Transversally elliptic complex and cohomological field theory

“…This paper is the logical continuation of two our previous works [9] and [10] where we studied N = 2 supersymmetric 4D Yang-Mills on a curved manifold that admits a Killing vector with isolated fixed points. We constructed Killing spinors, defined the corresponding supersymmetry transformations and presented a supersymmetric action.…”

“…The localization locus of this theory is controlled by this generalized notion of self-duality and the corresponding PDEs are transversely elliptic. In [10] we studied the formal aspects of the transverse ellipticity and its significance for the gauge theory. At the moment however we do not have a good analytical control of the PDEs that are responsible for the localization locus, hence we can only conjecture the final answer for the partition function of the theory.…”

“…If we want to localize, we need to add additional fields to deal with the gauge symmetry, (c, c, b): ghost, anti-ghost and a Lagrangian multiplier. The resulting cohomological theory is controlled by a transversely elliptic complex (see [10]) and the corresponding localization locus is described in terms of transversely elliptic PDEs (or various deformations thereof). It is hard to say something definite about the localization locus beside a general conjecture that the path integral is dominated by point like (anti)-instantons and fluxes when the manifold is simply connected.…”

“…When discussing the cohomological theory we use the conventions in[10] that differ from those of[9].In particular δ 2 = Lv − [φ − v µ Aµ , ] instead of δ 2 = iLv − i[φ + iv µ Aµ , ]. This eliminates factors of i in many formulas.…”

S-duality and supersymmetry on curved manifolds

“…This paper is the logical continuation of two our previous works [9] and [10] where we studied N = 2 supersymmetric 4D Yang-Mills on a curved manifold that admits a Killing vector with isolated fixed points. We constructed Killing spinors, defined the corresponding supersymmetry transformations and presented a supersymmetric action.…”

“…The localization locus of this theory is controlled by this generalized notion of self-duality and the corresponding PDEs are transversely elliptic. In [10] we studied the formal aspects of the transverse ellipticity and its significance for the gauge theory. At the moment however we do not have a good analytical control of the PDEs that are responsible for the localization locus, hence we can only conjecture the final answer for the partition function of the theory.…”

“…If we want to localize, we need to add additional fields to deal with the gauge symmetry, (c, c, b): ghost, anti-ghost and a Lagrangian multiplier. The resulting cohomological theory is controlled by a transversely elliptic complex (see [10]) and the corresponding localization locus is described in terms of transversely elliptic PDEs (or various deformations thereof). It is hard to say something definite about the localization locus beside a general conjecture that the path integral is dominated by point like (anti)-instantons and fluxes when the manifold is simply connected.…”

“…When discussing the cohomological theory we use the conventions in[10] that differ from those of[9].In particular δ 2 = Lv − [φ − v µ Aµ , ] instead of δ 2 = iLv − i[φ + iv µ Aµ , ]. This eliminates factors of i in many formulas.…”

S-duality and supersymmetry on curved manifolds

“…All the theories considered in [1] can be written in terms of cohomological (twisted) fields which helps elucidating what data, of geometrical or other origin, their supersymmetric observables can depend on. These results were formulated in a more rigorous mathematical framework in [32].…”

Cohomological localization of $$ \mathcal{N} $$ = 2 gauge theories with matter

Partition functions and fibering operators on the Coulomb branch of 5d SCFTs