In this study, a SU(2) gauge theory of fluctuating magnetic order in the two-dimensional Hubbard model is presented, based on a fractionalization of electrons in fermionic chargons and bosonic spinons. Different magnetic order phenomena are observed for chargons below a density-dependent transition temperature T*, while spinon fluctuations prevent the formation of magnetic long-range order of the electrons at any finite temperature.
We present a SU(2) gauge theory of fluctuating magnetic order in the two-dimensional Hubbard model. The theory is based on a fractionalization of electrons in fermionic chargons and bosonic spinons. The chargons undergo Neel or spiral magnetic order below a density-dependent transition temperature T*. Fluctuations of the spin orientation are described by a nonlinear sigma model obtained from a gradient expansion of the spinon action. The spin stiffnesses are computed from a renormalization group improved random phase approximation. Our approximations are designed for moderate, not for strong, Hubbard interactions. The stiffnesses are strongly doping dependent with discontinuities at half-filling and a pronounced electron-hole asymmetry. The spinon fluctuations prevent magnetic long-range order of the electrons at any finite temperature. The phase with magnetic chargon order shares characteristic features with the pseudogap regime in high-Tc cuprates: a strong reduction of charge carrier density, a spin gap, and Fermi arcs. A substantial fraction of the pseudogap regime exhibits electronic nematicity.
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