langle y\rangle \otimes \Lambda (dz),\partial )$ where this time $y$ sits in grading one and homological degree one (recall that $L\Omega$ has a grading and a homological degree). Thus, our virtual $E^{0}$-term this time takes the form
and the differential $\partial$ becomes a $d^{1}$. The spectral sequence looks graphically as follows:
This spectral sequence is a slightly improved version of spectral sequence (iii) as there are way less higher differentials possible. The whole wedge above the diagonal line through $1$ on the $j$-axis is zero. Again this spectral sequence behaves well and degenerates in the ‘small $k$’ case Proposition 6.4, but behaves as badly in the other cases.
Essentially, one should view Proposition 6.4 as degeneration result for the spectral sequences (iii) and (iv), and Proposition 6.7 as a degeneration result for the Brun spectral sequence (ii). By putting both the Bökstedt element $x$ and the divided power element $y$ (coming from the relation $\pi ^{k}=0$) in the same filtration, the spectral sequence (i) that we have used allows us to uniformly treat both of these cases, as well as still behaving well in the cases not covered by Propositions 6.7 and 6.4 (like Example 6.8), where the homology of the DGA of Theorem 5.2 becomes more complicated and all of the three alternative spectral sequences discussed here can have non-trivial extension problems, seen in our spectral sequence in the form of cycles which are interesting linear combinations of powers of $x$ and $y$.
9. Bökstedt periodicity for complete regular local rings
In this section we include a very brief discussion of the more general case of a complete regular local ring $A$, that is, a complete local ring $A$ whose maximal ideal $\mathfrak {m}$ is generated by a regular sequence $(a_1,\ldots, a_n)$, see [Sta19, Tag 00NQ] and [Sta19, Tag 00NU]. Assume furthermore that $A/\mathfrak {m}=k$ is perfect of characteristic $p$. We focus on the mixed characteristic case, because by a result of Cohen [Reference CohenCoh46], $A$ agrees with a power series ring over $k$ in the equal characteristic case.
We can regard $A$ as an algebra over $\mathbb {S}[z_1,\ldots,z_n] = \mathbb {S}[\mathbb {N}\times \cdots \times \mathbb {N}]$. We then have the following generalization of Theorem 3.1:
Theorem 9.1 For a complete regular local ring $A$ of mixed characteristic with perfect residue field of characteristic $p$ we have
with $x$ in degree two.
We give a proof which is completely analogous to that of Theorem 3.1. We first need the following Lemma. Note that by perfectness of $A/\mathfrak {m}=k$ we get a canonical map $W(k) \to A$ and, thus, together with the choice of generators $a_1,\ldots, a_n$ an algebra structure over $W(k)[\kern -0.1em[{z_1,\ldots,z_n}]\kern -0.1em]$.
Lemma 9.2 If $A$ is a complete regular local ring as above, it is of finite type over $W(k)[\kern -0.1em[{z_1,\ldots,z_n}]\kern -0.1em]$. More precisely, it takes the form
for a power series $E$ with $E(0,\ldots,0)=p$.
Proof. The map $W(k)[\kern -0.1em[{z_1,\ldots,z_n}]\kern -0.1em]\to A$ is a surjective $W(k)[\kern -0.1em[{z_1,\ldots,z_n}]\kern -0.1em]$-module map, and the base-change of its kernel $K$ along $W(k)[\kern -0.1em[{z_1,\ldots,z_n}]\kern -0.1em]\to W(k)$ agrees with the kernel of $W(k)\to k$, i.e. $pW(k)$. Therefore, K is free of rank one, on a generator $E\in W(k)[\kern -0.1em[{z_1,\ldots,z_n}]\kern -0.1em]$ reducing to $p$ modulo $(z_1,\ldots,z_n)$.
