1. Introduction
Classically, ramification is studied in the setting of extensions of rings of integers in number fields. If $K \subset L$ is an extension of number fields and if $\mathcal{O}_K \rightarrow \mathcal{O}_L$ is the corresponding extension of rings of integers, then a prime ideal $\mathfrak{p} \subset \mathcal{O}_K$ ramifies in $L$ , if $\mathfrak{p}\mathcal{O}_L = \mathfrak{p}_1^{e_1} \cdot \ldots \cdot \mathfrak{p}_s^{e_s}$ in $\mathcal{O}_L$ and $e_i \gt 1$ for at least one $1 \leqslant i \leqslant s$ . The ramification is tame when the ramification indices $e_i$ are all relatively prime to the residue characteristic of $\mathfrak{p}$ , and it is wild otherwise. Auslander and Buchsbaum [Reference Auslander and Buchsbaum1] considered ramification in the setting of general noetherian rings. If $K \subset L$ is a finite $G$ -Galois extension, then $\mathcal{O}_K \rightarrow \mathcal{O}_L$ is unramified, if and only if $\mathcal{O}_K = \mathcal{O}_L^G\rightarrow \mathcal{O}_L$ is a Galois extension of commutative rings, and this in turn says that $\mathcal{O}_L \otimes _{\mathcal{O}_K}\mathcal{O}_L \cong \prod _G \mathcal{O}_L$ (see [Reference Chase, Harrison and Rosenberg13, Remark 1.5 (d)], [Reference Auslander and Buchsbaum1] or [Reference Rognes44, Example 2.3.3] for more details).
Our main interest is to investigate notions of ramified extensions of ring spectra and to study examples.
1.1. Galois extensions
Rognes [Reference Rognes44, Definition 4.1.3] introduces $G$ -Galois extensions of ring spectra. A map $A \rightarrow B$ of commutative ring spectra is a $G$ -Galois extension for a finite group $G$ , if certain cofibrancy conditions are satisfied, if $G$ acts on $B$ from the left through commutative $A$ -algebra maps and if the following two conditions are satisfied:
-
1. The map from $A$ to the homotopy fixed points of $B$ with respect to the $G$ -action, $i \;:\; A \rightarrow B^{hG}$ is a weak equivalence.
-
2. The map
(1.1) \begin{equation} h \;:\; B \wedge _A B \rightarrow \prod _G B \end{equation}is a weak equivalence.
Here, $h$ is right adjoint to the composite map:
induced by the $G$ -action $B \wedge G_+ \cong G_+ \wedge B \rightarrow B$ on $B$ and the multiplication on $B$ .
Condition (1) is the fixed point condition familiar from ordinary Galois theory. Condition (2) is needed to ensure that the map $A \rightarrow B$ is unramified. Among other things, it implies for instance that the $A$ -endomorphisms of $B$ , $F_A(B,B)$ , correspond to the group elements in $G$ in the sense that
is a weak equivalence, where $j$ is right adjoint to the composite map
which is again induced by the $G$ -action and the multiplication on $B$ .
If $A$ is the Eilenberg–MacLane spectrum $H\mathcal{O}_K$ and $B = H\mathcal{O}_L$ for a $G$ -Galois extension $K \subset L$ , then $H\mathcal{O}_K \rightarrow H\mathcal{O}_L$ is a $G$ -Galois extension of ring spectra if and only if $\mathcal{O}_K \rightarrow \mathcal{O}_L$ is a $G$ -Galois extension of commutative rings.
1.2. Ramification
For certain Galois extensions, Ausoni and Rognes [Reference Ausoni and Rognes3] conjecture a version of Galois descent for algebraic K-theory. A descent result that covers many of the conjectured cases is established in [Reference Clausen, Mathew, Naumann and Noel15]. In some cases, descent can be established even in the presence of ramification. Ausoni [Reference Ausoni2, Theorem 10.2] shows for instance that the canonical map $K(\ell _p) \rightarrow K(ku_p)^{hC_{p-1}}$ is an equivalence after $p$ -completion despite the fact that the inclusion of the $p$ -completed connective Adams summand, $\ell _p$ , into $p$ -completed topological connective K-theory, $ku_p$ , should be viewed as a tamely ramified extension of commutative ring spectra. In other cases that are not Galois extensions, for instance in the case of the map $ko \rightarrow ku$ from real to complex connective topological K-theory that shows features of a wildly ramified extension, one can consider a modified version of descent [Reference Clausen, Mathew, Naumann and Noel15, §5.4].
How can we detect ramification? The unramified condition from (1.1) ensures for instance that $A \rightarrow B$ is separable [Reference Rognes44, Definition 9.1.1], and this in turn implies that the canonical map from $B$ to the relative topological Hochschild homology, $\textsf{THH}^A(B)$ , is an equivalence and that the spectrum of topological André–Quillen homology $\textsf{TAQ}^A(B)$ [Reference Basterra6] is trivial. So if we know for a map of commutative ring spectra $A \rightarrow B$ that $B \rightarrow \textsf{THH}^A(B)$ is not a weak equivalence or that $\pi _*\textsf{TAQ}^A(B) \neq 0$ , then this is an indicator for ramification. We will study examples of nonvanishing $\textsf{TAQ}$ in Section 2.1 and study relative topological Hochschild homology in examples related to level- $2$ -structures on elliptic curves in Section 2.2.
1.3. Types of ramification
Whereas detecting ramification for structured ring spectra is rather straightforward in many cases, it is less clear whether a map $A \rightarrow B$ is tamely or wildly ramified; it might also be that there are more types of ramification. Several methods from algebra do not carry over. One obstacle is for instance that there is no concept of ideals for commutative ring spectra that has all features of the algebraic one. Jeff Smith proposed a definition of ideals (see [Reference Hovey25] for an available account), but this notion is not geared toward the case of commutative ring spectra. Determining the homotopy type of the spectrum of topological André–Quillen homology is often hard with the notable exception of suitable Thom spectra [Reference Basterra and Mandell8, Theorem 5 and Corollary]. Therefore, we did not see a way of studying its annihilator as an analog of the different.
Spectra with trivial negative homotopy groups are called connective. For a spectrum $A$ , we denote by $\tau _{\geqslant 0}A$ its connective cover. It is a connective spectrum whose homotopy groups in nonnegative degrees agree with those of $A$ . Akhil Mathew shows in [Reference Mathew36, Theorem 6.17] that connective Galois extensions are algebraically étale: the induced map on homotopy groups is étale in a graded sense. So, in particular, connective covers of Galois extensions are rarely Galois extensions, because several known examples such as $KO \rightarrow KU$ and examples of Galois extensions in the context of topological modular forms are far from behaving nicely on the level of homotopy groups. We like to think of these connective covers as analog of rings of integers in number fields, but we cannot offer any systematic approach behind this interpretation. If you start with a periodic ring spectrum, then just cutting away the negative homotopy groups might not produce a good connective model. In such cases, there might be several meaningful choices for connective models and the analogy is then even less clear.
We determine relative topological Hochschild homology and the bottom nontrivial homotopy groups of the topological André–Quillen spectrum in the cases $ko \rightarrow ku$ , $\ell \rightarrow ku_{(p)}$ , $\textsf{tmf}_0(3)_{(2)} \rightarrow \textsf{tmf}_1(3)_{(2)}$ , $\textsf{tmf}_{(3)} \rightarrow \textsf{tmf}_0(2)_{(3)}$ , $\textsf{Tmf}_{(3)} \rightarrow \textsf{Tmf}_0(2)_{(3)}$ , and $\textsf{tmf}_0(2)_{(3)} \rightarrow \textsf{tmf}(2)_{(3)}$ . We also study a version of the discriminant map in the context of structured ring spectra and apply it to the examples $\ell \rightarrow ku_{(p)}$ and $ko \rightarrow ku$ in Section 2.3.
For certain finite extensions of discrete valuation rings, tame ramification is equivalent to being log-étale (see for instance [Reference Rognes46, Example 4.32]). It is known by work of Sagave [Reference Sagave50] that $\ell \rightarrow ku_{(p)}$ is log-étale if one considers the log structures generated by $v_1 \in \pi _{2p-2}\ell$ and $u \in \pi _2(ku)$ . We show that $ko \rightarrow ku$ is not log-étale if one considers the log structures generated by the Bott elements $\omega \in \pi _8(ko)$ and $u \in \pi _2(ku)$ . This might be seen as in indicator for wild ramification in this case.
1.4. Tate cohomology and Tate construction
Emmy Noether shows [Reference Noether42, §2] that tame ramification is equivalent to the existence of a normal basis. Tame ramification can also be detected by the surjectivity of the trace map [Reference Cassels and Fröhlich12, Theorem 2, Chapter 1, §5]. This in turn yields a vanishing of Tate cohomology.
In stable homotopy theory, Tate cohomology is modeled by the Tate construction. If $E$ is a spectrum with an action of a finite group $G$ , then there is a norm map $N \;:\; E_{hG} \rightarrow E^{hG}$ from the homotopy orbits of $E$ with respect to $G$ , $E_{hG}$ , to the homotopy fixed points, $E^{hG}$ . Its cofiber is the Tate construction of $E$ with respect to $G$ , $E^{tG}$ . If $E$ is an Eilenberg–MacLane spectrum $E = HA$ , then the homotopy groups of the Tate construction agree with the Tate cohomology groups in the sense that $\pi _*(HA^{tG}) \cong \hat{H}^{-*}(G;\; A)$ .
Using Tate spectra as a possible criterion for wild ramification is for instance suggested by Rognes in [Reference Rognes47] and in [Reference Mathew and Meier37]. Rognes also shows a version of Noether’s theorem in [Reference Rognes45, Theorem 5.2.5]: if a spectrum with a $G$ -action $X$ is in the thick subcategory generated by spectra of the form $G_+ \wedge W$ , then $X^{tG} \simeq *$ , so in particular, if $B$ has a normal basis, $B \simeq G_+ \wedge A$ , then $B^{tG} \simeq *$ .
