Abstract
Unconventional symmetry breaking without spin order,such as the rotational symmetry breaking (=nematic or smectic) orders as well as the spontaneous loop-current orders, have been recently reported in cuprate superconductors and their related materials.They are theoretically represented by non-$A_{1g}$ symmetry breaking in self-energy, which we call the form factor $f_{k,q}$.In this paper, we analyze typical Hubbard models by applying the renormalization-group (RG) method, and find that various unconventional ordering emerges due to the quantum interference among spin fluctuations. Due to this mechanism,nematic ($q=0$) and smectic ($q \ne 0$)bond orders with $d$-wave form factor appear $f_{k,q}\propto \cos k_x - \cos k_y$ in both cuprates and $\kappa$-(BEDT-TTF)$_2$X. The derived bond orders naturally explain the pseudogap behaviors in these compounds. The quantum interference also induces various current orders with odd-parity form factor. For example, we find the emergence of the charge and spin loop-current orders with $p$-wave form factor in geometrically frustrated Hubbard models. Thus, rich quantum phase transitions with $d$- and $p$-wave form factors are driven by the paramagnon interference in many low-dimensional Hubbard models.
Highlights
Various exotic symmetry-breaking, such as violations of the rotational, time-reversal and inversion symmetries, have been discovered in many strongly correlated metals, thanks to the recent progress of experiments
We investigate the rich variety of exotic orderings in terms of the non-A1g symmetry breaking in self-energy, which is represented as the form factor fk,q, in a unified way
We show the diagrammatic explanation of the RG+constrained randon-phaseapproximation (cRPA) method in Fig. 4 (a)
Summary
Various exotic symmetry-breaking, such as violations of the rotational, time-reversal and inversion symmetries, have been discovered in many strongly correlated metals, thanks to the recent progress of experiments. Electronic nematic states (=rotational symmetry breaking) without magnetization commonly emerge in Fe-based and cuprate superconductors These discovered exotic symmetry breaking are generally called the “quantum liquid crystal states”, and they are totally different from conventional local spin/charge density waves (SDW/CDW) studied so far. Conventional N -patch RG57–59 is applicable for a model with simple band dispersion, this constraint is alleviated by combining the RG and the constrained randon-phaseapproximation (cRPA) Using this RG+cRPA method, we can calculate the general charge (spin) susceptibilities with non-local form factor, χcf(s)(q), by including higher-order VCs. The realized order with form factor f at wavevector q is determined under the condition of maximizing the function χcf(s)(q). We explain the optimization of form factors within the RG scheme
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