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Derived Differentiable Manifolds
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Derived Differentiable Manifolds
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We develop the theory of derived differential geometry in terms of bundles of curved $L_\infty[1]$-algebras, i.e. dg manifolds of positive amplitudes. We prove the category of derived manifolds is a category of fibrant objects. Therefore, we can make sense of "homotopy fibered product" and "derived intersection" of submaifolds in a smooth manifold in the homotopy category of derived manifolds. We construct a factorization of the diagonal using path spaces. First we construct an infinite-dimensional factorization using actual path spaces motivated by the AKSZ construction, then we cut down to finite dimensions using the Fiorenza-Manetti method. The main ingredient is the homotopy transfer theorem for curved $L_\infty[1]$-algebras. We also prove the inverse function theorem for derived manifolds, and investigate the relationship between weak equivalence and quasi-isomorphism for derived manifolds.
Forward citations
Cited by 3 Pith papers
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From $L_\infty$ algebroids to $L_\infty$ spaces: Part I
Develops L∞ spaces over dg manifolds and establishes an equivalence of categories with transitive L∞ algebroids (plus a faithful functor) both detecting weak equivalences.
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Categorical structures of Kuranishi spaces with $L_{\infty}[1]$-algebras
Defines L∞-Kuranishi spaces via L∞[1]-algebras on Kuranishi charts and proves they form a category embedding smooth manifolds, by modifying conditions from prior work.
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Homotopy theory for curved $L_\infty$ spaces
Proves L_∞ spaces over dg manifolds form a category of fibrant objects, implying the same for transitive L_∞ algebroids via companion paper.
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