Abstract
In this work, we first solve complex Morse flow equations for the simplest case of a bosonic harmonic oscillator to discuss localization in the context of Picard-Lefschetz theory. We briefly touch on the exact non-BPS solutions of the bosonized supersymmetric quantum mechanics on algebraic geometric grounds and report that their complex phases can be accessed through the cohomology of WKB 1-form of the underlying singular spectral curve subject to necessary cohomological corrections for non-zero genus. Motivated by Picard-Lefschetz theory, we write down a general formula for the index of $\mathcal{N} = 4$ quantum mechanics with background $R$-symmetry gauge fields. We conjecture that certain symmetries of the refined Witten index and singularities of the moduli space may be used to determine the correct intersection coefficients. A few examples, where this conjecture holds, are shown in both linear and closed quivers with rank-one quiver gauge groups. The $R$-anomaly removal along the "Morsified" relative homology cycles also called "Lefschetz thimbles" is shown to lead to the appearance of Stokes lines. We show that the Fayet-Iliopoulos (FI) parameters appear in the intersection coefficients for the relative homology of the quiver quantum mechanics resulting from dimensional reduction of $2d$ $\mathcal{N}=(2,2)$ gauge theory on a circle and explicitly calculate integrals along the Lefschetz thimbles in $\mathcal{N}=4$ $\mathbb{CP}^{k-1}$ model. The Stokes jumping of coefficients and its relation to wall crossing phenomena is briefly discussed. We also find that the notion of "on-the-wall" index is related to the invariant Lefschetz thimbles under Stokes phenomena. An implication of the Lefschetz thimbles in constructing knots from quiver quantum mechanics is indicated.
Highlights
AND SUMMARYSupersymmetric quantum mechanics is a very fruitful tool for studying mathematical properties of manifolds and algebraic curves
At least from a topological standpoint, supersymmetric quantum mechanics boils down to calculating the ground states and their proper counting based on their parity under the action of ð−1ÞF operator where F is the fermion number operator
We argue that for singular algebraic curves of supersymmetric quantum mechanics with nonzero genus, apart from higher order quantum corrections, the WKB 1-form is not enough to capture the complex phases of its saddle configurations hidden in the topology of thimbles, so it needs to be corrected by considering the sheaf of holomorphic 1forms
Summary
Supersymmetric quantum mechanics is a very fruitful tool for studying mathematical properties of manifolds and algebraic curves. In the context of supersymmetric theories in physics, the invariant measured by this relative homology is usually a Witten-type index, which by a clue from the bosonic harmonic theory discussed above, roots back to localization to Lefschetz thimbles attached to BPS configurations This holomorphization procedure for any path integral over a field space ΓR yields an equivalent formulation with a path integral over an integration cycle in the complexified field space ΓC, such that we can write the path integral as. This enables us to define the irreducible J-set whose elements J a are (1) generators of HkðF; Fτ⋆Þ and (2) form a homotopy class 1⁄2J aπ where 1⁄2:π means “modulo path homotopy.” This removes the degeneracy of saddle points in theory and renders a clear interpretation of the homological quantum mechanics in the presence of a gauge group action, provided that the intersection coefficients be determined by the Witten index check or other alternative checks discussed in Sec. V C. We explain the connection between degenerate (or singular) spectral curves and non-BPS solutions to the integrable/quasiexact-solvable systems related to them
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