Generalizing Deconfined Criticality to 3D N-Flavor SU(2) Quantum Chromodynamics on the Fuzzy Sphere

Abstract

The infra-red behaviour of gauge theories coupled to matter remains an open problem in quantum field theory. For a given gauge group, such theories are expected to flow to an interacting conformal fixed point over a range of fermion or scalar flavours, known as the `conformal window.' Their nature is important for understanding critical phases and phase transitions beyond the Landau paradigm like the deconfined quantum critical point (DQCP), yet remains challenging for conventional non-perturbative approaches. In this work, we study a family of fuzzy-sphere models corresponding to non-linear sigma models with Sp(N) global symmetry extended to the strongly-coupled region. These theories are expected have an infra-red fixed point described by SU(2) quantum chromodynamics (QCD) in three space-time dimensions with N flavours of fermions. They can be viewed as a generalisation of the SO(5) DQCP, corresponding to N=2. We investigate them using quantum Monte Carlo for N up to 16. We find evidence that for N≥4 the phase diagram contains a critical phase that appears to be absent for N=2. Within this phase, we measure the two-point correlation function and the excitation spectrum, which exhibit emergent conformal symmetry. We also extract the scaling dimension φ of a leading operator and find consistency with large-N expectations.