Proof. We have by the definition of the box product (see e.g. [Reference Hill and Mazur13, definition 3.1])

\begin{equation*} \underline M^\mathrm{fix}\Box\underline N^\mathrm{fix} = \begin{cases} [M^{C_2} \otimes N^{C_2} \oplus (M\otimes N)/C_2]/\text{FR} &\text{at }C_2/C_2\\ M\otimes N &\text{at }C_2/e, \end{cases} \end{equation*}

and we map it to ${\underline{(M\otimes N)}}^\mathrm{fix}$ by using the Mackey or Tambara functor map corresponding to the identity map on the free orbit $C_2/e$ via the adjunction in remark 3.1. Then our map will consist of the identity on the free orbit and $\mathsf{res}$ on the trivial orbit, which will land in $(M\otimes N)^{C_2}$.

On the trivial orbit the map $\mathsf{res}$ includes $M^{C_2} \otimes N^{C_2}$ into $(M\otimes N)^{C_2}$ and maps $(M\otimes N)/C_2$ to $(M\otimes N)^{C_2}$ by the map $[m\otimes n]\mapsto m\otimes n +\bar m\otimes\bar n$ (which is an equivalence since 2 is invertible in $M\otimes N$).

Then $\mathsf{res}$ maps $\underline M^\mathrm{fix}\Box\underline N^\mathrm{fix} (C_2/C_2)$ surjectively onto $ (M\otimes N)^{C_2}$ because its restriction to the second summand does, and it is injective because its restriction to the second summand is injective and Frobenius Reciprocity allows us to identify the first summand into the second one: if 2 is invertible in M, any $m\in M^{C_2}$ is equal to $\mathsf{tr} (m/2)$ so $m\otimes n$ is identified with $[m/2\otimes n]$, and if 2 is invertible in N similarly $m\otimes n$ is identified with $[m\otimes n/2]$.

Proof. Applying the formula for the box product ([Reference Hill and Mazur13, definition 3.1]) to the formula for the norm yields

\begin{align*}& (N^{C_2}_eR) \Box \underline M^\mathrm{fix}\\ &\quad = \begin{cases} \bigl( ( \mathbb{Z}\{R\} \oplus (R\otimes R)/C_2 ) /\mathrm{TR} \otimes M^{C_2} \oplus (R\otimes R \otimes M)/C_2 \bigr)/\mathrm{FR}\ \ \text{at } C_2/C_2 \\ R \otimes R \otimes M \ \text{at } C_2/e, \end{cases} \end{align*}

and again we send it to ${\underline{(R \otimes R \otimes M)}}^\mathrm{fix}$ by the Mackey or Tambara functor map that corresponds via the adjunction of remark 3.1 to the identity on the free orbit. So the resulting map is the identity on the free orbit and $\mathsf{res}$ on the trivial orbit, which will land in $(R \otimes R \otimes M)^{C_2}$.

Again, since 2 is invertible the restriction of $\mathsf{res}$ to $(R\otimes R \otimes M)/C_2$, which sends $[a\otimes b\otimes m] \mapsto a\otimes b \otimes m + \bar b\otimes \bar a\otimes \bar m $ is an isomorphism $(R\otimes R \otimes M)/C_2 \to (R\otimes R \otimes M)^{C_2} $. Frobenius Reciprocity identifies $\mathsf{tr}(a\otimes b)\otimes m$ with $[a\otimes b\otimes \mathsf{res}(m)]\in (R\otimes R \otimes M)/C_2$ for all $a, b \in R$, $m\in M^{C_2}$. It also identifies $\{a\} \otimes \mathsf{tr}(m)$ with $[a\otimes \bar a \otimes m ] \in (R\otimes R \otimes M)/C_2$ for all $a\in R$, $m\in M$, and since 2 is invertible, $\mathsf{tr}(M) =M^{C_2}$ (any $m\in M^{C_2}$ is equal to $\mathsf{tr} (m/2)$). So in fact,

\begin{equation*}(N^{C_2}_eR) \Box \underline M^\mathrm{fix} (C_2/C_2) \cong (R \otimes R \otimes M)/{C_2} \cong (R \otimes R \otimes M)^{C_2}, \end{equation*}

and our map between $(N^{C_2}_eR)\Box \underline M^\mathrm{fix} $ and ${\underline{(R \otimes R\otimes M)}}^\mathrm{fix}$ is an isomorphism at both levels.

