A Family of Instanton-Invariants for Four-Manifolds and Their Relation to Khovanov Homology
Abstract
This article provides a review of the gauge-theoretic approach to Khovanov homology, framed in terms of a generalisation of Witten's original proposal. Concretely, the physical arguments underlying Witten's insights suggest that there is a one-parameter family of Haydys-Witten instanton Floer homology groups HFθ(W4) for four-manifolds. At the heart of the proposal is a systematic investigation of the dimensional reductions of the Haydys-Witten equations. It is shown that on the five-dimensional cylinder M5=Rs× W4 with nowhere-vanishing vector field v=θ ∂s+θ w, the Haydys-Witten equations provide flow equations for the θ-Kapustin-Witten equations on W4. Similar reductions to lower dimensions include the twisted extended Bogomolny equations on three-manifolds and the twisted octonionic Nahm equations on one-manifolds, whose solutions provide natural boundary conditions along the boundary and corners of W4. These reductions determine the indicial roots of the Haydys-Witten and θ-Kapustin-Witten equations with twisted Nahm-pole boundary conditions, which are required to establish elliptic regularity. Motivated by these insights, the groups HFθ(W4) are defined in analogy with Yang-Mills instanton Floer theory: solutions of the θ-Kapustin-Witten equations on W4 modulo Haydys-Witten instantons on the cylinder Rs× W4 interpolating between them. The relation to knot invariants observed by Witten arises when the four-manifold is the geometric blow-up W4=[X3×R+,K] along a knot K⊂ X3×0 in its three-dimensional boundary. This yields a precise restatement of Witten's conjecture as the equality between HFπ/2([S3×R+,K]) and Khovanov homology Kh(K).
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