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The Cahiers topos being the sheaf topos on the site SDCartSp of infinitessimally thickened cartesian spaces is an important example of a differentially cohesive toppos. More generally the higher cahiers topos being the -sheaf -topos on the -site SDCartSp is an important example of a differentially cohesive -topos.
However the -topos arising in this way is (still) a 1-localic (i.e. localic) -topos; in other words this notion of higher cahiers topos is no more intelligible than just the classical Cahiers topos. In fact there hasn’t been described any example of a differentially cohesive non-localic -topos.
What is ? The construction is a follows: Let denote the opposite of the category of cartesian spaces of finite dimension (as -vector spaces, so these are essentially of the form ). is the syntactic category of the Lawvere theory of smooth algebras. Define to be the subcategory of Weil algebras; i.e. the subcategory on those objects having as vector space at least dimension and which are nilpotent as algebras. Then is defined to be the category of objects being of the form a product with and .
By substituting into this receipt (see below) for we obtain the notion of higher derived Cahiers topos which is not -localic for any . In the following shall be argued that it is differentially cohesive.
Let denote the ∞-category of spectra, the ∞-category of commutative algebra objects in , for let denote the category of -module objects in . A derived moduli problem is defined to be a functor (There is also a notion of classical moduli problem where an instance is called to be enhanced by an associated derived moduli problem). For a field let denote the coslice of over and call it the ∞-category of -algebras; such a -algebra is called to be discrete if its homotopy groups vanish for .
An object of the symmetric monoidal (by the usual tensor product) category of chain complexes over is called a commutative differential graded algebra over . There are functors and . A quasi-isomorphism in is defined to be a morphism inducing an isomorphism between the underlying chain complexes. There is a notion of smallness for -module spectra and -algebras over (see below); the corresponding full sub ∞-categories are denoted by resp. . A formal moduli problem over is defined to be a functor such that is contractible and preserves pullbacks of maps inducing epimorphisms between the -th homotopy groups.
The (Grothendieck) tangent space of a formal moduli problem is defined to be a map . is a topological space. Define where denotes the -fold shift of (as a -module spectrum). One can elaborate that is the loop space of ; define the tangent complex of the formal moduli problem to be the sequence ; is a -module spectrum. The operation reflects equivalences.
Let be a field of characteristic zero. A differential graded Lie algebra over is defined to be a Lie algebra object in : a chain complex equipped with a binary operation such that and for homogenous elements . The category of differential graded Lie algebras over localized at quasi-isomorphisms is denoted by and just also called the category of differential graded Lie algebras over .
(Theorem 5.3): Let be a field of characteristic zero, let the full subcategory spanned by formal moduli problems over , let denotes the ∞-category of differential graded Lie algebras over . Then there is an equivalence .
We first summarize the proof for the -localic case from [Schr11] Proposition 4.5.8: A covering family in is define to be of the form where is a covering family in . Hence such a covering family by definition does not depend on the thickening components . ?: Since all are contractible a morphism is an epimorphisms iff is an epimorphism. Thus it suffices to show that is an -cohesive site: has finite products given by . Every object has a point . Let be a good open covering family. This implies that the Cech nerve is degree-wise a coproduct of representables. Hence the nerve theorem implies is an equivalence (the statement of the nerve theorem is that is an equivalence, our statement is then implied by the fact that as a cartesian space is contractible). Finally is an equivalence: The morphism has the right lifting property wrt. all boundary inclusions and hence it is an equivalence.
Now we define the -site : Let be a field. Define , . For an associative ring let ; i.e. the category of chain complexes of -modules modulo quasi-isomorphisms. (Definition 4.4): An object is called to be small if (1) For every integer , the homotopy group is a finite dimensional -vector space. (2) vanishes for and . An object is called to be small if it is small as a -module spectrum and satisfies (3): The commutative ring has a unique maximal ideal and the composite map is an isomorphism. The full subcategory of spanned by the small -module spectra is denoted by . The full subcategory of spanned by the small -algebras over is denoted by . And we take
and we could write (where by Remark 4.3). We define
meaning the semi-direct product of categories: there is a functor which we identify with the
(…)
Semidirect product of categories are described in (Kock p.12). In more modern terminology and generalized to quasicategories this reads: Let be a category which is (left) tensored over . Then the category is defined to have as objects pair and a morphism is defined to be a pair . Composition of this morphism with is defined to be the pair
The identity morphism in is defined to be where denotes the initial object of . There is a (full) embedding given by and . This embedding preserves all limits which are preserved by all . If has exponential object which are preserved by all (in that ) and if preserves finite products, then the embedding preserves exponential objects.
Lemma: The semidirect product of an ∞-cohesive ∞-site with an ∞-site equipped with trivial topology is an ∞-cohesive ∞-site in that the ∞-sheaf ∞-topos on is is a cohesive ∞-topos.
Proof: adapt the proof of Schr11, Proposition 3.4.9, p.198-199:
Jacob Lurie, Formal moduli problems, containing: DAGX: Formal Moduli Problems, 2011, (166 p.). And another more condensed (30 p.) version of this text titled “Moduli Problems and DG-Lie Algebras”. In particular Theorem 5.3 in the second version
Vladimir Hinich, DG coalgebras as formal stacks, arXiv:math/9812034
Urs Schreiber, Differential cohomology in a cohesive -topos
David Carchedi, Dmitry Roytenberg, On Theories of Superalgebras of Differentiable Functions, arXiv:1211.6134
Lawvere et al, algebraic theories, Cambridge University Press 2010
Martin Hyland, The category theoretic understanding of universal algebra Lawvere theories and monads, pdf.
Anders Kock, Convenient vector spaces embed into the Cahiers topos, web