For a finite group $G$ and a connective spectrum $B$ , the Tate construction $B^{tG}$ is trivial if and only if the unit $1 \in \pi _0B$ is in the image of the algebraic norm map. We study examples in the context of topological K-theory, topological modular forms, and cochains on classifying spaces with coefficients in Lubin–Tate spectra (also known as Morava E-theory) whose Tate construction is nontrivial. Our hope is that the structure of the Tate construction in such cases might tell us something about the type of ramification. In the examples where we can completely determine the homotopy type of the Tate construction, however, we obtain generalized Eilenberg–Mac Lane spectra.
1.5. Topological modular forms
Several of our examples use topological modular forms with level structures. The spectrum of topological modular forms, $\textsf{TMF}$ , arises as the global sections of a structure sheaf of $E_\infty$ -ring spectra on the moduli stack of elliptic curves, $\mathcal{M}_{\text{ell}}$ . A variant of it, $\textsf{Tmf}$ , lives on a compactified version, $\overline{\mathcal{M}}_{\text{ell}}$ . Its connective version is denoted by $\textsf{tmf}$ . There are other variants corresponding to level structures on elliptic curves. Recall that a $\Gamma (n)$ -structure (or level $n$ -structure for short) carries the datum of a chosen isomorphism between the $n$ -torsion points of an elliptic curve and the group $(\mathbb{Z}/n\mathbb{Z})^2$ . A $\Gamma _1(n)$ -structure corresponds to the choice of a point of exact order $n$ , whereas a $\Gamma _0(n)$ -structure comes from the choice of a subgroup of order $n$ of the $n$ -torsion points. See [Reference Katz and Mazur27, Chapter 3] for the precise definitions and for background. These level structures give rise to a tower of moduli problems (see [Reference Katz and Mazur27, p. 200] and [Reference Deligne and Rapoport17])
with corresponding commutative ring spectra $\textsf{TMF}_0(n) \rightarrow \textsf{TMF}_1(n) \rightarrow \textsf{TMF}(n)$ and their compactified versions $\textsf{Tmf}_0(n) \rightarrow \textsf{Tmf}_1(n) \rightarrow \textsf{Tmf}(n)$ [Reference Hill and Lawson23, Theorem 6.1].
In [Reference Mathew and Meier37], Mathew and Meier prove that the maps $\textsf{Tmf}\left[\frac{1}{n}\right] \rightarrow \textsf{Tmf}(n)$ are not Galois extensions but they satisfy Tate vanishing, which might be seen as an indication of tame ramification. In contrast, we will identify cases when $\textsf{tmf}(n)^{tGL_2(\mathbb{Z}/n\mathbb{Z})}$ is nontrivial (see Theorem 3.13).
This paper is intended as a starting point for the investigation of different types of ramification for structured ring spectra. We are aware that for a deeper understanding of ramification, one probably needs to use stacks (see e.g., [Reference Mathew36, Reference Meier and Ozornova41]).
2. Detecting ramification
For connective commutative ring spectra that satisfy a mild finiteness condition, the common notions of étaleness are all equivalent [Reference Mathew35, Corollary 3.1]: for a map $A \rightarrow B$ of such spectra $\textsf{TAQ}^A(B) \simeq *$ if and only if the natural map $B \rightarrow \textsf{THH}^A(B)$ is an equivalence if and only if $A \rightarrow B$ is étale in the sense of Lurie [Reference Lurie32, Definition 7.5.1.4], in particular
So we know that in the following examples there is ramification. The question is whether the invariants that are used can tell us something about the type of ramification.
2.1. Topological André–Quillen homology
For a map of connective commutative ring spectra $i \;:\; A \rightarrow B$ , we use the connectivity of the map to determine the bottom homotopy group of $\textsf{TAQ}^A(B)$ [Reference Basterra6].
2.1.1. Algebraic cases
If $\mathcal{O}_K \rightarrow \mathcal{O}_L$ is an extension of number rings with corresponding extension of number fields $K \subset L$ , then of course we cannot use a connectivity argument for understanding $\textsf{TAQ}$ , but here, the algebraic module of Kähler differentials, $\Omega ^1_{\mathcal{O}_L|\mathcal{O}_K}$ , is isomorphic to the first Hochschild homology group $\textsf{HH}_1^{\mathcal{O}_K}(\mathcal{O}_L)$ which in turn is isomorphic to $\pi _0\textsf{TAQ}^{H\mathcal{O}_K}(H\mathcal{O}_L)$ . This follows from combining [Reference Basterra and Richter7, Theorem 2.4], which ensures that $\pi _0\textsf{TAQ}^{H\mathcal{O}_K}(H\mathcal{O}_L)$ is isomorphic to the zeroth Gamma homology group $H\Gamma _0(\mathcal{O}_L|\mathcal{O}_K;\; \mathcal{O}_L)$ , with [Reference Robinson and Whitehouse43, Proposition 6.5], which yields $H\Gamma _0(\mathcal{O}_L|\mathcal{O}_K;\; \mathcal{O}_L) \cong \Omega ^1_{\mathcal{O}_L|\mathcal{O}_K}$ .
2.1.2. The connective Adams summand
Let $\ell$ denote the Adams summand of connective $p$ -localized topological complex K-theory, $ku_{(p)}$ . Here, $p$ is an odd prime.
The inclusion $i \;:\; \ell \rightarrow ku_{(p)}$ induces an isomorphism on $\pi _0$ and $\pi _1$ . Thus, by the Hurewicz theorem for topological André–Quillen homology [Reference Basterra6, Lemma 8.2], [Reference Baker, Gilmour and Reinhard4, Lemma 1.2], we get that $\pi _2\textsf{TAQ}^{\ell }(ku_{(p)})$ is the bottom homotopy group and is isomorphic to the second homotopy group of the cone of $i$ , and this in turn can be determined by the long exact sequence:
Hence, we have $\pi _2 \textsf{TAQ}^{\ell }(ku_{(p)}) \cong \mathbb{Z}_{(p)}$ .
We know from [Reference Dundas, Lindenstrauss and Richter19] that $\ell \rightarrow ku_{(p)}$ shows features of a tamely ramified extension of number rings, and Sagave shows [Reference Sagave50, Theorem 6.1] that $\ell \rightarrow ku_{(p)}$ is log-étale.
2.1.3. Real and complex connective topological K-theory
The complexification map $c \;:\; ko \rightarrow ku$ induces an isomorphism on $\pi _0$ and an epimorphism on $\pi _1$ , so it is a $1$ -equivalence. Hence, again $\pi _2\text{cone}(c) \cong \pi _2(\textsf{TAQ}^{ko}(ku))$ is the bottom homotopy group, but here we obtain an extension:
In order to understand $\pi _2\text{cone}(c)$ , we consider the cofiber sequence:
and the commutative diagram on homotopy groups:
Here, $\tau _e \;:\; e \rightarrow E$ denotes the map from the connective cover $e$ of $E$ to $E$ . The middle vertical map $g$ is the map induced by the cofiber sequences. By the five lemma, $g$ is an isomorphism hence
So this group is also torsion-free. We will later see that $ko \rightarrow ku$ is not log-étale, and we will see some other indicators for wild ramification, but the bottom homotopy group of $\textsf{TAQ}^{ko}(ku)$ does not detect that.
2.1.4. Connective topological modular forms with level structure (case $n=3$ )
We consider $\textsf{tmf}_1(3)$ . Its homotopy groups are $\pi _*(\textsf{tmf}_1(3)) \cong \mathbb{Z}[\frac{1}{3}][a_1, a_3]$ with $|a_i| = 2i$ . See [Reference Hill and Lawson23] for some background. There is a $C_2$ -action on $\textsf{tmf}_1(3)$ coming from the permutation of elements of exact order three and one denotes by $\textsf{tmf}_0(3)$ the connective cover of the homotopy fixed points, $\textsf{tmf}_1(3)^{hC_2}$ . There is a homotopy fixed point spectral sequence that was studied in detail in [Reference Mahowald and Rezk33] for the periodic versions. In [Reference Hill and Lawson23, p. 407], it is explained how to adapt this calculation to the connective variants: the terms in the spectral sequence with $s \gt t-s \geqslant 0$ can be ignored. The $C_2$ -action on the $a_i$ ’s is given by the sign-action, so if $\tau$ generates $C_2$ , then $\tau (a_i^n) =(\!-\!1)^na_i^n$ .
This implies that only $H^0(C_2;\; \pi _0(\textsf{tmf}_1(3))) \cong \mathbb{Z}[\frac{1}{3}]$ survives to $\pi _0(\textsf{tmf}_0(3))$ . For $\pi _1$ , we get a contribution from $H^1(C_2;\; \pi _2(\textsf{tmf}_1(3)))$ , giving a $\mathbb{Z}/2\mathbb{Z}$ generated by the class of $a_1$ (this detects an $\eta$ ). For $\pi _2(\textsf{tmf}_0(3))$ , the class of $a_1^2$ generates a copy of $\mathbb{Z}/2\mathbb{Z}$ .
Hence, the map $j \;:\; \textsf{tmf}_0(3)_{(2)} \rightarrow \textsf{tmf}_1(3)_{(2)}$ is $1$ -connected, so $\pi _2\textsf{TAQ}^{\textsf{tmf}_0(3)_{(2)}}(\textsf{tmf}_1(3)_{(2)})$ is the bottom homotopy group and is isomorphic to $\pi _2(\text{cone}(j))$ which sits in an extension. We can use the commutative diagram of commutative ring spectra from [Reference Hill and Lawson23, Theorem 6.3]
in order to determine to $\pi _2(\text{cone}(j))$ . By [Reference Lawson and Naumann30, Theorem 1.2], there is a cofiber sequence of $\textsf{tmf}_1(3)_{(2)}$ -modules
and hence $\pi _2(\textsf{tmf}_1(3)_{(2)}) \cong \pi _2(ku_{(2)})$ .
The diagram
commutes and the $5$ -lemma implies that $\pi _2(\text{cone}(j)) \cong \mathbb{Z}_{(2)}$ .
