Section 24.15 (0FRM): Tensor product for sheaves of differential graded modules

24.15 Tensor product for sheaves of differential graded modules

This section is the analogue of part of Differential Graded Algebra, Section 22.12.

Let $(\mathcal{C}, \mathcal{O})$ be a ringed site. Let $(\mathcal{A}, \text{d})$ be a sheaf of differential graded algebras on $(\mathcal{C}, \mathcal{O})$. Let $\mathcal{M}$ be a right differential graded $\mathcal{A}$-module and let $\mathcal{N}$ be a left differential graded $\mathcal{A}$-module. In this situation we define the tensor product $\mathcal{M} \otimes _\mathcal {A} \mathcal{N}$ as follows. As a graded $\mathcal{O}$-module it is given by the construction in Section 24.6. It comes endowed with a differential

\[ \text{d}_{\mathcal{M} \otimes _\mathcal {A} \mathcal{N}} : (\mathcal{M} \otimes _\mathcal {A} \mathcal{N})^ n \longrightarrow (\mathcal{M} \otimes _\mathcal {A} \mathcal{N})^{n + 1} \]

defined by the rule that

\[ \text{d}_{\mathcal{M} \otimes _\mathcal {A} \mathcal{N}}(x \otimes y) = \text{d}_\mathcal {M}(x) \otimes y + (-1)^{\deg (x)}x \otimes \text{d}_\mathcal {N}(y) \]

for homogeneous local sections $x$ and $y$ of $\mathcal{M}$ and $\mathcal{N}$. To see that this is well defined we have to show that $\text{d}_{\mathcal{M} \otimes _\mathcal {A} \mathcal{N}}$ annihilates elements of the form $xa \otimes y - x \otimes ay$ for homogeneous local sections $x$, $a$, $y$ of $\mathcal{M}$, $\mathcal{A}$, $\mathcal{N}$. We compute

\begin{align*} & \text{d}_{\mathcal{M} \otimes _\mathcal {A} \mathcal{N}}( xa \otimes y - x \otimes ay) \\ & = \text{d}_\mathcal {M}(xa) \otimes y + (-1)^{\deg (x) + \deg (a)} xa \otimes \text{d}_\mathcal {N}(y) -\text{d}_\mathcal {M}(x) \otimes ay - (-1)^{\deg (x)} x \otimes \text{d}_\mathcal {N}(ay) \\ & = \text{d}_\mathcal {M}(x)a \otimes y + (-1)^{\deg (x)}x\text{d}(a) \otimes y + (-1)^{\deg (x) + \deg (a)} xa \otimes \text{d}_\mathcal {N}(y) \\ & -\text{d}_\mathcal {M}(x) \otimes ay - (-1)^{\deg (x)} x \otimes \text{d}(a)y - (-1)^{\deg (x) + \deg (a)} x\otimes a\text{d}_\mathcal {N}(y) \end{align*}

then we observe that the elements

\[ \text{d}_\mathcal {M}(x)a \otimes y - \text{d}_\mathcal {M}(x) \otimes ay,\quad x\text{d}(a) \otimes y - x \otimes \text{d}(a)y,\quad \text{and}\quad xa \otimes \text{d}_\mathcal {N}(y) - x\otimes a\text{d}_\mathcal {N}(y) \]

map to zero in $\mathcal{M} \otimes _\mathcal {A} \mathcal{N}$ and we conclude. We omit the verification that $\text{d}_{\mathcal{M} \otimes _\mathcal {A} \mathcal{N}} \circ \text{d}_{\mathcal{M} \otimes _\mathcal {A} \mathcal{N}} = 0$.

If we fix the left differential graded $\mathcal{A}$-module $\mathcal{N}$ we obtain a functor

\[ - \otimes _\mathcal {A} \mathcal{N} : \textit{Mod}(\mathcal{A}, \text{d}) \longrightarrow \text{Comp}(\mathcal{O}) \]

where on the right hand side we have the category of complexes of $\mathcal{O}$-modules. This can be upgraded to a functor of differential graded categories

\[ - \otimes _\mathcal {A} \mathcal{N} : \textit{Mod}^{dg}(\mathcal{A}, \text{d}) \longrightarrow \text{Comp}^{dg}(\mathcal{O}) \]

On underlying graded objects, we send a homomorphism $f : \mathcal{M} \to \mathcal{M}'$ of degree $n$ to the degree $n$ map $f \otimes \text{id}_\mathcal {N} : \mathcal{M} \otimes _\mathcal {A} \mathcal{N} \to \mathcal{M}' \otimes _\mathcal {A} \mathcal{N}$, because this is what we did in Section 24.6. To show that this works, we have to verify that the map

\[ \mathop{\mathrm{Hom}}\nolimits _{\textit{Mod}^{dg}(\mathcal{A}, \text{d})}(\mathcal{M}, \mathcal{M}') \longrightarrow \mathop{\mathrm{Hom}}\nolimits _{\text{Comp}^{dg}(\mathcal{O})}( \mathcal{M} \otimes _\mathcal {A} \mathcal{N}, \mathcal{M}' \otimes _\mathcal {A} \mathcal{N}) \]

is compatible with differentials. To see this for $f$ as above we have to show that

\[ (\text{d}_{\mathcal{M}'} \circ f - (-1)^ n f \circ \text{d}_\mathcal {M}) \otimes \text{id}_\mathcal {N} \]

is equal to

\[ \text{d}_{\mathcal{M}' \otimes _\mathcal {A} \mathcal{N}} \circ (f \otimes \text{id}_\mathcal {N}) - (-1)^ n (f \otimes \text{id}_\mathcal {N}) \circ \text{d}_{\mathcal{M} \otimes _\mathcal {A} \mathcal{N}} \]

Let us compute the effect of these operators on a local section of the form $x \otimes y$ with $x$ and $y$ homogeneous local sections of $\mathcal{M}$ and $\mathcal{N}$. For the first we obtain

\[ (\text{d}_{\mathcal{M}'}(f(x)) - (-1)^ n f(\text{d}_\mathcal {M}(x))) \otimes y \]

and for the second we obtain

\begin{align*} & \text{d}_{\mathcal{M}' \otimes _\mathcal {A} \mathcal{N}}(f(x) \otimes y) - (-1)^ n (f \otimes \text{id}_\mathcal {N})( \text{d}_{\mathcal{M} \otimes _\mathcal {A} \mathcal{N}}(x \otimes y) \\ & = \text{d}_{\mathcal{M}'}(f(x)) \otimes y + (-1)^{\deg (x) + n}f(x) \otimes \text{d}_\mathcal {N}(y) \\ & -(-1)^ n f(\text{d}_\mathcal {M}(x)) \otimes y -(-1)^ n (-1)^{\deg (x)}f(x) \otimes \text{d}_\mathcal {N}(y) \end{align*}

which is indeeed the same local section.

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24.15 Tensor product for sheaves of differential graded modules

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