Proof of Theorem 9.1 From Lemma 9.2, one can deduce as in Proposition 3.5 that the following all agree:
These statements can again all be checked modulo $p$, observing that the lower right-hand term $\operatorname {THH}(A/\mathbb {S}_{W(k)}[\kern -0.1em[{z_1,\ldots,z_n}]\kern -0.1em])$ is already $p$-complete by Lemma 3.6 because $A$ is of finite type over $\mathbb {S}_{W(k)}[\kern -0.1em[{z_1,\ldots,z_n}]\kern -0.1em]$. The key is (as in the proof of Proposition 3.5) that the maps
are all relatively perfect.
Note that, as opposed to the DVR case, $A$ is not of finite type over the ring spectrum $\mathbb {S}_{W(k)}[z_1,\ldots,z_n]$ and, thus, $\operatorname {THH}(A/\mathbb {S}_{W(k)}[z_1,\ldots,z_n])$ is not necessarily $p$-complete.
From Proposition 7.1, we now obtain the following result.
Proposition 9.3 There is a canonical multiplicative, convergent spectral sequence
Analogously to Lemma 4.2 we can describe the differential $d^{2}$ of this spectral sequence.
Lemma 9.4 Representing $A$ as in Lemma 9.2, we can choose the generator
in such a way that
for the $d^{2}$-differential in the spectral sequence of Proposition 9.3.
Proof. We have $\operatorname {THH}_1(A;\mathbb {Z}_p) \cong \Omega ^{1}_{A/W(k)[\kern -0.1em[{z_1,\ldots,z_n}]\kern -0.1em]}$. We obtain
Thus, the image of $d^{2}$ in degree $(0,1)$ has to agree with the ideal generated by $\sum _i ({\partial E}/{\partial z_i}) \,dz_i$. Up to a unit, we thus have
For $n=2$, this differential again completely determines $\operatorname {THH}_*(A;\mathbb {Z}_p)$, because $d^{2}$ in degrees $(2k,0)\mapsto (2k-2,1)$ is injective, and therefore the $E^{3}$-page is concentrated in degrees $(0,0)$, $(2k,1)$ and $(2k,2)$ for $k\geq 0$ and the spectral sequence degenerates thereafter without potential for extensions. For $n\geq 3$, there could be extensions, and for $n\geq 4$, there could be longer differentials, both of which we do not know how to control.
Finally, we want to remark a couple of things about computing $\operatorname {THH}_*(A';\mathbb {Z}_p)$ for $A' = A/(f_1,\ldots,f_d)$, with $(f_1,\ldots,f_d)$ a regular sequence analogously to § 5. We still have a spectral sequence
but the study of $\operatorname {THH}_*(A'/\mathbb {S}[z_1,\ldots,z_n];\mathbb {Z}_p)$ turns out to be potentially more subtle. As opposed to Proposition 3.7, we only have a spectral sequence
but this does not necessarily degenerate into an equivalence because there is no analogue of the spherical lift $\mathbb {S}[z]/z^{k}$ used in the proof of Proposition 3.7.
In our case, $\operatorname {THH}_*(A/\mathbb {S}[z_1,\ldots,z_n];\mathbb {Z}_p)$ is $A[x]$, and $\operatorname {HH}_*(A' / A)$ is easily seen to be a divided power algebra on $d$ generators. Thus, the spectral sequence is even and cannot have non-trivial differentials. However, there is potential for multiplicative extensions. We have been informed by Guozhen Wang that these do indeed show up, as shown in joint work with Ruochuan Liu in [Reference Liu and WangLW22] which appeared after our paper was finished.
10. Logarithmic THH of CDVRs
In this section we want to explain how to deduce results about logarithmic THH from our methods. This way we recover known computations of Hesselholt and Madsen [Reference Hesselholt and MadsenHM03] for logarithmic $\operatorname {THH}$ of DVRs. We thank Eva Höning for asking about the relation between relative and logarithmic $\operatorname {THH}$, which inspired this section.
