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Keywords:
model category; homotopy theory; derived functor; $D$-module; $D$-geometry; homotopical geometry; Tor functor; spectral sequence
model category; homotopy theory; derived functor; $D$-module; $D$-geometry; homotopical geometry; Tor functor; spectral sequence
Summary:
Homotopical algebraic $D$-geometry combines aspects of homotopical algebraic geometry and $D$-geometry. It was introduced in as a suitable framework for a coordinate-free study of the Batalin-Vilkovisky complex and more generally for the study of non-linear partial differential equations and their symmetries. In order to consolidate the foundation of the theory, we have to prove that the standard methods of linear and commutative algebra are available in the context of homotopical algebraic $D$-geometry, and we must show that in this context the eeetale topology is a kind of homotopical Grothendieck topology and that the notion of smooth morphism is, roughly speaking, local for the eeetale topology. The first half of this work was done in. The remaining part covers the study of eeetale and flat morphisms in the category of differential graded $D$-algebras and is based on the Tor spectral sequence which connects the graded Tor functors in homology with the homology of the derived tensor product of two differential graded $D$-modules over a differential graded $D$-algebra.
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