Proof. The relative box-product $ N_e^{C_2,{\underline{k}}^c}i_e^*({\underline{R}}^\mathrm{fix}) = N_e^{C_2}i_e^*({\underline{R}}^\mathrm{fix} )\Box_{N_e^{C_2}i_e^*({\underline{k}}^c)} {\underline{k}}^c$ is the coequalizer of the diagram

where ν is the composite of the map $N_e^{C_2}i_e^*{\underline{k}}^c \rightarrow N_e^{C_2}i_e^*({\underline{R}}^\mathrm{fix})$ and the multiplication map of $N_e^{C_2}i_e^*({\underline{R}}^\mathrm{fix})$ and $\nu'$ uses the counit of the adjunction $\varepsilon \colon N_e^{C_2}i_e^*{\underline{k}}^c \rightarrow {\underline{k}}^c$ and the multiplication in ${\underline{k}}^c$. As ${\underline{k}}^c$ is the fixed point Tambara functor for the trivial action we can use the fact that $i_e^*$ and $N_e^{C_2}$ are strong symmetric monoidal and lemma 3.2 to get that

\begin{align*}N_e^{C_2}i_e^*({\underline{R}}^\mathrm{fix}) \Box N_e^{C_2}i_e^*({\underline{k}}^c) & = N_e^{C_2}i_e^*({\underline{R}}^\mathrm{fix} \Box {\underline{k}}^c) = N_e^{C_2}i_e^*({\underline{R}}^\mathrm{fix} \Box {\underline{k}}^\mathrm{fix})\\ &\cong N_e^{C_2}i_e^*({\underline{(R\otimes k)}}^\mathrm{fix}).\end{align*}

Then we can use lemma 3.3 to rewrite the diagram as

where now ν uses the map $k \rightarrow R$ and the induced k-module structure on R and $\nu'$ uses the multiplication in k.

Note that $R \otimes_k R \cong (R \otimes R) \otimes_{k \otimes k} k$. We will show that taking the fixed point Tambara functor commutes with forming coequalizers.

To this end we consider the full subcategory of C ₂-Tambara functors whose objects are fixed point Tambara functors and denote it by $C_2\text{-Tamb}^{\mathrm{fix}}$. But then the fact that the functor $T \mapsto {\underline{T}}^\mathrm{fix}$ is right adjoint to evaluation at the free level implies that

\begin{align*} C_2\text{-Tamb}^{\mathrm{fix}}(\underline R^\mathrm{fix}, {\underline{T}}^\mathrm{fix}) & = C_2\text{-Tamb}(\underline R^\mathrm{fix}, {\underline{T}}^\mathrm{fix})\cong cC_2\text{-rings}(\underline R^\mathrm{fix}(C_2/e), T) \\ & = cC_2\text{-rings}(R, T) = cC_2\text{-rings}(R, {\underline{T}}^\mathrm{fix}(C_2/e)), \end{align*}

where $cC_2\text{-rings}$ denotes the category of commutative C ₂-rings. Therefore, if we restrict to the above full subcategory, taking the fixed point Tambara functor is left adjoint, hence preserves coequalizers.

Proof. Using lemma 3.2 we know that

\begin{equation*}\underline M^\mathrm{fix}\Box{{\underline{k}}^c} \Box \underline N^\mathrm{fix} = \underline M^\mathrm{fix}\Box{{\underline{k}}^\mathrm{fix}} \Box \underline N^\mathrm{fix} \cong {\underline{(M\otimes k \otimes N)}}^\mathrm{fix}\end{equation*}

and

\begin{equation*}\underline M^\mathrm{fix}\Box \underline N^\mathrm{fix} \cong {\underline{(M\otimes N)}}^\mathrm{fix}.\end{equation*}

The result in the k-module case then follows from the fact that taking the fixed point Mackey functor commutes with forming coequalizers, which is completely analogous to the fact that the fixed point Tambara functor commutes with forming coequalizers which was shown in the proof of proposition 4.1 above. In the case of k-algebras, it follows directly by the argument in the proof there.

