nLab tensor product of infinity-modules

Skip the Navigation Links | Home Page | All Pages | Latest Revisions | Discuss this page |
Redirected from "tensor product of (∞,1)-modules".
Contents

Context

Higher algebra

higher algebra

universal algebra

Algebraic theories

Algebras and modules

Higher algebras

Model category presentations

Geometry on formal duals of algebras

Theorems

Contents

Idea

The generalization of the notion of tensor product of modules to ∞-modules.

Definition

We start by defining a collection of colored symmetric operad Tens Tens^\otimes parameterized by the simplex category Δ\Delta such that for each kk-simplex [k]Delta[k] \in Delta the algebras over an operad over Tens [k] Tens^\otimes_{[k]} are (n+1)(n+1)-tuples of associative algebras (A i)(A_i) together with a consecutive sequence of bimodules over these (the right algebra of every bimodule being the left algebra of the next one).

The definition is a straightforward generalization of the of the operad for modules and the operad for bimodules.

Definition

Write Tens Tens^\otimes for the category (to be thought of as a family of categories of operators of symmetric operads) whose

  • objects are triples consisting of

    • an object nAssoc \langle n\rangle \in Assoc^\otimes of the category of operators of the associative operad;

    • an object [k]Δ[k] \in \Delta of the simplex category;

    • two functions c ,c +:n [k]c_-, c_+ \colon \langle n\rangle^\circ \to [k] such that for all iinn i in \langle n\rangle^\circ either c +(i)=c (i)c_+(i) = c_-(i) or c +(i)=c (i)+1c_+(i) = c_-(i) + 1;

  • morphisms consist if

    • a morphism α:nn\alpha \colon \langle n\rangle \to \langle n'\rangle in Assoc Assoc^\otimes

    • a morphism λ:[k][k]\lambda \colon [k'] \to [k] in Δ\Delta

    such that (…)

(Lurie, def. 4.3.4.1)

We disuss how an object of this category is to be thought of as labeled with “algebra labels 𝔞 i\mathfrak{a}_i” for vertices of a simplex, an “bimodule lables 𝔫 i,j\mathfrak{n}_{i, j}” for edges of the simplex.

Remark

By construction there are forgetful functors

Δ opTens 𝒜𝓈𝓈 . \Delta^{op} \leftarrow Tens^\otimes \rightarrow \mathcal{Ass}^\otimes \,.

(Lurie, 4.3.4.1)

Definition (Notation)

For SΔ opS \to \Delta^{op} an (∞,1)-functor (given as a map of simplicial sets from a quasi-category SS to the nerve of the simplex category), write

Tens S Tens ×Δ opS Tens^\otimes_{S} \coloneqq Tens^\otimes \underset{\Delta^{op}}{\times} S

for the fiber product in sSet.

(Lurie, notation 4.3.4.5, 4.3.4.15)

Proposition

We have

  • Tens [0] Assoc Tens^\otimes_{[0]} \simeq Assoc^\otimes, the associative operad;

  • Tens [1] BM Tens^\otimes_{[1]} \simeq BM^\otimes the operad for bimodules.

  • Tens [k] Tens {0,1} Tens {1} Tens {1,2} Tens {2} Tens {k1} Tens {k1,k} Tens^\otimes_{[k]} \simeq Tens^\otimes_{\{0,1\}} \underset{Tens^\otimes_{\{1\}}}{\coprod} Tens^\otimes_{\{1,2\}} \underset{Tens^\otimes_{\{2\}}}{\coprod} \cdots \underset{Tens^\otimes_{\{k-1\}}}{\coprod} Tens^\otimes_{\{k-1,k\}}

    as an (∞,1)-colimit in the (∞,1)-category of (∞,1)-operads (a dual Segal condition)

(Lurie, example 4.3.4.6, 4.3.4.7, prop. 4.3.4.11)

Remark

Prop. implies that for 𝒞 \mathcal{C}^\otimes an (∞,1)-operad, the (∞,1)-algebras over an (∞,1)-operad over the fiber Tens [k] Tens^\otimes_{[k]} in 𝒞\mathcal{C} form the (∞,1)-category

Alg Tens [k] (𝒞)BMod(𝒞)×Alg(𝒞)BMod(𝒞)×Alg(𝒞)×Alg(𝒞)BMod(𝒞) kfactors. Alg_{Tens^\otimes_{[k]}}(\mathcal{C}) \simeq \underbrace{ BMod(\mathcal{C}) \underset{Alg(\mathcal{C})}{\times} BMod(\mathcal{C}) \underset{Alg(\mathcal{C})}{\times} \cdots \underset{Alg(\mathcal{C})}{\times} BMod(\mathcal{C}) }_{k\;factors} \,.