2.1.5. Connective topological modular forms with level structure (case $n=2$ , $p=3$ )
Forgetting a $\Gamma _0(2)$ -structure yields a map $f\;:\; \textsf{tmf}_{(3)} \rightarrow \textsf{tmf}_0(2)_{(3)}$ such that $f$ is a $3$ -equivalence. We will recall more details about these spectra at the beginning of Section 2.2. Again, we obtain that the bottom nontrivial homotopy group of the spectrum of topological André–Quillen homology is $\pi _4(\textsf{TAQ}^{\textsf{tmf}_{(3)}}(\textsf{tmf}_0(2)_{(3)})) \cong \pi _4(\text{cone}(f))$ . There is a short exact sequence
so a priori $\pi _4 \text{cone}(f)$ could be isomorphic to $\mathbb{Z}_{(3)}$ or to $\mathbb{Z}_{(3)} \oplus \mathbb{Z}/3\mathbb{Z}$ .
There is an equivalence:
where $T = S^0 \cup _{\alpha _1} e^4 \cup _{\alpha _1} e^8$ with $\alpha _1$ denoting the generator of $\pi _3^s$ at $3$ , [Reference Behrens10, Lemma 2, p. 382], [Reference Mathew36, Theorem 4.15]. Thus, $T$ is part of a cofiber sequence:
and we obtain a cofiber sequence:
and thus
But as we have a short exact sequence:
we obtain
2.2. Relative topological Hochschild homology
In [Reference Dundas, Lindenstrauss and Richter19] (see also [Reference Dundas, Lindenstrauss and Richter20] for a correction), we show that the relative topological Hochschild homology spectra $\textsf{THH}^{\ell }(ku_{(p)})$ and $\textsf{THH}^{ko}(ku)$ have highly nontrivial homotopy groups. Here, we extend these results to the relative $\textsf{THH}$ -spectra of $\textsf{tmf}_{(3)} \to \textsf{tmf}_0(2)_{(3)}$ , $\textsf{Tmf}_{(3)} \to \textsf{Tmf}_0(2)_{(3)}$ and $\textsf{tmf}_0(2)_{(3)} \to \textsf{tmf}(2)_{(3)}$ . For formulas concerning the coefficients of elliptic curves, we refer to [Reference Deligne16].
Recall that we have $\textsf{tmf}_0(2)_{(3)} \simeq \tau _{\geqslant 0}\textsf{tmf}(2)_{(3)}^{hC_2}$ . By [Reference Stojanoska53, §7], we know that $\pi _*\textsf{tmf}(2)_{(3)} \cong \mathbb{Z}_{(3)}[\lambda _1, \lambda _2]$ with $|\lambda _i| = 4$ and with $C_2$ -action given by $\lambda _1 \mapsto \lambda _2$ and $\lambda _2 \mapsto \lambda _1$ [Reference Stojanoska53, Lemma 7.3]. Since $|C_2|$ is invertible in $\pi _*\textsf{tmf}(2)_{(3)}$ , the $E^2$ -page of the homotopy fixed point spectral sequence is given by:
Thus, we have
with $a_2 = -(\lambda _1 + \lambda _2)$ and $a_4 = \lambda _1 \lambda _2$ . Recall the following facts about the homotopy of $\textsf{tmf}_{(3)}$ (see for instance [Reference Douglas, Francis, Henriques and Michael Hill18, p. 192]), we have
where $\alpha _1$ is the image of $\alpha _1 \in \pi _3(S_{(3)})$ under $\pi _3(S_{(3)}) \to \pi _3\textsf{tmf}_{(3)}$ . By [Reference Stojanoska53, Proof of Proposition 10.3], we have that the map $\pi _*\textsf{tmf}_{(3)} \to \pi _*\textsf{tmf}_0(2)_{(3)}$ satisfies $c_4 \mapsto 16a_2^2 -48 a_4$ and $c_6 \mapsto -64 a_2^3 + 288 a_2a_4$ . (There is a discrepancy between our sign for $c_6$ and that in [Reference Stojanoska53].)
We know from personal communication with Mike Hill that there is a fiber sequence of $\textsf{tmf}_0(2)_{(3)}$ -modules:
See [Reference Hill and Meier24, Proposition 4.24] for the analogous statement at $p = 2$ . The kernel of $\pi _*(f)$ has $\mathbb{Z}_{(3)}$ -basis:
and the cokernel has $\mathbb{Z}_{(3)}$ -basis:
We get that in negative degrees $\pi _*\textsf{Tmf}_0(2)_{(3)}$ is given by:
where $\frac{1}{a_2^n a_4^m}$ has degree $-4n-8m-1$ . The $\pi _*\textsf{tmf}_0(2)_{(3)}$ -action is given by:
and analogously for $a_4$ .
By the gap theorem (see for instance [Reference Konter28]), we have $\pi _*\textsf{Tmf}_{(3)} \cong 0$ for $-21 \lt * \lt 0$ .
Lemma 2.1.
where $r$ has degree $4$ and is mapped to 0 under the multiplication map.
Proof. As above, we use that we have an equivalence of $\textsf{tmf}_{(3)}$ -modules $\textsf{tmf}_{(3)} \wedge T \simeq \textsf{tmf}_0(2)_{(3)}$ . Here, $T$ is defined by the cofiber sequences:
and
where $S^7_{(3)} \stackrel {\phi }{\longrightarrow } \text{cone}(\alpha _1) \to S^4_{(3)}$ is equal to $\alpha _1$ . We get an equivalence of left $\textsf{tmf}_0(2)_{(3)}$ -modules:
Smashing the above cofiber sequences with $\textsf{tmf}_0(2)_{(3)}$ gives cofiber sequences of $\textsf{tmf}_0(2)_{(3)}$ -modules:
and
The map $\bar{\alpha }_1$ is zero in the derived category of $\textsf{tmf}_0(2)_{(3)}$ -modules, because $\pi _*(\textsf{tmf}_0(2)_{(3)})$ is concentrated in even degrees. We therefore get an equivalence of $\textsf{tmf}_0(2)_{(3)}$ -modules:
This implies that $\textsf{tmf}_0(2)_{(3)} \wedge \text{cone}(\alpha _1)$ has nontrivial homotopy groups only in even degrees, and therefore that $\bar{\phi }$ is zero in the derived category of $\textsf{tmf}_0(2)_{(3)}$ -modules. We get an equivalence of $\textsf{tmf}_0(2)_{(3)}$ -modules:
We can assume that the map $\textsf{tmf}_{(3)} \to \textsf{tmf}_0(2)_{(3)}$ factors in the derived category of $\textsf{tmf}_{(3)}$ -modules as:
This implies that the inclusion in the first smash factor:
is given by:
We obtain that the map:
is a left inverse for $\textsf{tmf}_0(2)_{(3)} \to \textsf{tmf}_0(2)_{(3)} \wedge \text{cone}(\alpha _1)$ . It is also clear that the inclusion in the second smash factor $\eta _R \;:\; \textsf{tmf}_0(2)_{(3)} \to \textsf{tmf}_0(2)_{(3)} \wedge _{\textsf{tmf}_{(3)}} \textsf{tmf}_0(2)_{(3)}$ is given by:
We claim that
maps to three times a unit under:
By commutativity of the diagram:
it suffices to show that $a_2 \in \pi _4(\textsf{tmf}_{(3)} \wedge T)$ maps to three times a unit under the bottom map. This follows by the exact sequence:
We define $r$ to be the unique element in $\pi _4(\textsf{tmf}_0(2)_{(3)} \wedge \text{cone}(\alpha _1))$ that maps to that unit under $\delta _4$ and that is in the kernel of the composition of $\pi _4(\textsf{tmf}_0(2)_{(3)} \wedge \text{cone}(\alpha _1)) \cong \pi _4(\textsf{tmf}_0(2)_{(3)} \wedge T)$ and the multiplication map
We have that $3r- \eta _R(a_2)$ is in the image of $\pi _4(\textsf{tmf}_0(2)_{(3)}) \to \pi _4(\textsf{tmf}_0(2)_{(3)} \wedge \text{cone}(\alpha _1))$ and thus can be written as $3r- \eta _R(a_2) = n \cdot a_2$ for an $n \in \mathbb{Z}_{(3)}$ . Applying the map
gives $n = -1$ .
We claim that $\eta _R(a_4) \in \pi _8(\textsf{tmf}_0(2)_{(3)} \wedge T)$ maps to three times a unit under
As above one sees that it suffices to show that $a_4$ maps to three times a unit under the map $\pi _8(\textsf{tmf}_{(3)} \wedge T) \to \pi _8(\Sigma ^8 \textsf{tmf}_{(3)})$ . For this, we consider the exact sequence:
Using that $\pi _4(\textsf{tmf}_{(3)}) = 0 = \pi _5(\textsf{tmf}_{(3)})$ , one gets that $\pi _8(\textsf{tmf}_{(3)}) \cong \pi _8(\textsf{tmf}_{(3)} \wedge \text{cone}(\alpha _1))$ , and under this isomorphism the first map in the exact sequence identifies with
As $\pi _6(\textsf{tmf}_{(3)}) = 0 = \pi _7(\textsf{tmf}_{(3)})$ , one gets that $\pi _7(\textsf{tmf}_{(3)} \wedge \text{cone}(\alpha _1)) \cong \pi _7(\Sigma ^4 \textsf{tmf}_{(3)})$ , and under this isomorphism the third map in the exact sequence identifies with
One obtains that the second map in the exact sequence maps $a_4$ to $3 \cdot m$ and $a_2^2$ to $9 \cdot m$ for a unit $m \in \mathbb{Z}_{(3)}$ .