Proof. Theorem 4.3 follows from the previous two results: proposition 4.1 says that for free orbits $C_2/e$,

\begin{equation*} \mathcal{L}^{C_2, {\underline{k}} ^c}_{C_2/e}({\underline{R}}^\mathrm{fix}) \cong {\underline{\mathcal{L}^k_{C_2/e}(R)}}^\mathrm{fix}.\end{equation*}

Clearly for one-point orbits,

\begin{equation*} \mathcal{L}^{C_2, {\underline{k}} ^c}_{C_2/C_2}({\underline{R}}^\mathrm{fix}) = {\underline{R}}^\mathrm{fix}= {\underline{\mathcal{L}^k_{C_2/C_2}(R)}}^\mathrm{fix}.\end{equation*}

If X and Y are disjoint C ₂-sets

\begin{equation*} \mathcal{L}^{C_2, {\underline{k}} ^c}_{X\sqcup Y} ({\underline{R}}^\mathrm{fix}) \cong \mathcal{L}^{C_2, {\underline{k}} ^c}_{X} ({\underline{R}}^\mathrm{fix}) \Box_{{\underline{k}} ^c} \mathcal{L}^{C_2, {\underline{k}} ^c}_{Y} ({\underline{R}}^\mathrm{fix}). \end{equation*}

Then lemma 4.2 implies that the identification for the free and trivial orbits can be assembled into a statement about disjoint unions of orbits. This gives the desired identification in each fixed simplicial degree.

Face maps in X are surjective and the identifications above are compatible with fold maps, orbit surjections $C_2/e \rightarrow C_2/C_2$ and isomorphisms. As degeneracy maps just insert units, they are also compatible with the degreewise isomorphisms.

Proof. The proof follows by induction on n. The base case n = 0 is lemma 3.2 applied to $M=N=R$, and the inductive step can be done with the help of lemma 3.3 for $M= R \otimes (R\otimes R)^{\otimes(n-1)} \otimes R$. Note that both lemmas proceed by identifying all the terms to the C ₂-coinvariant (second) part of the box product on $C_2/C_2$, so these identifications of the term $\underline R^\mathrm{fix} \Box (N^{C_2}_ei^{*}_e\underline R^\mathrm{fix} )^{\Box n} \Box \underline R^\mathrm{fix}$ with ${\underline{(R\otimes (R\otimes R)^{\otimes n} \otimes R)}} ^\mathrm{fix}$ behave as one would expect for internal multiplications and insertions of units. See also the comment below the proof of lemma 3.3. Therefore, these identifications are compatible with the simplicial structure maps.

Proof. We get the first isomorphism because the map of theorem 6.1 is a quasi-isomorphism. It also follows from the fact that both complexes calculate $ \mathsf{Tor}_*^{A\otimes A^\mathrm{op} }(A,M)$ because of the assumption that A is flat over k. Note that in the case M = A the first isomorphism also follows from the fact that the bar construction on the left is isomorphic to the Segal-Quillen subdivision of the Hochschild complex [Reference Segal24].

The second isomorphism follows from the fact that 2 is invertible in both complexes: As 2 is invertible in A, the unit of A, $k \rightarrow A$ factors through $k[\frac{1}{2}]$. We can express every level of each of the complexes as the direct sum of the +1-eigenspace and the −1-eigenspace of the action of the generator of C ₂ on them. Since the actions commute with d, in fact each of the complexes breaks up as the direct sum of a positive subcomplex and a negative subcomplex.

Since the quasi-isomorphism is a C ₂-map, it preserves this decomposition, and as it is a quasi-isomorphism, it must be a quasi-isomorphism on the positive and negative subcomplexes, respectively. That means that we get an isomorphism

\begin{equation*}H_*( B^k_*(A, A\otimes A^\mathrm{op}, M)^{C_2}) \to H_*(\mathsf{CH}^k_*(A;M) ^{C_2}),\end{equation*}

but since 2 is invertible, we have a chain isomorphism

\begin{equation*} \mathsf{CH}^k_*(A;M) ^{C_2} \to \mathsf{CH}^k_*(A;M) _{C_2}= \mathsf{CH}^k_*(A;M)/(1-r),\end{equation*}

and hence the claim follows with [Reference Graves11, proposition 2.4].

