Abstract
We study symmetries and dynamics of chiral $SU(N)$ gauge theories with matter Weyl fermions in a two-index symmetric ($\ensuremath{\psi}$) or antisymmetric tensor ($\ensuremath{\chi}$) representation, together with $N\ifmmode\pm\else\textpm\fi{}4+p$ fermions in the antifundamental ($\ensuremath{\eta}$) and $p$ fermions in the fundamental ($\ensuremath{\xi}$) representations. They are known as the Bars-Yankielowicz (the former) and the generalized Georgi-Glashow models (the latter). The conventional 't Hooft anomaly matching algorithm is known to allow a confining, chirally symmetric vacuum in all these models, with a simple set of massless baryonlike composite fermions describing the infrared physics. We analyzed recently one of these models ($\ensuremath{\psi}\ensuremath{\eta}$ model), by applying the ideas of generalized symmetries and the consequent, stronger constraints involving certain mixed anomalies, finding that the confining, chirally symmetric, vacuum is actually inconsistent. In the present paper, this result is extended to a wider class of the Bars-Yankielowicz and the generalized Georgi-Glashow models. It is shown that for all these models with $N$ and $p$ both even, at least, the generalized anomaly matching requirement forbids the persistence of the full chiral symmetries in the infrared if the system confines. The most natural and consistent possibility is that some bifermion condensates form, breaking the color gauge symmetry dynamically, together with part of the global symmetry.
Highlights
A few steps have been taken recently [1,2] to go beyond the conventional ’t Hooft anomaly matching analysis in understanding the infrared dynamics of chiral gauge theories
The most natural and consistent possibility is that some bifermion condensates form, breaking the color gauge symmetry dynamically, together with part of the global symmetry
Vectorlike, gauge theories, the results from the new approach can be corroborated by the extensive literature, based on some general theorems [17,18], on lattice simulations [19,20,21,22], on the effective Lagrangians [23,24,25,26], on ’t Hooft anomaly analysis [27], on the powerful exact results in N 1⁄4 2 supersymmetrie theories [28,29], or on some other theoretical ideas such as the space compactification combined with semiclassical analyses [30,31,32,33]
Summary
A few steps have been taken recently [1,2] to go beyond the conventional ’t Hooft anomaly matching analysis in understanding the infrared dynamics of chiral gauge theories. Vectorlike, gauge theories, the results from the new approach can be corroborated by the extensive literature, based on some general theorems [17,18], on lattice simulations [19,20,21,22], on the effective Lagrangians [23,24,25,26], on ’t Hooft anomaly analysis [27], on the powerful exact results in N 1⁄4 2 supersymmetrie theories [28,29], or on some other theoretical ideas such as the space compactification combined with semiclassical analyses [30,31,32,33] Most of these theoretical tools are, unavailable for the study of strongly coupled chiral gauge theories, except for some general wisdom, the large-N approximation, and the ’t Hooft anomaly considerations. Together, they offer significant, but not very stringent, information on the infrared dynamics, phases, and symmetry realization 1-form ZN of an SUðNÞ gauge theory, one arrives at an SUðNÞ ZN gauge system, with consequent
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