| Higher-dimensional algebra VI: Lie 2-algebras. Theory and Applications of Categories (2004) | |||||||||||||||
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| Abstract. The theory of Lie algebras can be categorified starting from a new notion of ‘2-vector space’, which we define as an internal category in Vect. There is a 2category 2Vect having these 2-vector spaces as objects, ‘linear functors ’ as morphisms and ‘linear natural transformations ’ as 2-morphisms. We define a ‘semistrict Lie 2algebra’ to be a 2-vector space L equipped with a skew-symmetric bilinear functor [·, ·]: L×L → L satisfying the Jacobi identity up to a completely antisymmetric trilinear natural transformation called the ‘Jacobiator’, which in turn must satisfy a certain law of its own. This law is closely related to the Zamolodchikov tetrahedron equation, and indeed we prove that any semistrict Lie 2-algebra gives a solution of this equation, just as any Lie algebra gives a solution of the Yang–Baxter equation. We construct a 2category of semistrict Lie 2-algebras and prove that it is 2-equivalent to the 2-category of 2-term L∞-algebras in the sense of Stasheff. We also study strict and skeletal Lie 2-algebras, obtaining the former from strict Lie 2-groups and using the latter to classify Lie 2-algebras in terms of 3rd cohomology classes in Lie algebra cohomology. This classification allows us to construct for any finite-dimensional Lie algebra g a canonical 1-parameter family of Lie 2-algebras g � which reduces to g at � = 0. These are closely related to the 2-groups G � constructed in a companion paper. 1. | |||||||||||||||
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