Quasi-isomorphism preserves group hypercohomology

Question

I am looking for a reference for the assertion in the title.

In more detail, let $\Gamma=\{1,\gamma\}$ be a group of order 2. Let $A$ be a $\Gamma$-module (an abelian group on which $\Gamma$ acts). Then I can compute the cohomology groups $H^k(\Gamma,A)$ using a certain nice periodic resolution.

Let $A_1\overset{\partial}{\longrightarrow} A_0$ be a morphism of $\Gamma$-modules, which I regard as a complex of $\Gamma$-modules of length 2 with $A_0$ in degree 0 and $A_1$ in degree $-1$. I can define the hypercohomology groups ${\Bbb H}^k(\Gamma, A_1\to A_0)$ of this complex in some reasonable way (I would be glad to have a reference for a standard definition!).

Now let $$(\varphi_1,\varphi_0)\colon\ (A_1\overset{\partial}{\longrightarrow} A_0)\,\longrightarrow\, (A_1'\overset{\partial'}{\longrightarrow} A_0')$$ be a quasi-isomorphism, that is, a morphism of complexes such that the induced morphisms $$\ker\partial\to\ker\partial'\qquad\text{and}\qquad {\rm coker\,}\partial\to{\rm coker\,}\partial'$$ are isomorphisms.

Proposition. If $(\varphi_1,\varphi_0)$ above is a quasi-isomorphism, then the induced homomorphism on hypercohomology $$\varphi_*\colon\ {\Bbb H}^k(\Gamma, A_1\to A_0)\,\to\, {\Bbb H}^k(\Gamma, A_1'\to A_0')$$ is an isomorphism.

I am looking for a reference (rather than a proof) for this proposition.

Answer 1

This is surely not the type of answer you want (I think Andy's comment is). But I think it's worth explaining that there's a general formalism that makes this type of result transparent. I'm sorry if this is clear to you already.

Let $$\Gamma_G : \mathrm{Mod}_{k[G]} \to \mathrm{Mod}_k$$ be the functor of taking $G$-invariants ($k$ is some ground ring). It is left exact, and $\mathrm{Mod}_{k[G]}$ has enough injectives, so it admits a derived functor $$ R\Gamma_G : D^+(\mathrm{Mod}_{k[G]}) \to D^+(\mathrm{Mod}_k).$$ The derived functor goes between derived categories.

Hypercohomology can be expressed in terms of $R\Gamma_G$: if $M^\bullet$ is a cochain complex of $G$-modules, then $H^q(R\Gamma_G(M^\bullet)) = \mathbb H^q(G,M^\bullet)$.

Now by definition quasi-isomorphisms of cochain complexes are isomorphisms in the derived category. So the fact that group hypercohomology takes quasi-isomorphisms to isomorphisms is equivalent, in the language of derived categories, to the statement that $R\Gamma_G$ takes isomorphisms to isomorphisms. That is, the claim that you want is implicit in the statement that hypercohomology is a functor between derived categories.

So in a sense, once you know that group cohomology is a derived functor, then a reference for your statement is any textbook that explains how to talk about derived functors in the language of derived categories, e.g. Gelfand and Manin - Methods of homological algebra, Yekutieli's book "Derived categories", Verdier's thesis, or the Stacks project.

Answer 2

I give an elementary proof of the fact that a quasi-isomorphism of short complexes (complexes of length 2) of $\Gamma$-modules induces an isomorphism on hypercohomology. Actually, it is very close to Theorem 3.3 on page 16 of my preprint of 1992, where I prove that a quasi-isomorphism of crossed modules with $\Gamma$-action preserves ${\Bbb H}^0$ and ${\Bbb H}^1$ (for any profinite group $\Gamma$).

First I give my elementary cocyclic definitions of cohomology and hypercohomology.

Definition of cohomology

Let $A$ be a $\Gamma$-module, that is, an abelian group written additively, endowed with an action of $\Gamma=\{1,\gamma\}$. We consider the first cohomology group $H^1(\Gamma,A)$. We write $H^1\! A$ for $H^1(\Gamma,A)$. Recall that $$H^1\! A=Z^1\! A/B^1\! A,$$ where $$Z^1\! A=\{a\in A\mid\,^\gamma\! a=-a\}, \quad B^1\! A=\{\,^\gamma\! a'-a'\mid a'\in A\}.$$

We define the second cohomology group $H^2\!A$ by $$ H^2\!A=Z^2\! A/ B^2\! A,$$ where $$Z^2\! A=A^\Gamma:= \{a\in A\mid\, ^\gamma\! a=a\},\quad\ B^2\! A=\{\,^\gamma\! a'+a'\mid a'\in A\}.$$