Proof of theorem 6.1

We consider two $A\otimes A^\mathrm{op}$-flat resolutions of A: We use $B^k_*(A, A\otimes A^\mathrm{op}, A\otimes A^\mathrm{op})$ with $A\otimes A^\mathrm{op}$ acting on the rightmost coordinate and $B^k_*(A,A,A)$ where $A^\mathrm{op}$ acts on the left and A on the right, as in the $\mathsf{Tor}$-identification of Hochschild homology. We let C ₂ act on $B_*(A, A\otimes A^\mathrm{op}, A\otimes A^\mathrm{op})$ by acting diagonally on all the coordinates, and denote the action of the generator on it by τ. This action is simplicial, and therefore commutes with d. We let C ₂ act on $B^k_*(A,A,A)$ by setting

\begin{equation*}r(a_0\otimes a_1\otimes \cdots \otimes a_n\otimes a_{n+1}) =(-1)^\frac{n(n+1)}{2} \bar a_{n+1}\otimes \bar a_n \otimes \cdots\otimes \bar a_1 \otimes \bar a_0.\end{equation*}

Because of the sign adjustment, r is a chain map. We only know that the two resolutions are flat, not that they are projective. But any chain map between them that covers the identity on A induces an isomorphism on H ₀, which is the only nontrivial homology group for both complexes, and therefore is a quasi-isomorphism.

We define $f_n \colon B^k_n(A, A\otimes A^\mathrm{op}, A\otimes A^\mathrm{op}) \to B^k_{n}(A,A,A)$ as

\begin{align*} f_n(a_0 \otimes &(a_1\otimes a_{2n+2}) \otimes (a_2\otimes a_{2n+1}) \otimes \cdots \otimes (a_{n+1}\otimes a_{n+2}))\\ = & a_{n+2}a_{n+3}\cdots a_{2n+1} a_{2n+2} a_0\otimes a_1\otimes a_2\otimes\cdots\otimes a_{n+1}. \end{align*}

This is a simplicial $A\otimes A^\mathrm{op}$-module map, and covers the identity on the A being resolved since in level 0 it sends $a_0\otimes (a_1\otimes a_2)$ to $a_2 a_0 \otimes a_1$ and both of these map down to $a_2 a_0 a_1\in A$. This map is not C ₂-equivariant, but if we define $g := r\circ f\circ\tau$, we get $g_n \colon B^k_n(A, A\otimes A^\mathrm{op}, A\otimes A^\mathrm{op}) \to B^k_{n}(A,A,A)$ with

\begin{align*} g_n(a_0 \otimes &(a_1\otimes a_{2n+2}) \otimes (a_2\otimes a_{2n+1}) \otimes \cdots \otimes (a_{n+1}\otimes a_{n+2}))\\ = & (-1)^\frac{n(n+1)}{2} a_{n+2}\otimes a_{n+3}\otimes \cdots \otimes a_{2n+1} \otimes a_{2n+2}\otimes a_0 a_1 a_2 \cdots a_{n+1}. \end{align*}

This is not a simplicial map but it is an $A\otimes A^\mathrm{op}$-module map and it is a chain map since r, f, and τ are chain maps. Again, it covers the identity on A since on level 0, $a_0\otimes (a_1\otimes a_2)\mapsto a_2 \otimes a_0 a_1$ and both of these map down to $a_2 a_0 a_1\in A$.

We now use the fact that 2 is invertible in A and consider the map

\begin{equation*}\frac {f+g}{2} \colon B^k_*(A, A\otimes A^\mathrm{op}, A\otimes A^\mathrm{op})\to B^k_*(A,A,A),\end{equation*}

which is a map of $A\otimes A^\mathrm{op}$-chain complexes and covers the identity on A since f and g are such maps. This map is also equivariant because

\begin{equation*} r\circ\frac {f+g}{2} = r\circ\frac {f+r\circ f\circ\tau}{2} =\frac {r\circ f + f\circ\tau}{2} =\frac {r\circ f \circ\tau + f}{2}\circ\tau =\frac {f+g}{2}\circ\tau. \end{equation*}

So $\frac{f+g}{2}$ is a quasi-isomorphism of flat $A\otimes A^\mathrm{op}$-complexes. By lemma 6.3 below, if we tensor it over $A\otimes A^\mathrm{op}$ with the $A\otimes A^\mathrm{op}$-module M, we get a quasi-isomorphism

\begin{equation*} \frac{f+g}{2}\otimes\mathrm{id}_M \colon B^k_*(A, A\otimes A^\mathrm{op}, M)\to \mathsf{CH}^k_*(A;M). \end{equation*}

This map is equivariant because it is the tensor product of two equivariant maps.

