Z2 fractionalized phases of a solvable, disordered, t-J model

Abstract

We describe the phases of a solvable t-J model of electrons with infinite-range, and random, hopping and exchange interactions, similar to those in the Sachdev-Ye-Kitaev models. The electron fractionalizes, as in an `orthogonal metal', into a fermion f which carries both the electron spin and charge, and a boson φ. Both f and φ carry emergent Z2 gauge charges. The model has a phase in which the φ bosons are gapped, and the f fermions are gapless and critical, and so the electron spectral function is gapped. This phase can be considered as a toy model for the underdoped cuprates. The model also has an extended, critical, `quasi-Higgs' phase where both φ and f are gapless, and the electron operator f φ has a Fermi liquid-like 1/τ propagator in imaginary time, τ. So while the electron spectral function has a Fermi liquid form, other properties are controlled by Z2 fractionalization and the anomalous exponents of the f and φ excitations. This `quasi-Higgs' phase is proposed as a toy model of the overdoped cuprates. We also describe the critical state separating these two phases.