Since the map $\pi _*(\textsf{tmf}_{(3)}) \to \pi _*(\textsf{tmf}_0(2)_{(3)})$ maps $c_4$ to $16a_2^2 -48 a_4$ , we have the equation:
in $\pi _*(\textsf{tmf}_0(2)_{(3)} \wedge _{\textsf{tmf}_{(3)}} \textsf{tmf}_0(2)_{(3)})$ . Replacing $\eta _R(a_2)$ by $3r + a_2$ and using torsion-freeness, one gets the equation:
We apply the map $\Delta _8\;:\; \pi _8(\textsf{tmf}_0(2)_{(3)} \wedge T) \to \pi _8(\Sigma ^8 \textsf{tmf}_0(2)_{(3)})$ to this equation and obtain by torsion-freeness of $\pi _*(\textsf{tmf}_0(2)_{(3)})$ :
We thus have an isomorphism of left $\pi _*(\textsf{tmf}_0(2)_{(3)})$ -modules:
Since the map $\pi _*(\textsf{tmf}_{(3)}) \to \pi _*(\textsf{tmf}_0(2)_{(3)})$ maps $c_6$ to $-64 a_2^3 + 288 a_2 a_4$ , we have
in $\pi _*(\textsf{tmf}_0(2)_{(3)} \wedge _{\textsf{tmf}_{(3)}} \textsf{tmf}_0(2)_{(3)})$ . Replacing $\eta _R(a_2)$ by $3r + a_2$ and $\eta _R(a_4)$ by $a_4 + 3r^2 + 2a_2 r$ and using torsion-freeness, one gets
This implies the lemma.
Remark 2.2. One can give a different proof of Lemma 2.1 using the perspective of Hopf algebroids and associated stacks (see computations in [Reference Bauer9, Section 5]).
Theorem 2.3. The canonical map $\textsf{tmf}_0(2)_{(3)} \rightarrow \textsf{THH}^{\textsf{tmf}_{(3)}}(\textsf{tmf}_0(2)_{(3)})$ is far from being an equivalence. More precisely,
Proof. We use the Tor spectral sequence
in order to calculate relative topological Hochschild homology. For determining
we consider the free resolution of $\mathbb{Z}_{(3)}[a_2,a_4]$ as a $\mathbb{Z}_{(3)}[a_2,a_4,r]/I$ -module:
Applying $(\!-\!) \otimes _{\mathbb{Z}_{(3)}[a_2,a_4,r]/I} \mathbb{Z}_{(3)}[a_2,a_4]$ yields
and hence we get
We note that all nontrivial classes in positive filtration degree have an odd total degree. Since the edge morphism $\pi _*(\textsf{tmf}_0(2)_{(3)}) \to \textsf{THH}^{\textsf{tmf}_{(3)}}_*(\textsf{tmf}_0(2)_{(3)})$ is the unit, the classes in filtration degree zero cannot be hit by a differential and the spectral seqence collapses at the $E^2$ -page. Since $E^2_{n,m} = E^\infty _{n,m}$ is a free $\mathbb{Z}_{(3)}$ -module for all $n,m$ , there are no additive extensions.
As for the connective covers, we have an equivalence of $\textsf{Tmf}_{(3)}$ -modules $\textsf{Tmf}_{(3)} \wedge T \simeq \textsf{Tmf}_0(2)$ [Reference Mathew36, §4.6] such that the map $\textsf{Tmf}_{(3)} \to \textsf{Tmf}_0(2)_{(3)}$ factors in the derived category of $\textsf{Tmf}_{(3)}$ -modules as:
Using the gap theorem, one can argue analogously to the proof of Lemma 2.1 to show that
Theorem 2.4. There is an additive isomorphism:
Proof. As above we have the following free resolution of $\pi _*(\textsf{Tmf}_0(2)_{(3)})$ as a module over
We get that the $E^2$ -page of the Tor spectral sequence:
is given by:
Since all nontrivial classes in positive filtration have an odd total degree, the spectral sequence collapses at the $E^2$ -page. There are no additive extensions, because the $E^{\infty } = E^2$ -page is a free $\mathbb{Z}_{(3)}$ -module.
Theorem 2.5. We have an additive isomorphism:
Proof. The map $\pi _*\textsf{tmf}_0(2)_{(3)} \to \pi _*\textsf{tmf}(2)_{(3)}$ is given by $\mathbb{Z}_{(3)}[\lambda _1 + \lambda _2, \lambda _1\lambda _2] \to \mathbb{Z}_{(3)}[\lambda _1, \lambda _2]$ . One easily sees that
so $\pi _*\textsf{tmf}(2)_{(3)}$ is a free $\pi _*\textsf{tmf}_0(2)_{(3)}$ -module. We get
where $a = \eta _R(\lambda _1) - \lambda _1$ . Let $C_* = \mathbb{Z}_{(3)}[\lambda _1, \lambda _2, a]/{a^2 + \lambda _1 a - \lambda _2 a}$ . We have the following free resolution of $\pi _*\textsf{tmf}(2)_{(3)}$ as a $C_*$ -module:
Thus, the $E^2$ -page of the Tor spectral sequence:
is given by:
Since the nontrivial classes in positive filtration have odd total degree, the spectral sequence collapses at the $E^2$ -page. There are no additive extensions, because the $E^2 = E^{\infty }$ -page is a free $\mathbb{Z}_{(3)}$ -module.
2.3. The discriminant map
Let $A \to B$ be a map of commutative ring spectra and $G$ be a finite group that acts on $B$ through $A$ -algebra maps such that $A \to B^{hG}$ is an equivalence. One then can define the discriminant map $\mathfrak{d}_{B|A} \;:\; B \rightarrow F_A(B,A)$ [Reference Rognes44, Definition 6.4.5]. The map $\mathfrak{d}_{B|A}$ is right adjoint to the trace pairing:
Here, $\mu$ is the multiplication of $B$ , and $tr$ is defined to be the composite:
where $N$ is the norm map. One has that $(A \to B) \circ tr$ is homotopic to $\sum _{g \in G} g$ . If $A \rightarrow B$ is a $G$ -Galois extension, then $\mathfrak{d}_{B|A}$ is a weak equivalence [Reference Rognes44, Proposition 6.4.7]. Rognes proposes that the deviation of $\mathfrak{d}_{B|A}$ from being a weak equivalence might be used for measuring ramification. Note that if $A$ and $B$ are connective, then $tr$ and $\mathfrak{d}_{B|A}$ are defined even if only $A \simeq \tau _{\geqslant 0} B^{hG}$ . We show in the examples of $\ell _p \rightarrow ku_p$ and $ko \rightarrow ku$ that $\mathfrak{d}$ does notice the ramification, but it does not give any information about the type of ramification.
Proposition 2.6. There is a cofiber sequence:
Proof. We know that $F_{\ell _p}(ku_p, \ell _p)$ can be decomposed as:
and $\mathfrak{d}_{ku_p|\ell _p}$ can be identified with a map:
As $\pi _*ku_p$ is a free graded $\pi _*\ell _p$ -module, we can calculate the effect of $\mathfrak{d}_{ku_p|\ell _p}$ algebraically via the trace pairing: the element $\Sigma ^{2i}1 \in \pi _*\Sigma ^{2i} \ell _p$ corresponds to $u^i$ , and it maps an element $u^j$ to $tr(u^i \cdot u^j)$ . Since $(\ell _p \to ku_p) \circ tr$ is $\sum _{g \in C_{p-1}} g$ , the sum of $(p-1)$ $\ell _p$ -algebra maps, we have
Hence on the level of homotopy groups, $\mathfrak{d}_{ku_p|\ell _p}$ maps $1 \in \pi _0 \Sigma ^0 \ell _p$ to $(p-1)\cdot 1 \in \pi _*\Sigma ^0\ell _p = \pi _*\ell _p$ and for $0 \lt i \leqslant p-2$ it maps $\Sigma ^{2i}1 \in \pi _*\Sigma ^{2i} \ell _p$ via multiplication with $(p-1)v_1 = (p-1)u^{p-1}$ to $\pi _*\Sigma ^{-2p+2i+2} \ell _p$ . On the summands $\Sigma ^{2i}\ell _p$ , we get the following maps:
As $(p-1)$ is a unit in $\pi _0(\ell _p)$ the cofiber of
is $\Sigma ^{-2p+2i+2} H\mathbb{Z}_p$ .
Note that $ko \simeq \tau _{\geqslant 0}ku^{hC_2}$ , but as the trace map $tr \;:\; ku \rightarrow ku^{hC_2}$ has the connective spectrum $ku$ as a source, it factors through $\tau _{\geqslant 0}ku^{hC_2}\simeq ko$ , and we obtain a discriminant $\mathfrak{d}_{ku|ko} \;:\; ku \rightarrow F_{ko}(ku,ko)$ . We fix notation for $\pi _*ko$ as:
with $|\eta | = 1$ , $|y|=4$ , and $|\omega |=8$ .
Proposition 2.7. There is a cofiber sequence $ku {\stackrel {\mathfrak{d}_{ku|ko}} \longrightarrow} F_{ko}(ku, ko) \longrightarrow{} \Sigma ^{-2} H\mathbb{Z}$ .
Proof. The cofiber sequence $\Sigma ko {\stackrel {\eta } \longrightarrow} ko {\stackrel {c} \longrightarrow} ku {\stackrel {\delta } \longrightarrow} \Sigma ^2ko {\stackrel {\eta } \longrightarrow} \Sigma ko$ induces a cofiber sequence:
which is equivalent to
This is the twofold desuspension of the cofiber sequence of and hence,
We consider the composition $c_* \circ \mathfrak{d}_{ku|ko} \;:\; ku \rightarrow F_{ko}(ku,ko) \rightarrow F_{ko}(ku,ku)$ . As $c_*$ is part of the cofiber sequence
and as $\eta$ is trivial on $ku$ , we know that $c_*$ induces a monomorphism on the level of homotopy groups.
As $\mathfrak{d}_{ku|ko}$ is adjoint to the trace pairing, the composite
can be identified with
where $t$ denotes the generator of $C_2$ , and the first map is adjoint to the multiplication $ku \wedge _{ko} ku \rightarrow ku$ .
The target of $c_*$ is $F_{ko}(ku,ku) \simeq F_{ku}(ku \wedge _{ko} ku, ku)$ , and we know by work of the first author, documented in [Reference Dundas, Lindenstrauss and Richter20, Proof of Lemma 0.1] that
so we can control the effect of $c_* \circ \mathfrak{d}_{ku|ko}$ on homotopy groups.
Note that $t$ induces a $ku$ -linear map $t_* \;:\; ku \rightarrow t^*ku$ , where $t^*ku$ is the $ku$ -module given by restriction of scalars along $t$ .