Proof. Since ϕ is a quasi-isomorphism, its mapping cone, $\mathrm{cone}(\phi)$, is acyclic. The mapping cone is also a bounded-below chain complex of flat right R-modules, so it can be viewed as a flat resolution of the 0-module, possibly with a shift. We suspend it, so that $\Sigma^a \mathrm{cone}(\phi)$ is a non-negative chain complex whose bottom chain group is in degree zero. Since flat resolutions can be used to calculate $\mathsf{Tor}$,

\begin{equation*}H_*(\Sigma^a\mathrm{cone}(\phi)\otimes_R M) \cong\mathsf{Tor}_{*}^R(0, M) =0\end{equation*}

for all $*$. So $\Sigma^a\mathrm{cone}(\phi)\otimes_R M$ and hence $\mathrm{cone}(\phi)\otimes_R M =\mathrm{cone}(\phi\otimes_R \mathrm{id}_M)$ is acyclic. But that forces $\phi\otimes_R \mathrm{id}_M$ to be a quasi-isomorphism.

Proof. As 2 is invertible, taking C ₂-fixed points is isomorphic to taking C ₂-coinvariants and both functors are exact. Thus we have to identify the quotient of $(R \otimes M)_{C_2}$ by the bimodule action and this yields $(R \otimes_{R \otimes_k R} M)_{C_2}$ which is isomorphic to $(M/\{am -ma, a \in R, m \in M\})_{C_2}$. By [Reference Fernàndez-València and Giansiracusa9, proposition 2.4.1], $R \otimes_{R^{ie}} M$ is isomorphic to the pushout of

and this proves the claim.

Proof. As we assume that R is flat over k, tensoring with R is exact, and as 2 is invertible, taking fixed points is exact. Therefore, in every simplicial degree n, the sequence

\begin{equation*} 0 \rightarrow (BM_1)_n \rightarrow (BM_2)_n \rightarrow (BM_3)_n \rightarrow 0\end{equation*}

is short exact and hence we obtain a short exact sequence of simplicial k-modules

\begin{equation*} 0 \rightarrow BM_1 \rightarrow BM_2 \rightarrow BM_3 \rightarrow 0\end{equation*}

which yields a long exact sequence on homotopy groups.

Proof. In the category of $R^{ie}$-modules, $R^{ie}$ is a projective generator and every module can be written as a quotient of a direct sum of copies of R ^ie. Our construction sends a direct sum of modules to a direct sum of simplicial objects, yielding a direct sum of associated chain complexes. Retracts of modules give retracts of the associated chain complexes. It therefore suffices to check the claim for $P=R^{ie}$.

If D is any k-module with a C ₂-action such that 2 acts invertibly on D, then there is an isomorphism

\begin{equation*} (D \otimes_k k[C_2])^{C_2} \cong D \end{equation*}

where on the left hand side we consider the diagonal C ₂-action: First note that $D \otimes_k k[C_2]$ with the diagonal action is isomorphic to $D \otimes_k k[C_2]$ where the C ₂-action is only on the right-hand factor. The isomorphism $\psi \colon D \otimes_k k[C_2] \rightarrow D \otimes_k k[C_2]$ sends a generator $d \otimes \tau^i$ to $\tau^{-i}d \otimes \tau^i$. Then, as 2 acts invertibly, we have

\begin{equation*} (D \otimes_k k[C_2])^{C_2} \cong (D \otimes_k k[C_2])_{C_2} = (D \otimes_k k[C_2]) \otimes_{k[C_2]} k. \end{equation*}

So in total, $(D \otimes_k k[C_2])^{C_2} \cong D$.

Therefore, in every simplicial degree n we can identify

\begin{equation*} {\underline{B^k_n(R, R\otimes_k R, R^{ie})}}^\mathrm{fix}(C_2/C_2) = (R \otimes_k (R \otimes_k R)^{\otimes_k n} \otimes_k (R \otimes_k R \otimes_k k[C_2]))^{C_2}\end{equation*}

with $R \otimes_k (R \otimes_k R)^{\otimes_k n} \otimes_k (R \otimes_k R)$. But then we are left with the bar construction $B^k(R, R \otimes_k R, R \otimes_k R)$ and this has trivial homotopy groups in positive degrees.

