Charge-density-wave order with momentum (2Q, 0) and (0, 2Q) within the spin-fermion model: continuous and discrete symmetry breaking, preemptive composite order, and relation to pseudogap in hole-doped cuprates

Abstract

We analyze charge order within the the spin-fermion model. We show that magnetically-mediated interaction gives rise to charge order kQ = c k+ Q c k- Q with momenta Q=Qx =(2Q,0) and Q=Qy =(0,2Q), if the magnetic correlation length exceeds some critical value. We argue that kQ and -kQ are not equivalent, and their symmetric and antisymmetric combinations describe density modulations and bond current. We derive GL functional for four-component U(1) order parameters Q k with Q = Qx or Qy. Within mean-field we find two types of CDW states, I and II, depending on system parameters. In state I density and current modulations emerge with the same Q = Qx or Qy, breaking Z2 lattice rotational symmetry, and differ in phase by π/2. The selection of π/2 or -π/2 additionally breaks Z2 time-reversal symmetry, such that the total order parameter manifold is U(1) × Z2 × Z2. In state II density and current modulations emerge with different Q and the order parameter manifold is U(1) × U (1) × Z2. We go beyond mean-field and show that discrete symmetries get broken before long-range charge order sets in. For state I, the system first breaks Z2 lattice rotational symmetry (C4 C2) at T= Tn and develops a nematic order, then breaks Z2 time-reversal symmetry at Tt < Tn, and finally breaks U(1) symmetry of a common phase of even and odd components of Qk at T= T cdw < Tt < Tn and develops a true charge order. We argue that the preemptive orders lift T cdw and reduces T sc such that at large charge order may develop prior to superconductivity. We obtain the phase diagram and present quantitative comparison with ARPES data for hole-doped cuprates.