We apply localization techniques to compute the partition function of a two-dimensional N = (2, 2) R-symmetric theory of vector and chiral multiplets on S 2 . The path integral reduces to a sum over topological sectors of a matrix integral over the Cartan subalgebra of the gauge group. For gauge theories which would be completely Higgsed in the presence of a Fayet-Iliopoulos term in flat space, the path integral alternatively reduces to the product of a vortex times an antivortex partition functions, weighted by semiclassical factors and summed over isolated points on the Higgs branch. As applications we evaluate the partition function for some U(N) gauge theories, showing equality of the path integrals for theories conjectured to be dual by Hori and Tong and deriving new expressions for vortex partition functions.
This paper addresses a long standing problem -to identify the chiral ring and moduli space (i.e. as an algebraic variety) on the Coulomb branch of an N = 4 superconformal field theory in 2+1 dimensions. Previous techniques involved a computation of the metric on the moduli space and/or mirror symmetry. These methods are limited to sufficiently small moduli spaces, with enough symmetry, or to Higgs branches of sufficiently small gauge theories. We introduce a simple formula for the Hilbert series of the Coulomb branch, which applies to any good or ugly three-dimensional N = 4 gauge theory. The formula counts monopole operators which are dressed by classical operators, the Casimir invariants of the residual gauge group that is left unbroken by the magnetic flux. We apply our formula to several classes of gauge theories. Along the way we make various tests of mirror symmetry, successfully comparing the Hilbert series of the Coulomb branch with the Hilbert series of the Higgs branch of the mirror theory.
We study Seiberg-like dualities in three dimensional N = 2 supersymmetric theories, emphasizing Chern-Simons terms for the global symmetry group, which affect contact terms in two-point functions of global currents and are essential to the duality map. We introduce new Seiberg-like dualities for Yang-Mills-Chern-Simons theories with unitary gauge groups with arbitrary numbers of matter fields in the fundamental and antifundamental representations. These dualities are derived from Aharony duality by real mass deformations. They allow to initiate the systematic study of Seiberg-like dualities in Chern-Simons quivers. We also comment on known Seiberg-like dualities for symplectic and orthogonal gauge groups and extend the latter to the Yang-Mills case. We check our proposals by showing that the localized partition functions on the squashed S 3 match between dual descriptions.
Using AdS/CFT, we study the addition of an arbitrary number of backreacting flavors to the Klebanov-Witten theory, making many checks of consistency between our new Type IIB plus branes solution and expectations from field theory. We study generalizations of our method for adding flavors to all N = 1 SCFTs that can be realized on D3-branes at the tip of a Calabi-Yau cone. Also, general guidelines suitable for the addition of massive flavor branes are developed.
We study two-dimensional $\mathcal{N}=(2,2)$ supersymmetric gauged linear
sigma models (GLSM) on the $\Omega$-deformed sphere, $S^2_\Omega$, which is a
one-parameter deformation of the $A$-twisted sphere. We provide an exact
formula for the $S^2_\Omega$ supersymmetric correlation functions using
supersymmetric localization. The contribution of each instanton sector is given
in terms of a Jeffrey-Kirwan residue on the Coulomb branch. In the limit of
vanishing $\Omega$-deformation, the localization formula greatly simplifies the
computation of $A$-twisted correlation functions, and leads to new results for
non-abelian theories. We discuss a number of examples and comment on the
$\epsilon_\Omega$-deformation of the quantum cohomology relations. Finally, we
present a complementary Higgs branch localization scheme in the special case of
abelian gauge groups.Comment: 101 pages plus appendices; v2: minor changes, typos corrected,
references added; v3: typos correcte
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