As $t^2=\textrm{id}$ , we therefore obtain
and a commutative diagram
Here, $\beta$ induces the map on $\pi _*$ that sends an $f \;:\; (ku \wedge _{ko} ku)_* \rightarrow \Sigma ^{-i}ku_*$ to
If we denote the right unit $\eta _R \;:\; ku \rightarrow ku \wedge _{ko} ku$ applied to $u$ by $u_r$ , then we have the relation $2s + u_r = u$ . As $(t \wedge \textrm{id})_*(u) = -u$ and $(t \wedge \textrm{id})_*(u_r) = u_r$ , this implies that
Torsion-freeness then yields $ (t \wedge \textrm{id})_*(s) = s-u$ .
The adjoint of the multiplication map $\pi _*ku \rightarrow \pi _*F_{ko}(ku, ku)$ maps $u^i$ to the map that sends $1$ to $\Sigma ^{-2i}u^i$ and $s$ to zero. Therefore, the composite $c_* \circ \mathfrak{d}_{ku|ko}$ maps $u^i$ to the map with values $1 \mapsto \Sigma ^{-2i}(u^i+(\!-\!1)^iu^i)$ and
In order to understand the effect of $\mathfrak{d}_{ku|ko}$ , we consider the diagram
where we can identify $c^* \;:\; \pi _*F_{ko}(ku, ko) \cong \pi _{*+2}(ku) \rightarrow \pi _*(ko)$ with $\pi _*\Sigma ^{-2}\delta$ .
The application of $c^*$ gives the restriction to the unit $c \;:\; ko \rightarrow ku$ . Say $(\mathfrak{d}_{ku|ko})_*(u^{2}) = x \in \pi _{6}(ku)$ . Then $\pi _*\Sigma ^{-2}\delta (x) = \lambda y$ , and as $c_*(y) = 2u^2$ , we obtain that $c^* (\mathfrak{d}_{ku|ko})_*(u^{2}) = \Sigma ^{-4}y$ and therefore $(\mathfrak{d}_{ku|ko})_*(u^{2}) = u^3$ . Similarly $c^*(\mathfrak{d}_{ku|ko})_*(u^{4}) = \Sigma ^{-8}2\omega$ and $(\mathfrak{d}_{ku|ko})_*(u^{4}) = u^5$ . By $\pi _*(ko)$ -linearity, these calculations yield
for all $i \geqslant 0$ .
Restriction to the unit of the odd powers of $u$ gives zero.
All the $u^i$ send $s$ to $\pm u^{i+1}$ under $c_* \circ (\mathfrak{d}_{ku|ko})_*$ , so also the odd powers of $u$ have to hit a generator under $(\mathfrak{d}_{ku|ko})_*$ , so as a map from $ku$ to $\Sigma ^{-2}ku$ the map $\mathfrak{d}_{ku|ko}$ has cofiber $\Sigma ^{-2}H\mathbb{Z}$ .
Remark 2.8. To prove Proposition 2.7 , one can alternatively use that the map $\mathfrak{d}_{ku|ko} \;:\; ku \to F_{ko}(ku, ko) \simeq \Sigma ^{-2}ku$ is in fact $ku$ -linear [Reference Rognes44, Lemma 6.4.6] and that it becomes an equivalence after applying $- \wedge _{ko} KO \simeq - \wedge _{ku} KU$ , because $KO \to KU$ is a Galois extension.
3. Describing ramification
3.1. Log-étaleness
It is shown in [Reference Rognes, Sagave and Schlichtkrull49] and [Reference Sagave50] that $\ell \rightarrow ku_{(p)}$ is log-étale with respect to the log structures that are generated by $v_1$ and by $u$ . We will use the class $u \in \pi _2ku_{(2)}$ in order to define a pre-log structure for $ko_{(2)} \rightarrow ku_{(2)}$ and show that $ko_{(2)} \rightarrow ku_{(2)}$ is not log-étale with respect to this pre-log structure. This indicates that the map is not tamely ramified. We use the notation from [Reference Sagave50].
Let $\omega$ denote the Bott element $\omega \in \pi _8ko_{(2)}$ . The complexification map sends $\omega$ to $u^4$ .
By [Reference Sagave50, Lemma 6.2], we have an exact sequence
Here, $D(u)$ and $D(\omega )$ are the pre-log structures for the elements $u$ and $\omega$ as in [Reference Sagave50, Construction 4.2], and $\textsf{TAQ}^{(-,-)}(-,-)$ is log topological André–Quillen homology [Reference Sagave50, Definition 5.20]. The commutative ring spectrum $C$ is given by $ko_{(2)} \wedge _{S^{\mathcal{J}} D(w)}S^{\mathcal{J}} D(u)$ , where $S^{\mathcal{J}}$ is the functor from commutative $\mathcal{J}$ -space monoids to commutative ring spectra defined in [Reference Sagave and Schlichtkrull52, p. 2139]. For the definition of the functor $\gamma (\!-\!)$ , see [Reference Sagave51, Section 3] and [Reference Sagave50, p. 457]. Using [Reference Sagave50, Lemma 4.6], it follows that $\gamma (D(w))$ and $\gamma (D(u))$ have the homotopy type of the sphere and that $\gamma (D(w)) \to \gamma (D(u))$ is multiplication by $4$ . Therefore, we get
We want to show that $\pi _1\textsf{TAQ}^C(ku_{(2)}) = 0 = \pi _0\textsf{TAQ}^C(ku_{(2)})$ . By [Reference Basterra6, Lemma 8.2], it suffices to show that $C \to ku_{(2)}$ is an $1$ -equivalence. Since $\pi _1(ku_{(2)}) = 0$ , it is enough to show that the map is an isomorphism on $\pi _0$ . Since $S^{\mathcal{J}} D(w)$ and $S^{\mathcal{J}} D(u)$ are concentrated in nonnegative $\mathcal{J}$ -space degrees by [Reference Rognes, Sagave and Schlichtkrull48, Example 6.8], they are connective. Thus, it is enough to show that $S^{\mathcal{J}} D(w) \to S^{\mathcal{J}} D(u)$ induces an isomorphism on $\pi _0$ . For this, we only have to prove that $H_0( S^{\mathcal{J}} D(w), \mathbb{Z}) \to H_0(S^{\mathcal{J}} D(u), \mathbb{Z})$ is an isomorphism. Since this map is a ring map, we only need to know that both sides are $\mathbb{Z}$ . This follows from [Reference Rognes, Sagave and Schlichtkrull49, Proposition 5.2, Corollary 5.3]. Hence, we obtain the following result:
Theorem 3.1. The map $(ko_{(2)}, D(\omega )) \rightarrow (ku_{(2)}, D(u))$ is not log-étale.
One could try to distinguish between tame and wild ramification by testing for log-étaleness. In many examples, however, it is less obvious what a suitable log structure would be. Calculations with log structures that are generated by more than one element are challenging because the methods above do not work. For a thorough investigation of log-étaleness and for related calculations, see Lundemo [Reference Lundemo31].
3.2. Ramification and Tate cohomology
In the algebraic context of Galois extensions of number fields and corresponding extension of number rings, tame ramification yields a normal basis and a surjective trace map. Both facts are actually also sufficient in order to distinguish tame from wild ramification. For structured ring spectra, it does not work to impose these properties on the level of homotopy groups, because even for finite faithful Galois extensions these would not hold. Instead, we propose to use the Tate construction in order to understand ramification.
Remark 3.2. Let $G$ be a finite group. Usually one calls a $G$ -module $M$ cohomologically trivial, if $\hat{H}^i(H;\;M) =0$ , for all $i \in \mathbb{Z}$ and all $H \lt G$ . If $M$ is a commutative ring $S$ , however, it suffices to require $\hat{H}^i(G;\;S) =0$ for all $i \in \mathbb{Z}$ : In particular, $\hat{H}^0(G;\;S) =0$ , and hence the norm map $N_G \;:\; S_G \rightarrow S^G$ (resp. the trace map $tr_G \;:\; S \rightarrow S^G$ ) is surjective. Thus, $1_{S^G}$ is in the image of the norm, say $N_G[x] = 1_{S^G}$ for $[x] \in S_G$ . If $H \lt G$ , then we consider the diagram:
and therefore we can express can express $1_{S^H}$ as:
so $1_{S^H}$ is in the image of $N_H$ and $\hat{H}^0(H;\;S) =0$ . But $\hat{H}^*(H;\;S)$ is a graded commutative ring with unit $[1_{S^H}]=0$ , and thus $\hat{H}^*(H;\;S) = 0$ .
The same argument shows that the surjectivity of the trace map suffices for being cohomologically trivial.
In particular, if the Tate cohomology is nontrivial, then the trace map is not surjective and this indicates wild ramification. In the following, we transfer this relationship to structured ring spectra.
We need the following generalization of Tate cohomology; for background, see [Reference Greenlees and May21]. If $E$ is a spectrum with an action of a finite group $G$ , then there is a norm map $N \;:\; E_{hG} \rightarrow E^{hG}$ from the homotopy coinvariants of $E$ with respect to $G$ , $E_{hG}$ , to the homotopy fixed points, $E^{hG}$ . Its cofiber is the Tate construction of $E$ with respect to $G$ , $E^{tG}$ . If $E$ is an Eilenberg–MacLane spectrum $E = HD$ for some abelian group $D$ , then $\pi _*((HD)^{tG}) \cong \hat{H}^{-*}(G;\; D)$ .
Even if $A \rightarrow B$ is a $G$ -Galois extension of ring spectra in the sense of Rognes [Reference Rognes44, Definition 4.1.3], it is not true that this implies that $B$ is faithful as an $A$ -module [Reference Rognes44, Definition 4.3.1]. An example due to Wieland is the $C_2$ -Galois extension $F((BC_2)_+, H\mathbb{F}_2) \rightarrow F((EC_2)_+, H\mathbb{F}_2) \simeq H\mathbb{F}_2$ which is not faithful: the $F((BC_2)_+, H\mathbb{F}_2)$ -module spectrum $(H\mathbb{F}_2)^{tC_2}$ is not trivial, but $H\mathbb{F}_2 \wedge _{F((BC_2)_+, H\mathbb{F}_2)} (H\mathbb{F}_2)^{tC_2} \sim *$ . In fact, a $G$ -Galois extension $A \to B$ is faithful if and only if $B^{tG}$ is contractible [Reference Rognes44, Proposition 6.3.3].