(Lurie, 4.3.5)

Definition (Notation)

For 𝒞 Tens S \mathcal{C}^\otimes \to Tens^\otimes_S a fibration in the model structure for quasi-categories which exhibits 𝒞 \mathcal{C}^\otimes as an SS-family of (∞,1)-operads, write

Alg S(𝒞)Fun Tens S (Step S,𝒞 ) Alg_S(\mathcal{C}) \hookrightarrow Fun_{Tens^\otimes_S}(Step_S, \mathcal{C}^\otimes)

for the full sub-(∞,1)-category on those (∞,1)-functors which send inert morphisms to inert morphisms.

(Lurie, notation 4.3.4.15)

Proposition

For an (∞,1)-functor SΔ opS \to \Delta^{op} and a fibration in the model structure for quasicategories q:𝒞 Tens S q \colon \mathcal{C}^\otimes \to Tens_S^\otimes exhibiting 𝒞 \mathcal{C}^\otimes as an SS-family of (∞,1)-operads, then there is an equivalence of (∞,1)-categories

Alg /Tens S(𝒞)Alg S(𝒞). Alg_{/Tens_S}(\mathcal{C}) \to Alg_S(\mathcal{C}) \,.

(Lurie, prop. 4.3.4.17).

Definition (Notation)

Let Δ 1Δ op\Delta^1 \to \Delta^{op} be the map that picks the morphism {0,2}Δ 2\{0,2\} \hookrightarrow \Delta^2 in the simplex category. With def. write

Tens > Tens Δ 1 Tens ×Δ opΔ 1. Tens^\otimes_{\gt} \coloneqq Tens_{\Delta^1}^\otimes \coloneqq Tens^\otimes \underset{\Delta^{op}}{\times} \Delta^1 \,.

(Lurie, notation 4.3.5.1)

Remark

The Tens > Tens^\otimes_{\gt} of def. is a correspondence of (∞,1)-operads which exhibits bilinear maps as follows:

An ∞-algebra over an (∞,1)-operad γ 1:Tens > × Δ 1{1}𝒞 \gamma_1 \colon Tens^\otimes_{\gt} \times_{\Delta^1} \{1\} \to \mathcal{C}^\otimes is equivalently a bimodule

X AMod(𝒞) C, X \in {}_{A'} Mod(\mathcal{C})_{C'} \,,

while an \infty-algebra γ 0:Tens > × Δ 1{0}𝒞 \gamma_0 \colon Tens^\otimes_{\gt} \times_{\Delta^1} \{0\} \to \mathcal{C}^\otimes is equivalently a pair of bimodules

N 1 AMod(𝒞) B,N 2 BMod(𝒞) C. N_1 \in {}_A Mod(\mathcal{C})_B \;\;, \;\; N_2 \in {}_B Mod(\mathcal{C})_C \,.

An extension of (γ 0,γ 1)(\gamma_0, \gamma_1) through the correspondence hence to a map of generalized (∞,1)-operads Tens > 𝒞 Tens^\otimes_{\gt} \to \mathcal{C}^\otimes is equivalently a pair of A-∞ algebra maps AAA \to A' and BBB \to B' together with a bilinear map N 1N 2XN_1 \otimes N_2 \to X.

([Lurie, beginning of 4.3.4]).

Definition

(relative tensor product of \infty-bimodules)

For q:𝒞 𝒪 q \colon \mathcal{C}^\otimes \to \mathcal{O}^\otimes a fibration of (∞,1)-operads, consider a morphism of generalized (∞,1)-operads

F:Tens > 𝒞 . F \colon Tens_{\gt}^\otimes \to \mathcal{C}^{\otimes} \,.

This exhibits three A-∞ algebras A iF| {i}A_i \coloneqq F|_{\{i\}}, a pair of bimodule objects

(N 1,N 2)=F| [2] (N_1, N_2) = F|_{[2]}

over A 0A_0-A 1A_1 and over A 1A_1-A 2A_2, respectively, and a bimodule object N=F| [1]N = F|_{[1]} over A 0A_0-A 2A_2. We say that NN exhibits the relative tensor product of ∞-modules of N 1N_1 with N 2N_2 over A 1A_1

NN 1 A 1N 2 N \simeq N_1 \otimes_{A_1} N_2

if FF is an operadic qq-(∞,1)-colimit-diagram.

(Lurie, def. 4.3.5.3).

Remark

Let 𝒞 Assoc \mathcal{C}^\otimes \to Assoc^\otimes exhibit a monoidal (∞,1)-category such that 𝒞\mathcal{C} has geometric realization of simplicial objects and the tensor product preserves these separately in each argument.

Then the tensor product of \infty-modules def. extends to an (∞,1)-functor

BMod(𝒞)×Alg(𝒞)BMod(𝒞)BMod(𝒞). BMod(\mathcal{C}) \underset{Alg(\mathcal{C})}{\times} BMod(\mathcal{C}) \to BMod(\mathcal{C}) \,.

(Lurie, example 4.3.5.11)

References

Section 4.3.5 of

Last revised on February 12, 2013 at 13:03:25. See the history of this page for a list of all contributions to it.

EditDiscussPrevious revisionChanges from previous revisionHistory (4 revisions) Cite Print Source