Proof. Lemmata 7.4–7.6 imply that $\pi_*{\underline{B^k(R, R\otimes_k R, -)}}^\mathrm{fix}(C_2/C_2)$ has the same axiomatic description as $\mathsf{Tor}_*^{R^{ie}}(R;-)$.

Proof of theorems 7.2 and 7.3

Theorem 7.2 is a special case of proposition 7.7 working with $k=\mathbb{Z}$ (although we are working over the C ₂-Burnside Tambara functor, not over $\mathbb{Z}^c$) and with M = R. Theorem 7.3 is the relative version.

Proof. We know that

\begin{align*}& (\tilde{N}^{C_2}_ei^{*}_e \underline R^\mathrm{fix}) \Box \underline R^\mathrm{fix} \\ &\quad= \begin{cases} \bigl( ( \mathbb{Z}\{R\} \oplus (R\otimes R^\mathrm{op})/C_2 ) /\mathrm{TR} \otimes R^{C_2} \oplus (R\otimes R^\mathrm{op} \otimes R)/C_2 \bigr)/\mathrm{FR}& \text{at } C_2/C_2 \\ R \otimes R^\mathrm{op} \otimes R& \text{at } C_2/e. \end{cases} \end{align*}

We define the left $\tilde{N}^{C_2}_ei^{*}_e \underline R^\mathrm{fix}$-module structure of $\underline R^\mathrm{fix}$ by

\begin{equation*} (a \otimes b) \otimes c \mapsto acb\end{equation*}

at the free level. At the trivial level we have three types of terms:

1. (1) For $a \in R$ and $x \in R^{C_2}$ we send $\{a\} \otimes x$ to $ax\bar{a}$.

2. (2) Whereas for $a, b \in R$ and $x \in R^{C_2}$ we define

   \begin{equation*} [a \otimes b] \otimes x \mapsto axb +\bar{b}x\bar{a}. \end{equation*}

   The resulting elements are fixed points under the anti-involution.

3. (3) The C ₂-action on $R \otimes R^\mathrm{op} \otimes R$ sends a generator $a \otimes b \otimes y$ to $\bar{b} \otimes \bar{a} \otimes \bar{y}$. We send a C ₂-equivalence class $[a \otimes b \otimes y]$ to $ayb + \bar{b}\bar{y}\bar{a}$.

We have to check that this action is well-defined and satisfies associativity and a unit condition.

A direct inspection shows that $[a \otimes b] \otimes x$ and $[\bar{b} \otimes \bar{a}] \otimes x$ map to the same element. Similarly, the value on $[a \otimes b \otimes y]$ and $[\bar{b} \otimes \bar{a} \otimes \bar{y}]$ agrees. It is also straightforward to see that the module structure respects Tambara reciprocity. For Frobenius reciprocity we have to compare three expressions:

• • $[a \otimes b] \otimes x$ is $\mathsf{tr}(a \otimes b) \otimes x$ and this is identified with $[a \otimes b \otimes \mathsf{res}(x)] = [a \otimes b \otimes x]$. Both terms are mapped to $axb + \bar{b}x\bar{a}$ because x is a fixed point.

• • A term $\{a\} \otimes \mathsf{tr}(y)$ is sent to $a(y + \bar{y})\bar{a}$. It is identified with $[\mathsf{res}\{a\} \otimes y] = [a \otimes \bar{a} \otimes y]$ and this goes to $ay\bar{a}+ a\bar{y}\bar{a}$.

• • We have

  \begin{equation*} [a \otimes b] \otimes (y + \bar{y}) = [a \otimes b] \otimes \mathsf{tr}(y) = \mathsf{res}([a \otimes b]) \otimes y. \end{equation*}

  All these terms are mapped to $ayb + \bar{b}y\bar{a} + a\bar{y}b + \bar{b}\bar{y}\bar{a}$.

As $\{1\}$ acts neutrally at the trivial level and as $1 \otimes 1$ acts neutrally at the free level, the unit condition is satisfied. Associativity can be proven with a very tedious calculation.

This shows that the map $\tilde{N}_e^{C_2}i_e^*\underline R^\mathrm{fix} \Box \underline R^\mathrm{fix} \rightarrow \underline R^\mathrm{fix}$ defined above yields a left $\tilde{N}_e^{C_2}i_e^*\underline R^\mathrm{fix}$-module structure on $\underline R^\mathrm{fix}$.

