Local intra-unit-cell order parameters in cuprates

Abstract

Starting with the on-site Hilbert space reduced to only three effective valence centers, nominally Cu1+,2+,3+, we present an unified approach to the description of the local intra-unit-cell (IUC) order parameters in cuprates. Central point of the model implies the occurrence of unconventional on-site quantum superpositions of the three valent states characterized by different hole occupation, nh=0,1,2, conventional spin s=1/2 for Cu2+ and s=0 for Cu1+,3+ centers, and different orbital symmetry:B1g for the ground states of the Cu2+ center and A1g for the Cu1+,3+ centers, respectively. The latter does result in a spontaneous orbital symmetry breaking with emergence of the IUC orbital nematic order parameter of the B1g dx2-y2 symmetry. To describe the quantum local charge order we develop an S=1 pseudospin model. Conventional spin density s for mixed valence superpositions can vary inbetween 0 and 1 in accordance with the weight of the Cu2+ center in the superposition. We show that the superconductivity and spin magnetism are nonsymbiotic phenomena with competing order parameters. Furthermore we argue that instead of a well-isolated Zhang-Rice (ZR) singlet 1A1g the ground state of the hole Cu3+ center in cuprates should be described by a complex 1A1g-1,3B2g-1,3Eu multiplet, formed by a competition of conventional hybrid Cu 3d-O 2p b1g(σ) dx2 -y2 state and purely oxygen nonbonding O 2pπ states with a2g(π) and eux,y(π) symmetry. In contrast with inactive ZR singlet we arrive at several novel competing IUC orbital and spin-orbital order parameters, e.g., electric dipole and quadrupole moments, Ising-like net orbital magnetic moment, orbital toroidal moment, intra-plaquette's staggered order of Ising-like oxygen orbital magnetic moments.