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Hilbert Series for Moduli Spaces of Two Instantons

1 Pith paper cite this work. Polarity classification is still indexing.

1 Pith paper citing it
abstract

The Hilbert Series (HS) of the moduli space of two G instantons on C^2, where G is a simple gauge group, is studied in detail. For a given G, the moduli space is a singular hyperKahler cone with a symmetry group U(2) \times G, where U(2) is the natural symmetry group of C^2. Holomorphic functions on the moduli space transform in irreducible representations of the symmetry group and hence the Hilbert series admits a character expansion. For cases that G is a classical group (of type A, B, C, or D), there is an ADHM construction which allows us to compute the HS explicitly using a contour integral. For cases that G is of E-type, recent index results allow for an explicit computation of the HS. The character expansion can be expressed as an infinite sum which lives on a Cartesian lattice that is generated by a small number of representations. This structure persists for all G and allows for an explicit expressions of the HS to all simple groups. For cases that G is of type G_2 or F_4, discrete symmetries are enough to evaluate the HS exactly, even though neither ADHM construction nor index is known for these cases.

fields

hep-th 1

years

2026 1

verdicts

UNVERDICTED 1

representative citing papers

Algorithmic Dualization of Unitary Circular Quivers

hep-th · 2026-07-01 · unverdicted · novelty 7.0

Develops an algorithmic construction of the full SL(2,Z) duality web for unitary circular quivers in 3d N=4 theories using QFT blocks, deriving mirror symmetry for good cases and providing index-matching evidence for bad cases.

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Showing 1 of 1 citing paper.

  • Algorithmic Dualization of Unitary Circular Quivers hep-th · 2026-07-01 · unverdicted · none · ref 63 · internal anchor

    Develops an algorithmic construction of the full SL(2,Z) duality web for unitary circular quivers in 3d N=4 theories using QFT blocks, deriving mirror symmetry for good cases and providing index-matching evidence for bad cases.