Minimal loop currents in doped Mott insulators
Abstract
For the - model, variational wave functions can generally be constructed based on an accurate description of antiferromagnetism (AFM) at half-filling and an exact phase-string sign structure under doping. The single-hole-doped and two-hole-doped states, as determined by variational Monte Carlo (VMC) simulations, display sharply contrasting behaviors. The single-hole state constitutes a ``cat state'' that resonates strongly between a quasiparticle component and a local loop-current component, with approximately equal weights. In the ground state, the quasiparticle spectral weight peaks at momenta . The total-energy dispersion versus agrees remarkably well with the Green function Monte Carlo results. However, Landau's one-to-one correspondence hypothesis for quasiparticles breaks down here with the incoherent component exhibiting intrinsic magnetization originating from a minimal loop current that forms a pattern on the square lattice--a finding in excellent agreement with density matrix renormalization group (DMRG) calculations. In the two-hole ground state, a new pairing mechanism is revealed: the two holes are automatically fused into a tightly bound object consisting of an incoherent pairing along the diagonal direction by compensating the local loop currents. This hole pair is again a ``cat state'' that resonates strongly between the incoherent and a coherent Cooper channel to gain substantial hopping energy. Its size extends over an area of about lattice spacings, much smaller than the divergent AFM correlation length, implying that it should survive as a minimal superconducting building block even in the dilute doping regime. Experimental implications and the generalization to the finite-doping case are briefly addressed.
Keywords
Cite
@article{arxiv.2602.21206,
title = {Minimal loop currents in doped Mott insulators},
author = {Can Cui and Jing-Yu Zhao and Zheng-Yu Weng},
journal= {arXiv preprint arXiv:2602.21206},
year = {2026}
}
Comments
24 pages, 20 figures