In the following, we denote by $\tau _{\geqslant 0} X$ the connective cover of a spectrum $X$ . Note that for a map $A \rightarrow B$ between connective commutative ring spectra with a finite group $G$ acting on $B$ via commutative $A$ -algebra maps it makes sense to replace the usual homotopy fixed point condition by the condition that $A$ is weakly equivalent to $\tau _{\geqslant 0}B^{hG}$ . In many examples, $B^{hG}$ won’t be connective. The map $A \rightarrow B$ factors through $A \rightarrow B^{hG} \rightarrow B$ , but as $A$ is connective, we can consider the induced map on connective covers and obtain a map of commutative ring spectra:
that turns $\tau _{\geqslant 0}B^{hG}$ into a commutative $A$ -algebra spectrum.
For any spectrum $X$ , we denote by $\tau _{\lt 0}X$ the cofiber of the map $\tau _{\geqslant 0} X \rightarrow X$ .
Lemma 3.3. Let $G$ be a finite group and let $e$ be a naive connective $G$ -spectrum. Then,
is a cofiber sequence and in particular, $\tau _{\lt 0}e^{tG} \simeq \tau _{\lt 0}e^{hG}$ .
Proof. We consider the norm sequence:
As $e_{hG}$ is a connective spectrum, we have that $\pi _{-1}e_{hG} = 0$ . Hence, applying $\tau _{\geqslant 0}$ still gives rise to a cofiber sequence:
We combine the norm cofiber sequences with the defining cofiber sequence of $\tau _{\lt 0}$ and obtain
Thus, $\tau _{\lt 0} e^{hG} \simeq \tau _{\lt 0} e^{tG}$ and the cofiber sequence in the second row then yields the claim.
Remark 3.4. In many cases, if $B^{tG} \not \simeq *$ , then $\pi _*(B^{tG})$ is actually periodic. As the canonical Künneth map:
is a map of graded commutative rings and as $\pi _*(B^{tG}) \cong \pi _*(B^{hG})$ in negative degrees, a periodicity generator in a negative degree would map to zero in $\pi _*B$ for connective $B$ and hence $\pi _*(B^{tG}) \otimes _{\pi _*(B^{hG})} \pi _*(B)$ is the zero ring. But then also $\pi _*(B^{tG} \wedge _{B^{hG}} B) \cong 0$ and
Therefore, $B$ would not be a faithful $B^{hG}$ -module in these cases. This emphasizes the importance of replacing the condition that $A$ be weakly equivalent to $B^{hG}$ by the requirement that $A \simeq \tau _{\geqslant 0}(B^{hG})$ .
From Lemma 3.3, we also know that in order to show that $B^{tG} \not \simeq *$ for connective $B$ it is sufficient to show that $\tau _{\lt 0}B^{hG}$ is not trivial.
We recall the following result from [Reference Rognes44]:
Proposition 3.5. [Reference Rognes44, Proposition 6.3.3] Assume that $G$ is a finite group, $B$ is a cofibrant commutative $A$ -algebra on which $G$ acts via maps of commutative $A$ -algebras. If $B$ is dualizable and faithful as an $A$ -module and if
then $B^{tG} \simeq *$ .
Rognes assumes that $A \simeq B^{hG}$ , but that assumption is not needed. A referee actually noted that it follows from the remaining assumptions in the Proposition: smashing the map $A \rightarrow B^{hG}$ with $B$ over $A$ yields $B \rightarrow B \wedge _A B^{hG}$ . Dualizability of $B$ as an $A$ -module identifies the latter with $(B \wedge _A B)^{hG} \simeq (F(G_+, B))^{hG} \simeq B$ . As $B$ is faithful as an $A$ -module, this implies $A \simeq B^{hG}$ .
Remark 3.6. Assume that $G$ is a finite group and that $B$ is a cofibrant commutative $A$ -algebra on which $G$ acts via maps of commutative $A$ -algebras. If $B$ is dualizable and faithful as an $A$ -module and if $B^{tG} \not \simeq *$ , then we know that $h \;:\; B \wedge _A B \rightarrow F(G_+,B)$ cannot be a weak equivalence, that is, that $A \rightarrow B$ is ramified.
In the following, we study the Tate constructions in several examples. To compute the homotopy of $B^{tG}$ , we use the Tate spectral sequence:
which is of standard homological type, multiplicative, and conditionally convergent. In particular by [Reference Boardman11, Theorem 8.2], it converges strongly if it collapses at a finite stage.
If the spectrum $B$ is connective, then the vanishing of $\pi _*B^{tG}$ is equivalent to the fact that $1 \in \pi _0B$ is in the image of the norm map $N \;:\; \pi _0(B_{hG}) \rightarrow \pi _0B$ . We learned a proof of this fact from one of the referees of an earlier version: one direction follows directly because the Postnikov section $B \rightarrow H(\pi _0(B))$ is a $G$ -equivariant map of commutative ring spectra. For the reverse note that the vanishing of $\hat{H}^{*}(G;\; \pi _0(B))$ implies the vanishing of $\hat{H}^{*}(G;\; \pi _n(B))$ for all $n$ . Thus, the $E^2$ -page of the Tate spectral sequence is trivial and hence $B^{tG} \simeq *$ .
Remark 3.7. Fix a prime $p$ . In the connective examples below, if $\hat{H}^{*}(G;\; \pi _0(B_{(p)})) = 0$ , then we might say that $B$ has tame ramification at $p$ and for primes $p$ with $\hat{H}^{*}(G;\; \pi _0(B_{(p)})) \neq 0$ we might say that $B$ has wild ramification at the prime $p$ .
Work by Greenlees, Hovey, Kuhn, and Sadofsky [Reference Greenlees and Sadofsky22, Reference Hovey and Sadofsky26, Reference Kuhn29] shows that for any finite group and any $K(n)$ -local spectrum (or $T(n)$ -local spectrum), the Tate construction is trivial $K(n)$ -locally (or $T(n)$ -locally). See also [Reference Clausen and Mathew14]. Note that in our examples, $K(n)$ -localization for large $n$ is actually trivial, so the information about ramification is concentrated at small $n$ .
We will now investigate the Tate construction in examples. First, we establish faithfulness:
Lemma 3.8. The map $\textsf{tmf}_0(2)_{(3)} \rightarrow \textsf{tmf}(2)_{(3)}$ identifies $\textsf{tmf}(2)_{(3)}$ as a faithful $\textsf{tmf}_0(2)_{(3)}$ -module.
Proof. For the map $\textsf{tmf}_0(2)_{(3)} \rightarrow \textsf{tmf}(2)_{(3)}$ , we know that $C_2$ acts on $\textsf{tmf}(2)_{(3)}$ via commutative $\textsf{tmf}_0(2)_{(3)}$ -algebra maps and that $\textsf{tmf}_0(2)_{(3)} \simeq \tau _{\geqslant 0}(\textsf{tmf}(2)_{(3)}^{hC_2})$ . The trace map $tr \;:\; \textsf{tmf}(2)_{(3)} \rightarrow \textsf{tmf}(2)_{(3)}^{hC_2}$ factors through $\tau _{\geqslant 0}(\textsf{tmf}(2)_{(3)}^{hC_2}) \simeq \textsf{tmf}_0(2)_{(3)}$ , because $\textsf{tmf}(2)_{(3)}$ is connective. As in [Reference Rognes44, Lemma 6.4.3], one can show that the composite:
is homotopic to the map that is the multiplication by $|C_2|=2$ . As $2$ is invertible in $\pi _0\textsf{tmf}_0(2)_{(3)}$ , the trace map $tr \;:\; \textsf{tmf}(2)_{(3)} \rightarrow \textsf{tmf}_0(2)_{(3)}$ is a split surjective map of $\textsf{tmf}_0(2)_{(3)}$ -modules and hence $\textsf{tmf}_0(2)_{(3)} \rightarrow \textsf{tmf}(2)_{(3)}$ is faithful.
Alternatively, faithfulness also follows from the fact that $\pi _*\textsf{tmf}(2)_{(3)}$ is a free $\pi _*\textsf{tmf}_0(2)_{(3)}$ -module (see the proof of Theorem 2.5).
Lemma 3.9. The spectrum $\textsf{tmf}_0(2)_{(3)}$ is faithful as a $\textsf{tmf}_{(3)}$ -module spectrum.
This result also follows from [Reference Meier40, Proposition 4.15].
Proof. We already mentioned the identification $\textsf{tmf}_0(2)_{(3)} \simeq \textsf{tmf}_{(3)} \wedge T$ where $T = S^0 \cup _{\alpha _1} e^4 \cup _{\alpha _1} e^8$ with $\alpha _1 \in (\pi _3S)_{(3)}$ , [Reference Behrens10, Lemma 2, p. 382], [Reference Mathew36, Theorem 4.15]. Note that $\alpha _1$ is nilpotent of order $2$ because $(\pi _6S)_{(3)} = 0$ .
Assume that $M$ is a $\textsf{tmf}_{(3)}$ -module with
Then, the cofiber sequences
imply that $\Sigma ^4\text{cone}(\alpha _1) \wedge M \simeq \Sigma M$ and $\Sigma ^8 M \simeq \Sigma \text{cone}(\alpha _1) \wedge M$ and therefore,
The equivalence is induced by a class in $\pi _{10}S_{(3)} \cong \mathbb{Z}/{3\mathbb{Z}}\{\beta _1\}$ . As this is nilpotent, we get that $M \simeq *$ .
Remark 3.10. It is known that $ko \rightarrow ku$ is faithful [Reference Rognes44, Proposition 5.3.1] and dualizable, and it is clear that $\ell \rightarrow ku_{(p)}$ is faithful and dualizable as the inclusion of a summand. As $\textsf{tmf}_1(3)_{(2)}$ can be identified with $\textsf{tmf}_{(2)} \wedge DA(1)$ as a $\textsf{tmf}_{(2)}$ -module [Reference Mathew36, Theorem 4.12], where $DA(1)$ is a finite cell complex realizing the double of $A(1) = \langle Sq^1,Sq^2\rangle$ , it is dualizable. An argument as in [Reference Rognes44, Proof of Proposition 5.4.5] shows that $\textsf{tmf}_{(2)} \rightarrow \textsf{tmf}_1(3)_{(2)}$ is faithful.