First we recall the definition of logarithmic $\operatorname {THH}$ following [Reference Hesselholt and MadsenHM03, Reference LeipLei18] and [Reference RognesRog09]. For an abelian monoid $M$ we consider the spherical group ring $\mathbb {S}[M]$ and have
where $B^{\mathrm {cyc}}M$ is the cyclic bar construction, i.e. the unstable version of THH. We denote by $M \to M^{\operatorname {gp}}$ the group completion and define the logarithmic $\operatorname {THH}$ of $\mathbb {S}[M]$ relative to $M$ by
There are induced maps of commutative ring spectra
whose composition is the canonical map. These are induced from the maps $B^{\mathrm{cyc}} M\to M \times _{M^{\operatorname {gp}}} B^{\mathrm{cyc}} M^{\operatorname {gp}} \to M$.
Definition 10.1 For a commutative ring $R$ with a map $\mathbb {S}[M] \to R$ we define logarithmic THH as the commutative ring spectrum
In practice, we only need the case $M = \mathbb {N}$ with the map $\mathbb {S}[\mathbb {N}] = \mathbb {S}[z] \to R$ given by sending $z$ to an element $\pi \in R$. In this case, we also denote $\operatorname {THH}(R\mid \mathbb {N})$ by $\operatorname {THH}(R\mid \pi )$.
Lemma 10.2 We have an equivalence of commutative ring spectra
Proof. We have
We use this lemma to obtain a spectral sequence similar to that of Proposition 7.1. To this end let us introduce some further notation. We set
which comes with a canonical map $\operatorname {HH}(\mathbb {Z}[M]) \to \operatorname {HH}( \mathbb {Z}[M]\, |\, M)$ .
Example 10.3 For $M = \mathbb {N}$ we have $\mathbb {Z}[M] = \mathbb {Z}[z]$ and we get that the logarithmic Hochschild homology $\operatorname {HH}_*(\mathbb {Z}[M]\, |\, M) = \operatorname {HH}_*(\mathbb {Z}[z]\mid z)$ is the exterior algebra over $\mathbb {Z}[z]$ on a generator $\operatorname {dlog} z$. One should think of $\operatorname {dlog} z$ as ‘$dz / z$.’ Indeed, under the canonical map
the element $dz \in \Omega ^{1}_{\mathbb {Z}[z]/\mathbb {Z}}$ gets mapped to $z\cdot \operatorname {dlog} z$ as one easily checks. In particular, one should think of $\operatorname {HH}_*(\mathbb {Z}[z]\, |\, z)$ as differential forms on the space $\mathbb {A}^{1} \setminus 0$ with logarithmic poles at $0$. This is a subalgebra of differential forms on $\mathbb {A}^{1} \setminus 0$ as is topologically witnessed by the injective map $\operatorname {HH}_*(\mathbb {Z}[z]\, |\, z) \to \operatorname {HH}_*(\mathbb {Z}[z^{\pm }])$ and the map $\operatorname {HH}_*(\mathbb {Z}[z])$ then includes the forms on $\mathbb {A}^{1}$.
Proposition 10.4 For every map $\mathbb {S}[M] \to R$ of commutative rings there is a multiplicative and convergent spectral sequence
Moreover, this spectral sequence receives a multiplicative map from the spectral sequence
of Proposition 7.1, which refines on the abutment the canonical map $\operatorname {THH}_*(R) \to \operatorname {THH}_*(R\, |\, M)$ and on the $E^{2}$-page the map $\operatorname {HH}_*(\mathbb {Z}[M]) \to \operatorname {HH}_*(\mathbb {Z}[M]\mid M)$. Similarly, there is a $p$-completed version of this spectral sequence.
Proof. We proceed exactly as in the proof of Proposition 7.1 and define a filtration on $\operatorname {THH}(R\, |\, M)$ by
By the same manipulations as there we obtain the result using Lemma 10.2.
Now for a CDVR $A$ of mixed characteristic with perfect residue field of characteristic $p$, we want to use this spectral sequence to determine the logarithmic $\operatorname {THH}_*(A\mid \pi ; \mathbb {Z}_p)$. As usual, this denotes the homotopy groups of the $p$-completion of $\operatorname {THH}(A \mid \pi )$.
