Gauge Enhanced Quantum Criticality Between Grand Unifications: Categorical Higher Symmetry Retraction

Abstract

Prior work [arXiv:2106.16248] shows that the Standard Model (SM) naturally arises near a gapless quantum critical region between Georgi-Glashow (GG) su(5) and Pati-Salam (PS) su(4) × su(2) × su(2) models of quantum vacua (in a phase diagram or moduli space), by implementing a modified so(10) Grand Unification (GUT) with a Spin(10) gauge group plus a new discrete Wess-Zumino Witten term matching a 4d nonperturbative global mixed gauge-gravity w2 w3 anomaly. In this work, we include Barr's flipped su(5) model into the quantum landscape, showing these four GUT-like models arise near the quantum criticality near SM. Highlights include: First, we find the precise GG or flipped u(5) gauge group requires to redefine a Lie group U(5) q with q=2 or 3 (instead of non-isomorphic analog q=1 or 4), and different q are related by multiple covering. Second, we show that the GG and flipped u(5) are two different symmetry-breaking vacua of the same order parameter separated by a first-order Landau-Ginzburg transition. We also show that analogous 3+1d deconfined quantum criticalities, both between GG and PS, and between the flipped u(5) and PS, are beyond Landau-Ginzburg paradigm. Third, topological quantum criticality occurs by tuning between the 15n vs 16n scenarios. Fourth, we explore the generalized higher global symmetries in the SM and GUTs. Gauging the Z2 flip symmetry between GG and flipped u(5) models, leads to a potential categorical higher symmetry that is a non-invertible global symmetry: within a gauge sector (u(1) × u(1)) Z2, the fusion rule of 2d topological surface operator splits. However, the un-Higgs Spin(10) at UV retracts this categorical symmetry.