At the moment we don’t know whether $\textsf{tmf}_0(3)_{(2)} \rightarrow \textsf{tmf}_1(3)_{(2)}$ is faithful. The diagram
commutes, so if $M$ is a $\textsf{tmf}_0(3)_{(2)}$ -module spectrum with $M \wedge _{\textsf{tmf}_0(3)_{(2)}} \textsf{tmf}_1(3)_{(2)} \simeq *$ , then multiplication by $2$ is a trivial self-map on $M$ . Meier shows [Reference Meier40, Proposition 4.13] that $\textsf{tmf}_1(3)$ is not perfect as a $\textsf{tmf}_0(3)$ -module; hence, $\textsf{tmf}_1(3)$ is not a dualizable $\textsf{tmf}_0(3)$ -module.
Meier also proves that $\textsf{tmf}\left[\frac{1}{n}\right] \rightarrow \textsf{tmf}(n)$ is dualizable and faithful for all $n$ [Reference Meier40, Theorem 4.4, Proposition 4.15]; thus, $\textsf{tmf}(2)_{(3)}$ is dualizable and faithful as a $\textsf{tmf}_{(3)}$ -module.
We show that the extensions $\textsf{tmf}_0(3)_{(2)} \rightarrow \textsf{tmf}_1(3)_{(2)}$ and $\textsf{tmf}_{(3)} \rightarrow \textsf{tmf}(2)_{(3)}$ have nontrivial Tate spectra. For $ku$ , the Tate spectrum with respect to the complex conjugation $C_2$ -action satisfies
This result is due to Rognes (compare [Reference Rognes44, §5.3]). As $ku_{(p)}^{tC_2} \simeq *$ for odd primes $p$ , $2$ is the only wildly ramified prime.
Theorem 3.11. For $\textsf{tmf}_1(3)_{(2)}$ with its $C_2$ -action, we obtain an equivalence of spectra:
Proof. We use the calculations in [Reference Mahowald and Rezk33]. They compute the homotopy fixed point spectral sequence:
where $\pi _*\textsf{TMF}_1(3)_{(2)} = \mathbb{Z}_{(2)}[a_1, a_3][\Delta ^{-1}]$ with $\Delta = a_3^3(a_1^3-27a_3)$ . From their computations, we deduce the following behavior of the Tate spectral sequence:
Let $R_{n,m}$ be the bigraded ring $\mathbb{Z}/2[a_1, a_3][\Delta ^{-1}][\zeta ^{\pm }]$ with $|\zeta | = (\!-\!1, 0)$ . If we assign odd weight to $a_1$ , $a_3$ , and $\zeta$ , then the $E^2$ -page of the Tate spectral sequence is the even part of $R_{n,m}$ . Alternatively, it is given by:
where $S_*$ is the subalgebra of $\mathbb{Z}/{2\mathbb{Z}}[a_1,a_3]$ generated by $a_1^2, a_1a_3, a_3^2$ , and where $x = \zeta a_3^3 \in E_{-1,18}$ . Note that $a_3^2$ is invertible in this ring with $a_3^{-2} = ((a_1a_3)a_1^2-27a_3^2)\Delta ^{-1}$ . By Mahowald–Rezk’s computations, the first nontrivial differential is $d^3$ and we have
Using the Leibniz rule, we get that the class $c_{n,m,k,l,i} = (a_1^2)^n(a_1a_3)^m(a_3^2)^k\Delta ^{-l}x^i$ with $n,m,k,l \in \mathbb{N}$ and $i \in \mathbb{Z}$ has differential
It follows that $\ker d^3$ is generated as an $\mathbb{F}_2$ -vector space by the classes $c_{n,m,k,l,i}$ with $n+k = 0$ in $\mathbb{F}_2$ . We claim that
To see this, note the following: If $n+k = 0$ in $\mathbb{F}_2$ and $m \gt 0$ , then $c_{n,m,k,l,i}$ is zero in $E^4_{*,*}$ because
If $n+k = 0$ in $\mathbb{F}_2$ and $n, k \gt 0$ , then we have $c_{n,0,k,l,i} = c_{n-1, 2, k-1,l,i}$ . This is in the image of $d^3$ , because $n-1 + k-1 = 0$ in $\mathbb{F}_2$ and $ 2 \gt 0$ . If $n = 0$ in $\mathbb{F}_2$ and $n \gt 0$ , then
and both of these summands are in the image of $d^3$ . Furthermore, note that in $E^4_{*,*}$ we have
This implies that for $k = 0$ in $\mathbb{F}_2$ we have
in $E^4_{*,*}$ . We thus get a surjective map $\mathbb{F}_2[x^{\pm }, \Delta ^{\pm }] \to E^4_{*,*}$ , which is injective, because the classes $\Delta ^lx^i$ for $l,i \in \mathbb{Z}$ are not divisible by $(a_1a_3)$ in $S_*[\Delta ^{-1}][x^{\pm }]$ .
From Mahowald–Rezk’s computations, we get that the next nontrivial differential is $d^7$ and that we have
This gives $E^8_{*,*} = 0$ .
We now want to determine the behavior of the Tate spectral sequence:
If we assign again odd weight to $a_1$ , $a_3$ , and $\zeta$ , then the $E^2$ -page is the even part of
and one sees that the map of spectral sequences from (3.2) to (3.1) is injective. We get that $d^3$ is the first nontrivial differential in (3.2) and that we have
Note that an $\mathbb{F}_2$ -basis of the $E^3$ -page is given by the classes:
for $n,m \in \mathbb{N}$ , and $i \in \mathbb{Z}$ .
The $d^3$ -differential on these classes is given by:
We get
The map of spectral sequences from (3.2) to (3.1) satisfies
In particular, one sees that it is injective on $E^4$ -pages. We conclude that the next nontrivial differential in spectral sequence (3.2) is $d^7$ and that we have
We obtain that
Since the $E^8$ -page is concentrated in the zeroth row, the spectral sequence collapses at this stage. This gives the answer on the level of homotopy groups. As $\textsf{tmf}_1(3)^{tC_2}$ is an $E_\infty$ -ring spectrum [Reference McClure39], it is in particular an $E_2$ -ring spectrum and therefore a result by Hopkins–Mahowald (see [Reference Mathew, Naumann and Noel38, Theorem 4.18]) implies that $\textsf{tmf}_1(3)^{tC_2}$ receives a map from $H\mathbb{F}_2$ and therefore is a generalized Eilenberg–MacLane spectrum of the claimed form.
Theorem 3.12. The $\Sigma _3$ -action on $\textsf{tmf}(2)_{(3)}$ yields
Proof. We use the calculation of [Reference Stojanoska53]. She proves that $\textsf{Tmf}(2)_{(3)}^{t\Sigma _3} \simeq *$ via the Tate spectral sequence:
The $E^2$ -page is given by:
with $| \alpha | = (\!-\!1,4)$ , $| \beta | = (\!-\!2,12)$ , and $| \Delta | = (0,24)$ , and the differentials are determined by:
Since $\textsf{tmf}(2)_{(3)}$ is the connective cover of $\textsf{Tmf}(2)_{(3)}$ , the $E^2$ -page of the Tate spectral sequence:
is the $\mathbb{Z}/{3\mathbb{Z}}$ -module
Using the map of Tate spectral sequences $\bar{E}^*_{*,*} \to E^*_{*,*}$ one sees that
Since $E^6_{*,*} = \mathbb{Z}/{3\mathbb{Z}}[\alpha \Delta ^2, \beta ^{\pm }, \Delta ^{\pm 3}]/{(\alpha \Delta ^2)^2}$ the map $\bar{E}^6_{*,*} \to E^6_{*,*}$ is injective. Thus, $\bar{d}^9$ is determined by $d^9$ and one gets
The class $\beta ^{-6}\Delta ^3$ has bidegree $(12,0)$ , and so $\bar{E}^{10}_{*,*}$ is concentrated in line zero and the spectral sequence collapses at this stage.
So the extensions $ko_{(2)} \rightarrow ku_{(2)}$ , $\textsf{tmf}_{(3)} \rightarrow \textsf{tmf}(2)_{(3)}$ , and $\textsf{tmf}_0(3)_{(2)} \rightarrow \textsf{tmf}_1(3)_{(2)}$ have nontrivial Tate constructions.
In contrast, $KO \rightarrow KU$ is a faithful $C_2$ -Galois [Reference Rognes44, §5], and $\textsf{TMF}_0(3) \rightarrow \textsf{TMF}_1(3)$ and $\textsf{Tmf}_0(3) \rightarrow \textsf{Tmf}_1(3)$ are both faithful $C_2$ -Galois extensions [Reference Mathew and Meier37, Theorem 7.12]. In general, $\textsf{TMF}[1/n] \rightarrow \textsf{TMF}(n)$ is a faithful $GL_2(\mathbb{Z}/n\mathbb{Z})$ -Galois extension [Reference Mathew and Meier37, Theorem 7.6] and the Tate spectrum $\textsf{Tmf}(n)^{tGL_2(\mathbb{Z}/n\mathbb{Z})}$ is contractible [Reference Mathew and Meier37, Theorem 7.11].
For general $n \gt 1$ , constructions of $\textsf{tmf}_1(n)$ and $\textsf{tmf}_0(n)$ are tricky: for some large $n$ , $\pi _1\textsf{Tmf}_1(n)$ is nontrivial. Lennart Meier constructs a connective version of $\textsf{Tmf}_1(n)$ with trivial $\pi _1$ as an $E_\infty$ -ring spectrum in [Reference Meier40, Theorem 1.1] so that there are $E_\infty$ -models of $\textsf{tmf}_1(n)$ for all $n$ .