From Theorem 3.1 we see that the spectral sequence of Proposition 10.4 takes the form
with $|x| = (2,0)$ and $|{\operatorname{dlog}z}| = (0,1)$:
The spectral sequence receives a map from the spectral sequence
used in § 4. This map sends $x$ to $x$ and $dz$ to $\pi \operatorname {dlog} z$. Thus, from our knowledge of the differential in this second spectral sequence where we have $d^{2}(x) = E'(\pi ) \,dz$ (Lemma 4.2), we can conclude that $d^{2}$ in the first spectral sequence has to send $x$ to $\pi E'(\pi ) \operatorname {dlog} z$. Thus we get the following result of Hesselholt and Madsen [Reference Hesselholt and MadsenHM03, Theorem 2.4.1 and Remark 2.4.2].
Proposition 10.5 For a CDVR $A$ of mixed characteristic with perfect residue field of characteristic $p$, the ring $\operatorname {THH}_*(A\mid \pi ; \mathbb {Z}_p)$ is isomorphic to the homology of the DGA
with $\partial x = \pi E'(x)\operatorname {dlog}\pi$ and $\partial \,d\pi =0$. In particular
Similarly to Proposition 4.5 one can also obtain a version with coefficients in an $A$-algebra $A'$, namely that $\pi _*( \operatorname {THH}(A \mid \pi ; \mathbb {Z}_p) \otimes _A A')$ is given by the homology of the DGA $H_*(A'[x] \otimes \Lambda (\operatorname {dlog}\pi ), \partial )$ with $\partial$ as in the case without coefficients.
Note that one could alternatively also deduce the differential in the log spectral sequence using the description of $\operatorname {THH}_1(A \mid \pi ; \mathbb {Z}_p)$ in terms of logarithmic Kähler differentials, similar to the way we have deduced the differential in the absolute spectral sequence for $\operatorname {THH}_*(A;\mathbb {Z}_p)$ in Lemma 4.2.
Remark 10.6 We have considered the DVR $A$ together with the map $\mathbb {N} \to A$ as input for our logarithmic $\operatorname {THH}$. This is what is called a pre-log ring. The associated log ring is given by the saturation $M \to A$ with $M = A \cap (A[\pi ^{-1}])^{\times }$. However, we have $M = A^{\times } \times \mathbb {N}$ as one easily verifies. Chasing through the definitions one sees that this implies that $\operatorname {THH}(A \mid \mathbb {N}) \simeq \operatorname {THH}(A \mid M)$, i.e. that the logarithmic $\operatorname {THH}$ only depends on the logarithmic structure. The saturated pair $(A, A^{\times } \times \mathbb {N})$ of course is functorial in more maps than the pre-log ring $(A, \mathbb {N})$ so that logarithmic $\operatorname {THH}$ is more functorial than it might appear from our naive definition. In contrast to that, relative $\operatorname {THH}$ does not have this additional functoriality.
Acknowledgements
We would like to thank L. Hesselholt, E. Höning, M. Mandell, M. Morrow, P. Scholze and G. Wang for helpful conversations. We also thank L. Hesselholt and E. Höning for comments on a draft. The authors were funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under Germany's Excellence Strategy EXC 2044 390685587, Mathematics Münster: Dynamics–Geometry–Structure.
Appendix A. Relation to the Hopkins–Mahowald result
Theorem 1.2 about $\mathbb {F}_p \otimes _{\mathbb {S}} \mathbb {F}_p$ is closely related to the following statement due to Hopkins and Mahowald. We thank Mike Mandell for explaining a proof to us.
Theorem A.1 (Hopkins, Mahowald)
The Thom spectrum of the $\mathbb {E}_2$-map
corresponding to the element $1-p \in \pi _0(\operatorname {GL}_1(\mathbb {S}_p))$ is equivalent to $\mathbb {F}_p$.
We claim that this result is equivalent to Theorem 1.2. More precisely, we show that each of the two results can be deduced from the other only using formal considerations and elementary connectivity arguments.
