d- and p-wave quantum liquid crystal orders in cuprate superconductors, -(BEDT-TTF)2X, and coupled chain Hubbard models: functional-renormalization-group analysis

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-A1g symmetry breaking in self-energy, which we call the form factor fk,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 0)bond orders with d-wave form factor appear fk,q kx - ky in both cuprates and -(BEDT-TTF)2X. 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.