The following is a sketch of the construction of the right $\tilde{N}_e^{C_2}i_e^*\underline R^\mathrm{fix}$-module structure on $\underline R^\mathrm{fix}$: We have to define $\underline R^\mathrm{fix} \Box \tilde{N}_e^{C_2}i_e^*\underline R^\mathrm{fix} \rightarrow \underline R^\mathrm{fix}$, that is: a map from

\begin{align*} &\underline R^\mathrm{fix} \Box (\tilde{N}^{C_2}_ei^{*}_e \underline R^\mathrm{fix})\\ &\quad = \begin{cases} R^{C_2} \otimes \bigl( ( \mathbb{Z}\{R\} \oplus (R\otimes R^\mathrm{op})/C_2 ) /\mathrm{TR} \oplus (R \otimes R\otimes R^\mathrm{op})/C_2 \bigr)/\mathrm{FR}& \text{at } C_2/C_2 \\ R \otimes R \otimes R^\mathrm{op} & \text{at } C_2/e \end{cases} \end{align*}

to $\underline R^\mathrm{fix}$. At the free level we send $a \otimes (b \otimes c)$ to cab and this propagates to the trivial level where we map $[y \otimes a \otimes b]$ to $bya + \bar{a}\bar{y}\bar{b}$ and $x \otimes [a \otimes b]$ to $bxa + \bar{a}x\bar{b}$. A term $x \otimes \{a\}$ goes to $\bar{a}xa$. Then a proof dual to the above shows that this indeed gives a well-defined right module structure and that this right-module structure is compatible with the left-module structure so that we actually obtain a bimodule structure.

Proof. We only point out where the differences to the proof in the commutative case are. As in lemma 3.3, we can show (by literally using the same proof) that there is an isomorphism of C ₂-Mackey functors

\begin{equation*} \tilde{N}_e^{C_2}i_e^* {\underline{R}}^{\mathrm{fix}} \Box {\underline{M}}^{\mathrm{fix}} \cong {\underline{(R \otimes R^{op} \otimes M)}}^{\mathrm{fix}}, \end{equation*}

if 2 is invertible in R and if R is an associative ring with anti-involution.

The arguments in § 5 go through with the difference that we have to replace $R \otimes R$ by $R \otimes R^{op}$ and theorem 5.1 gives an isomorphism of C ₂-Mackey functors

\begin{equation*} \mathcal{L}_{S^\sigma}^{C_2}(\underline R^\mathrm{fix}) \cong B(\underline R^\mathrm{fix}, \tilde{N}_e^{C_2}i_e^*\underline R^\mathrm{fix}, \underline R^\mathrm{fix}) \cong {\underline{B(R, R \otimes R^{op}, R)}}^\mathrm{fix}. \end{equation*}

Section 6 is already formulated for associative algebras and also the homological algebra arguments in section 7 go through but we have to replace $R \otimes R$ by the enveloping algebra $R \otimes R^{op}$.

Proof. We have to adapt the statement and the proof of proposition 4.1 and claim that for an associative k-algebra A with anti-involution we obtain that

\begin{equation*} \tilde{N}_e^{C_2,{\underline{k}}^c}i_e^*({\underline{A}}^\mathrm{fix}) \cong {\underline{(A \otimes_k A^{op})}}^\mathrm{fix}, \end{equation*}

where C ₂ acts on $A \otimes_k A^{op}$ by $\tau(a\otimes b)=\bar b \otimes \bar a$.

The proof goes through, when we consider the adjunction between the full subcategory of C ₂-fixed point Mackey functors of associative rings with anti-involution and the category of rings with anti-involution. Then the proof of the adjunction can be copied. This yields an analogue of theorem 4.3 in the associative setting.

\begin{equation*} \mathcal{L}_{S^\sigma}^{C_2,{\underline{k}}^c}({\underline{A}}^\mathrm{fix}) \cong {\underline{\mathcal{L}_{S^\sigma}^k(A)}}^\mathrm{fix} \end{equation*}

The other changes are similar to the absolute case of an associative ring with anti-involution but of course now we have to replace $A \otimes_k A$ by the enveloping algebra $A \otimes_k A^{op}$.