Proof. Let us first phrase Theorem A.1 a bit more conceptually following [Reference Antolín-Camarena and BarthelAB19]. We can view $\Omega ^{2} S^{3} \to \operatorname {BGL}_1(\mathbb {S}_p)$ as the free $\mathbb {E}_2$-monoid on
in the category $(\mathcal {S}_{*})_{/\operatorname {BGL}_1(\mathbb {S}_p)}$ of pointed spaces over $\operatorname {BGL}_1(\mathbb {S}_p)$. The Thom spectrum functor $\mathcal {S}_{/\operatorname {BGL}_1(\mathbb {S}_p)} \to \operatorname {Mod}_{\mathbb {S}_p}$ is symmetric-monoidal and, thus, the Thom spectrum of $\Omega ^{2} S^{3}$ can equivalently be described as the free $\mathbb {E}_2$-algebra over $\mathbb {S}_p$ on the pointed $\mathbb {S}_p$-module obtained as the Thom spectrum of $S^{1} \xrightarrow {1-p} \operatorname {BGL}_1(\mathbb {S}_p)$. This is easily seen to be $\mathbb {S}_p \to \mathbb {S}_p/p$. As the free $\mathbb {E}_2$-$\mathbb {S}$-algebra on the pointed $\mathbb {S}$-module $\mathbb {S}\to \mathbb {S}/p$ is already $p$-complete, it also agrees with this Thom spectrum. We write this as $\operatorname {Free}^{\mathbb {E}_2}(\mathbb {S}\to \mathbb {S}/p)$. There is a map $\mathbb {S}/p\to \mathbb {F}_p$ of pointed $\mathbb {S}$-modules which induces an isomorphism on $\pi _0$. We obtain an induced map
Theorem A.1 is now equivalently phrased as the statement that the map (A.1) is an equivalence. As both sides are $p$-complete, this is equivalent to the claim that the map is an equivalence after tensoring with $\mathbb {F}_p$. This is the map
induced by the map $\mathbb {F}_p\otimes \mathbb {S}/p\to \mathbb {F}_p\otimes _{\mathbb {S}} \mathbb {F}_p$ of pointed $\mathbb {F}_p$-modules. It follows by elementary connectivity arguments that this map is an isomorphism on $\pi _0$ and $\pi _1$.
Now we have an equivalence $\mathbb {F}_p \otimes \mathbb {S}/p \simeq \mathbb {F}_p \oplus \Sigma \mathbb {F}_p$ as pointed $\mathbb {F}_p$-modules. Thus, we can also write $\operatorname {Free}^{\mathbb {E}_2}_{\mathbb {F}_p}(\mathbb {F}_p\to \mathbb {F}_p\otimes \mathbb {S}/p)$ as the free $\mathbb {E}_2$-algebra on the unpointed $\mathbb {F}_p$-module $\Sigma \mathbb {F}_p$. Thus, the Hopkins–Mahowald result is seen to be equivalent to the claim that the map
induced by a map $\Sigma \mathbb {F}_p\to \mathbb {F}_p\otimes _{\mathbb {S}}\mathbb {F}_p$ which is an isomorphism on $\pi _1$, is an equivalence. This is precisely Theorem 1.2.
In § 1 we have deduced Bökstedt's theorem (Theorem 1.1) directly from Theorem 1.2. Blumberg, Cohen and Schlichtkrull deduced an additive version of Bökstedt's theorem in [Reference Blumberg, Cohen and SchlichtkrullBCS10, Theorem 1.3] from Theorem A.1. A variant of this argument is also given in [Reference BlumbergBlu10, § 9]. We note that the argument that they use only works additively and does not give the ring structure on $\operatorname {THH}_*(\mathbb {F}_p)$. We explain this argument now and also how to modify it to give the ring structure as well.
