Higher-order gaugino condensates on a twisted T4: In the beginning was semi-classics

Abstract

We compute the gaugino condensates, Πi=1k tr(λλ)(xi) for 1 ≤ k N-1, in SU(N) super Yang-Mills theory on a small four-dimensional torus T4, subject to 't Hooft twisted boundary conditions. Two recent advances are crucial to performing the calculations and interpreting the result: the understanding of generalized anomalies involving 1-form center symmetry and the construction of multi-fractional instantons on the twisted T4. These self-dual classical configurations have topological charge k/N and can be described as a sum over k closely packed lumps in an instanton liquid. Using the path integral formalism, we perform the condensate calculations in the semi-classical limit and find, assuming gcd(k,N)=1, Πi=1k tr(λλ)(xi) = n-1 \; N2(16π2 3)k, where is the strong-coupling scale and n is a normalization constant. We determine the normalization constant, using path integral, as n = N2, which is N times larger than the normalization used in our earlier publication arXiv:2210.13568. This finding resolves the extra-factor-of-N discrepancy encountered there, aligning our results with those obtained through direct supersymmetric methods on R4. The normalization constant n can be understood within the Euclidean path-integral framework as the Witten index IW. From the Hamiltonian approach, it is well-established that IW = N. While the value n = N2 correctly reproduces the condensate result, this discrepancy between the Hamiltonian and path-integral formulations calls for reconciliation. We attempt to provide a potential solution we outline in our discussion.