Phases and geometry of the N=1 A_2 quiver gauge theory and matrix models

A partial list is: N. Dorey; A partial list is: N. Dorey; A. Brandhuber; A. Klemm; A. Klemm; C. Ahn; C. Ahn; C.I. Lazaroiu; E. Witten; Enrico Trincherini; F. Cachazo; F. Cachazo; F. Cachazo; F. Cachazo; F. Cachazo; F. Cachazo; F. Ferrari; F. Ferrari; F. Ferrari; G. Bertoldi; J. McGreevy; K. Konishi; K. Konishi; K.-H. Oh; L.F. Alday; M. Bershadsky; M. Petrini; M.R. Douglas; N. Seiberg; P. Kraus; R. Argurio; R. Casero; R. Dijkgraaf; R. Dijkgraaf; R. Dijkgraaf; R. Dijkgraaf; Roberto Casero; S.G. Naculich; S.G. Naculich; S.G. Naculich; T. Eguchi; T.J. Hollowood; V. Balasubramanian

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Phases and geometry of the N=1 A_2 quiver gauge theory and matrix models

Abstract

We study the phases and geometry of the N=1 A_2 quiver gauge theory using matrix models and a generalized Konishi anomaly. We consider the theory both in the Coulomb and Higgs phases. Solving the anomaly equations, we find that a meromorphic one-form sigma(z)dz is naturally defined on the curve Sigma associated to the theory. Using the Dijkgraaf-Vafa conjecture, we evaluate the effective low-energy superpotential and demonstrate that its equations of motion can be translated into a geometric property of Sigma: sigma(z)dz has integer periods around all compact cycles. This ensures that there exists on Sigma a meromorphic function whose logarithm sigma(z)dz is the differential. We argue that the surface determined by this function is the N=2 Seiberg-Witten curve of the theory.Comment: 41 pages, 2 figures, JHEP style. v2: references adde

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