Abstract
Using Quantum Monte Carlo simulations, we study a series of models of fermions coupled to quantum Ising spins on a square lattice with $N$ flavors of fermions per site for $N=1,2$ and $3$. The models have an extensive number of conserved quantities but are not integrable, and have rather rich phase diagrams consisting of several exotic phases and phase transitions that lie beyond Landau-Ginzburg paradigm. In particular, one of the prominent phase for $N>1$ corresponds to $2N$ gapless Dirac fermions coupled to an emergent $\mathbb{Z}_2$ gauge field in its deconfined phase. However, unlike a conventional $\mathbb{Z}_2$ gauge theory, we do not impose the `Gauss's Law' by hand and instead, it emerges due to spontaneous symmetry breaking. Correspondingly, unlike a conventional $\mathbb{Z}_2$ gauge theory in two spatial dimensions, our models have a finite temperature phase transition associated with the melting of the order parameter that dynamically imposes the Gauss's law constraint at zero temperature. By tuning a parameter, the deconfined phase undergoes a transition into a short range entangled phase, which corresponds to N\'eel/Superconductor for $N=2$ and a Valence Bond Solid for $N=3$. Furthermore, for $N=3$, the Valence Bond Solid further undergoes a transition to a N\'eel phase consistent with the deconfined quantum critical phenomenon studied earlier in the context of quantum magnets.
Highlights
Ground states of strongly interacting electronic systems can exhibit an extremely rich variety of phases
For N > 1, we find that when the kinetic energy of the aforementioned Ising spins is small compared to the kinetic energy of the fermions, the ground state resembles the deconfined phase of the Z2 gauge theory coupled to 2N Dirac fermions
Since 1⁄2Qi; H 1⁄4 0, this is akin to spontaneous symmetry breaking in a classical Ising model
Summary
Ground states of strongly interacting electronic systems can exhibit an extremely rich variety of phases. Gapped phases that possess a local order parameter are characterized by shortrange entanglement; that is, the reduced density matrix of a large subsystem A can be understood by patching together density matrices of smaller subsystems Ai whose union is A [10]. This is no longer true for gapless phases such as Fermi liquids [11,12,13] or gapped topological phases such as a fractional quantum Hall liquid, and such phases are said to possess “long-range entanglement” [7,8,14]. Even a phase as ubiquitous and as well understood as a Fermi liquid is rather hard to simulate numerically because fermions at finite density with repulsive interactions tend to have an intricate sign
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