We cannot determine the homotopy type of the $GL_2(\mathbb{Z}/n\mathbb{Z})$ -Tate construction of $\textsf{tmf}(n)$ for arbitrary $n \gt 1$ , but we can identify cases where it is nontrivial.
Theorem 3.13. Assume that for $n \geqslant 2$ we have that $\pi _1\textsf{Tmf}_1(n) =0$ . Then $\textsf{tmf}(n)^{tGL_2(\mathbb{Z}/{n\mathbb{Z}})} \simeq *$ if and only if the order of $SL_2(\mathbb{Z}/{n\mathbb{Z}})$ , or equivalently the order of $GL_2(\mathbb{Z}/{n\mathbb{Z}})$ , is a unit in $\mathbb{Z}\left[\frac{1}{n}\right]$ .
In particular, if $n \geqslant 2$ with $\pi _1\textsf{Tmf}_1(n) =0$ and $2 \nmid n$ or if $n = 2^k$ for $k \geqslant 1$ , then $\textsf{tmf}(n)^{tGL_2(\mathbb{Z}/{n\mathbb{Z}})} \not \simeq *$ .
Proof. Since $\textsf{tmf}(n)_{hGL_2(\mathbb{Z}/{n\mathbb{Z}})}$ is connective, the defining cofiber sequence of $\textsf{tmf}(n)^{tGL_2(\mathbb{Z}/{n\mathbb{Z}})}$ gives an exact sequence:
We have that $\pi _0(\textsf{tmf}(n)) \cong \mathbb{Z}[\frac{1}{n}, \zeta _n]$ , where $\zeta _n$ is a primitive $n$ th root of unity. Consider the commutative diagram
By the homotopy orbit spectral sequence, we have that the left-hand vertical map is an isomorphism. By [Reference Katz and Mazur27, p. 282], an element $A \in GL_2(\mathbb{Z}/{n\mathbb{Z}})$ acts on $\zeta _n^i$ as:
This implies that the ring in the lower right corner is $\mathbb{Z}\left[\frac{1}{n}\right]$ . Since we also have
and since the right-hand vertical map in the diagram is a map of rings, it follows that it is an isomorphism. We thus have to compute the cokernel of the algebraic norm map:
We claim that its image is $|SL_2(\mathbb{Z}/{n\mathbb{Z}})| \mathbb{Z}\left[\frac{1}{n}\right]$ so that $\pi _0(\textsf{tmf}(n)^{tGL_2(\mathbb{Z}/{n\mathbb{Z}})}) \cong \mathbb{Z}\left[\frac{1}{n}\right]/|{SL_2(\mathbb{Z}/{n\mathbb{Z}}})|$ .
Let $\varphi (\!-\!)$ denote the Euler $\varphi$ -function and let $\mu (\!-\!)$ denote the Möbius function. If $d$ is the order of a power $\zeta _n^i$ , then the norm map $N$ sends $\zeta _n^i$ to
For the second equality note that the canonical map $(\mathbb{Z}/{n \mathbb{Z}})^\times \to (\mathbb{Z}/{d\mathbb{Z}})^\times$ is a surjection whose kernel has order $\frac{\varphi (n)}{\varphi (d)}$ . Now, let $d$ be the maximal number which is square-free and divides $n$ . Then, since $d$ is square-free, we have $\mu (d) \in \{1, -1\}$ . If
we have
and
Since the latter is a unit in $\mathbb{Z}\left[\frac{1}{n}\right]$ , we get that the image of the norm is $|SL_2(\mathbb{Z}/{n\mathbb{Z}})|\mathbb{Z}\left[\frac{1}{n}\right]$ . Therefore, we have $\textsf{tmf}(n)^{tGL_2(\mathbb{Z}/{n\mathbb{Z}})}\simeq *$ if and only if $|SL_2(\mathbb{Z}/{n\mathbb{Z})}|$ is a unit in $\mathbb{Z}\left[\frac{1}{n}\right]$ . Since
and $|GL_2(\mathbb{Z}/{n\mathbb{Z}})| = \varphi (n) \cdot |SL_2(\mathbb{Z}/{n\mathbb{Z}})|$ , we see that $|SL_2(\mathbb{Z}/{n\mathbb{Z}})|$ is invertible in $\mathbb{Z}\left[\frac{1}{n}\right]$ if and only if $|GL_2(\mathbb{Z}/{n\mathbb{Z}})|$ is invertible in $\mathbb{Z}\left[\frac{1}{n}\right]$ .
If $n \geqslant 2$ and $2 \nmid n$ , then $|GL_2(\mathbb{Z}/n\mathbb{Z})|$ and $|SL_2(\mathbb{Z}/n\mathbb{Z})|$ are not units in $\mathbb{Z}\left[\frac{1}{n}\right]$ : let $q$ be an odd prime factor of $n$ . Then in
we have a factor of $q-1$ and this is even, but $2$ is not invertible in $\mathbb{Z}\left[\frac{1}{n}\right]$ .
If $n = 2^k$ for some $k \geqslant 1$ , we obtain
which contains $3$ as a non-invertible factor.
Note that Meier shows [Reference Meier40, Theorem 4.4 and Proposition 4.15] that $\textsf{tmf}(n)$ is dualizable and faithful as a $\textsf{tmf}[1/n]$ -module.
Remark 3.14. For many $n$ , the Tate construction $\textsf{tmf}(n)^{tGL_2(\mathbb{Z}/n\mathbb{Z})}$ is actually trivial. If $n = 2^k3^\ell$ with $k, \ell \geqslant 1$ for instance, the order of $GL_2(\mathbb{Z}/n\mathbb{Z})$ is invertible in $\mathbb{Z}\left[\frac{1}{n}\right]$ . Similarly, if $n = p_1 \cdot \ldots \cdot p_r$ for primes $p_i$ , then $|GL_2(\mathbb{Z}/n\mathbb{Z})|$ is invertible in $\mathbb{Z}\left[\frac{1}{n}\right]$ if for all $p_i$ the numbers $p_i-1$ and $p_i+1$ are invertible in $\mathbb{Z}\left[\frac{1}{n}\right]$ . This is for instance the case if $n = 2 \cdot 3 \cdot \cdots \cdot p_m$ is the product of the first $m$ prime numbers for any $m \geqslant 2$ or for $n = 2 \cdot 3 \cdot 7= 42$ but not for $n = 2 \cdot 3 \cdot 11$ .
We close with a periodic example. For a fixed prime $p$ , let $E_n$ denote the Lubin-Tate spectrum whose coefficient ring is
where $u$ is an element of degree $2$ and the $u_i$ s have degree 0. For a perfect field $k$ , $W(k)$ denotes the ring of Witt vectors of $k$ . The ring $W(\mathbb{F}_{p^n})[[u_1,\ldots,u_{n-1}]] = \pi _0(E_n)$ represents deformations of the height $n$ Honda formal group law over $\mathbb{F}_{p^n}$ . The quotient $E_n/(p,u_1,\ldots,u_{n-1}) =K_n$ is a $2$ -periodic version of Morava K-theory whose coefficient ring is the graded field $\pi _*(K_n) = \mathbb{F}_{p^n}[u^{\pm 1}]$ .
For any finite group $G$ , $F(BG_+, E_n) \rightarrow F(EG_+, E_n) \simeq E_n$ is faithful in the $K_n$ -local category [Reference Baker and Richter5, Theorem 4.4]. At the moment, we don’t know whether $E_n$ is a dualizable $F(BG_+, E_n)$ -module for any finite group $G$ .
In [Reference Baker and Richter5, Theorem 5.1], it is shown that $F((BC_{p^r})_+, E_n) \rightarrow E_n$ is ramified and one can also consider more general groups than $C_{p^r}$ . The corresponding Tate constructions are not trivial:
Lemma 3.15. For all $r \geqslant 1$ and $n \geqslant 1$
Proof. The Tate spectral sequence
has as $E^2$ -term
As $\pi _*(E_n)$ is concentrated in even degrees, the whole $E_2$ -term is concentrated in bidegrees $(s,t)$ where $s$ and $t$ are even. Therefore, all differentials have to be trivial and $E_2 = E_\infty$ . Thus, $\pi _*(E_n^{tC_{p^r}})$ is highly nontrivial.
Theorem 3.16. Assume that $G$ is a finite group with $p \mid |G|$ . Then, $E_n^{tG}$ is nontrivial when $E_n$ is the Lubin-Tate spectrum at the prime $p$ .
Proof. The assumption implies that $G$ has $C_p$ as a subgroup. The restriction map induces a map on Tate constructions $E_n^{tG} \rightarrow E_n^{t{C_{p}}}$ . For the remainder of the proof, we use the notation from [Reference Greenlees and May21], denoting the Tate construction $E_n^{tG}$ by the $G$ -fixed points $t((E_n)_G)^G$ of a $G$ -spectrum $t((E_n)_G)$ . McClure [Reference McClure39] shows that the $E_\infty$ -structure on Tate constructions $t((E_n)_G)^G$ is compatible with inclusions of subgroups and Greenlees–May show [Reference Greenlees and May21, Proposition 3.7] that for any subgroup $H \lt G$ the $H$ -spectrum $t((E_n)_G)$ is equivalent to $t((E_n)_H)$ . Therefore, the inclusion of fixed points $t((E_n)_G)^G \rightarrow t((E_n)_G)^H$ is a map of $E_\infty$ -ring spectra. As we know that $E_n^{tC_{p}} = t((E_n)_G)^{C_{p}}$ is nontrivial by Lemma 3.15, $E_n^{tG}$ cannot be trivial, either.
Acknowledgments
We thank Lennart Meier for sharing a draft version of [Reference Meier40] with us, and we thank him and Mike Hill for patient explanations about tmf and friends. We are grateful to John Rognes and Mark Behrens for several helpful comments. We thank the anonymous referees for several useful remarks. During this project, the first named author was a postdoc at the Universität Hamburg funded by the DFG priority program SPP 1786 Homotopy Theory and Algebraic Geometry. The last named author would like to thank the Isaac Newton Institute for Mathematical Sciences for support and hospitality during the program Homotopy Harnessing Higher Structures when work on this paper was undertaken. This work was supported by EPSRC grant number EP/R014604/1.
Competing interests
The authors declare none.