Proof Proof of Theorem 1.1 from Theorem A.1
The Thom spectrum functor
preserves colimits and sends products to tensor products, and thus sends the unstable cyclic bar construction of $\Omega ^{2} S^{3}$ to the cyclic bar construction of $\mathbb {F}_p$. This identifies $\operatorname {THH}(\mathbb {F}_p)$ as an $\mathbb {E}_1$-ring with a Thom spectrum on the free loop space $LB\Omega ^{2} S^{3} \simeq L\Omega S^{3}$. Now, using the natural fiber sequence of $\mathbb {E}_1$-monoids in $\mathcal {S}_{/\operatorname {BGL}_1(\mathbb {S}_p)}$, $\Omega ^{2} S^{3} \to L\Omega S^{3} \to \Omega S^{3}$, one can identify $\operatorname {THH}(\mathbb {F}_p)$ with $\mathbb {F}_p[\Omega S^{3}]$. For example, because this is a split fiber sequence of $\mathbb {E}_1$ monoids, one obtains an equivalence $L\Omega S^{3} \simeq \Omega ^{2} S^{3} \times \Omega S^{3}$ and, thus, an identification of $\operatorname {THH}(\mathbb {F}_p)$ as a tensor product of the Thom spectrum on $\Omega ^{2} S^{3}$ (i.e. $\mathbb {F}_p$) and the Thom spectrum on $\Omega S^{3}$. Thus, a Thom isomorphism yields an equivalence $\operatorname {THH}(\mathbb {F}_p) \simeq \mathbb {F}_p[\Omega S^{3}]$. However, the equivalence $L\Omega S^{3} \simeq \Omega ^{2} S^{3} \times \Omega S^{3}$ is not an $\mathbb {E}_1$-map, so this argument only describes $\operatorname {THH}(\mathbb {F}_p)$ additively.
One can fix this as follows. The Thom spectrum can be interpreted as the colimit of the functor $L\Omega S^{3} \to \operatorname {Sp}$ obtained by postcomposing with the functor $\operatorname {BGL}_1(\mathbb {S}_p) \to \operatorname {Sp}$ that sends the point to $\mathbb {S}_p$. Instead of passing to the colimit directly, one can pass to the left Kan extension along the map $L\Omega S^{3} \to \Omega S^{3}$. This yields a functor $\Omega S^{3} \to \operatorname {Sp}$ which sends the basepoint of $\Omega S^{3}$ to the colimit along the fiber, i.e. the Thom spectrum over $\Omega ^{2} S^{3}$, which is precisely $\mathbb {F}_p$. We thus obtain a functor $\Omega S^{3} \to \operatorname {BGL}_1(\mathbb {F}_p)$, whose colimit is the Thom spectrum of $L\Omega S^{3}$. As the original functor $L\Omega S^{3} \to \operatorname {Sp}$ was lax monoidal, because it came from an $\mathbb {E}_1$ map, the Kan extension $\Omega S^{3} \to \operatorname {BGL}_1(\mathbb {F}_p)$ is also an $\mathbb {E}_1$ map. The space of $\mathbb {E}_1$ maps $\Omega S^{3} \to \operatorname {BGL}_1(\mathbb {F}_p)$ agrees with the space of maps $S^{2} \to \operatorname {BGL}_1(\mathbb {F}_p)$ and is, thus, trivial. Thus, the resulting colimit $\operatorname {THH}(\mathbb {F}_p)$ is, as an $\mathbb {E}_1$ ring, given by $\mathbb {F}_p[\Omega S^{3}]$.
We think that the proof of Bökstedt's Theorem given in § 1 directly from Theorem 1.2 is easier than the ‘Thom spectrum proof’ presented in this section, because the latter first uses Theorem 1.2 to deduce the Hopkins–Mahowald theorem and then the (extended) Blumberg–Cohen–Schlichtkrull argument to deduce Bökstedt's result. However, logically all three results (Theorems 1.1, 1.2 and A.1) are equivalent as shown in Remark 1.5 and Lemma A.2. Thus, either can be deduced from the others. It would be nice to have a proof of one of these that does not rely on computing the dual Steenrod algebra with its Dyer–Lashof operations (or dually the Steenrod algebra and the Nishida relations).