For $k\in{\mathbb Z}$ we define the coboundary operator $$d^k\colon A\to A,\quad a\mapsto\,^\gamma\! a-(-1)^k a.$$ In other words, $d^k=\gamma-(-1)^k\in {\mathbb Z}[\Gamma]$, where ${\mathbb Z}[\Gamma]={\mathbb Z}\oplus{\mathbb Z}\gamma$ is the group ring of $\Gamma$. We calculate: \begin{align*} d^k\circ d^{k-1}=\big(\gamma-(-1)^k\big)\big(\gamma-(-1)^{k-1}\big)&=\big(\gamma-(-1)^k\big)\big(\gamma+(-1)^k\big)\\ &=\gamma^2-(-1)^{2k}=1-1=0. \end{align*} We see that $d^{k+1}\circ d^k=0$. We define the Tate cohomology groups $H^k_T A$ for all $k\in {\mathbb Z}$ by $$ H^k_T\, A=Z^k\! A/B^k\! A,$$ where \begin{align*} Z^k\! A=\ker d^k=\{a\in A\mid\,^\gamma\! a=(-1)^k a\},\quad B^k\! A={\rm im\,} d^{k-1}=\{\,^\gamma\! a'+(-1)^k a'\mid a'\in A\}. \end{align*} Then clearly $$H^k_T\, A=H^1\! A\quad\text{if $k$ is odd, $\ $ and}\quad H^k_T\, A=H^2\!A\ \ \text{if $k$ is even.}$$

Definition of hypercohomology

Let $A_0\overset{\partial}{\longrightarrow} A_0$ be a short complex of $\Gamma$-modules. For $k\in{\mathbb Z}$ we define a differential $$D^k\colon\, A_1\oplus A_0\to A_1\oplus A_0,\quad\ D(a_1,a_0)=\big(d^{k+1} a_1,\, d^k a_0-(-1)^k a_1\big).$$ We calculate: \begin{align*} D^k\big( D^{k-1}(a_1,a_0)\big)&=D^k\big(\, d^k a_1,\ d^{k-1} a_0-(-1)^{k-1} a_1\,\big)\\ &=\big(d^{k+1}d^k a_1,\ d^k d^{k-1} a_0-(-1)^{k-1}d^k a_1- (-1)^k d^k a_1\big)=0. \end{align*} Thus $D^k\circ D^{k-1}=0$.

We define the $k$-th Tate hypercohomology group ${\mathbb H}^k(A_{1}{\overset\partial\longrightarrow } A_0)$ by $$ {\mathbb H}^k(A_{1}{\overset\partial\longrightarrow } A_0)=Z^k(A_{1}{\overset\partial\longrightarrow } A_0)\,/\,B^k(A_{1}{\overset\partial\longrightarrow } A_0),$$ where \begin{align*} Z^k(A_{1}&{\overset\partial\longrightarrow } A_0)=\ker D^k=\\ &=\{(a_{1},a_0)\in A_{1}\oplus A_0,\,\, \mid\,d^{k+1} a_1=0,\, d^k a_0-(-1)^k\partial a_{1}=0\}, \\ B^k(A_{1}&{\overset\partial\longrightarrow } A_0)={\rm im\,} D^{k-1}=\\ &=\{(d^k a'_1,\ d^{k-1} a'_0-(-1)^{k-1}\partial a'_1\,) \,\mid\, (a'_1, a_0')\in A_1\oplus A_0\}. \end{align*}

Quasi-isomorphism induces isomorphism on hypercohomology

Proposition. If $\varphi=(\varphi_1,\varphi_0)\colon\, (A_1\overset{\partial}{\longrightarrow} A_0)\,\longrightarrow\, (A_1'\overset{\partial'}{\longrightarrow} A_0')$ is a quasi-isomorphism, then the induced homomorphism on hypercohomology $$\varphi_*\colon\ {\Bbb H}^k(\Gamma, A_1\to A_0)\,\to\, {\Bbb H}^k(\Gamma, A_1'\to A_0')$$ is an isomorphism.

Sketch of an elementary proof. From $A_1\overset{\partial}{\longrightarrow} A_0$, using the short exact sequence of complexes $$0\to(\ker\partial\to 0)\to (A_{1}\overset\partial\longrightarrow A_0)\to ({\rm im}\, \partial\hookrightarrow A_0)\to 0,$$ we obtain a long exact sequence $$\dots H^{k-1}{\rm coker}\,\partial\to H^{k+1}\ker\partial\to {\mathbb H}^k(A_{1}\overset\partial\longrightarrow A_0) \to H^k{\rm coker}\,\partial\to H^{k+2}\ker\partial\dots, $$ and similarly, from $A_1'\overset{\partial'}{\longrightarrow} A_0'$ we obtain a long exact sequence $$\dots H^{k-1}{\rm coker}\,\partial'\!\to\! H^{k+1}\ker\partial'\!\to\! {\mathbb H}^k(A_{1}'\!\overset{\partial'}\longrightarrow\! A_0') \!\to\! H^k{\rm coker}\,\partial'\!\to H^{k+2}\ker\partial'\!\dots $$ Our morphism $\varphi=(\varphi_1,\varphi_0)$ induces a morphism of the exact sequences, that is, a commutative diagram with exact rows. Since our morphism $\varphi$ is a quasi-isomorphism, the induced homomorphisms $$ H^{k}\ker\partial\to H^{k}\ker\partial'\quad\text{and} \quad H^k{\rm coker}\,\partial\to H^k{\rm coker}\,\partial' $$ are isomorphisms for all $k$, and by the five lemma we conclude that the induced homomorphism on hypercohomology $$\varphi_*\colon\ {\Bbb H}^k(\Gamma, A_1\to A_0)\,\to\, {\Bbb H}^k(\Gamma, A_1'\to A_0')$$ is an isomorphism, as required.