Abstract
The ground states and excitations of two-dimensional insulating and doped Mott insulators are described by a bond operator formalism. While the method represents the degrees of freedom of an arbitrary antiferromagnet exactly, it is especially suited to systems in which there is a natural pairing of sites into bonds, as in states with spontaneous or explicit spin-Peierls order (or bond-centered charge order). In the undoped insulator, as discussed previously, we obtain both paramagnetic and magnetically-ordered states. We describe the evolution of superconducting order in the ground state with increasing doping--at low doping, the superconductivity is weak, can co-exist with magnetic order, and there are no gapless spin 1/2 fermionic excitations; at high doping, the magnetic order is absent and we obtain a BCS d-wave superconductor with gapless spin 1/2, nodal fermions. We present the critical theory describing the onset of these nodal fermionic excitations. We discuss the evolution of the spin spectrum, and obtain regimes where a spin 1 exciton contributes a sharp resonance in the dynamic spin susceptiblity. We also discuss the experimental consequences of low-energy, dynamically fluctuating, spin-Peierls order in an isotropic CuO_2 plane--we compute consequences for the damping and dispersion of an optical phonon involving primarily the O ions, and compare the results with recent neutron scattering measurements of phonon spectra.
Highlights
It is reasonably well established that the doped antiferromagnets found in the cuprate compounds have a superconducting ground state with a d-wave pairing symmetry
We describe the evolution of superconducting order in the ground state with increasing doping—at low doping, the superconductivity is weak, can co-exist with magnetic order, and there are no gapless spin 1/2 fermionic excitations; at high doping, the magnetic order is absent and we obtain a BCS d-wave superconductor with gapless spin 1/2, nodal fermions
This paper has introduced a bond operator formalism to represent the degrees of freedom of doped antiferromagnets
Summary
It is reasonably well established that the doped antiferromagnets found in the cuprate compounds have a superconducting ground state with a d-wave pairing symmetry. Many low temperature (T ) properties appear to be well described in the framework of the conventional BCS theory of d-wave superconductors. There are a number of fascinating properties at temperatures above Tc (the critical temperature for the onset of superconductivity) which are not well understood, but there are numerous plausible candidate theories for these, involving crossovers between different competing orders in doped antiferromagnets. There are some low T properties of the superconducting state that do not appear naturally in the traditional BCS framework. Among these are (a) the appearance of a S = 1/2 moment near non-magnetic Zn or Li impurties in the underdoped region, (b) the presence of low energy collective spin excitations (a S = 1 spin exciton) at (π, π) and nearby incommensurate wavevectors, and (c) instabilities to various co-existing spin and charge density wave states. While it is possible to “cook-up” a microscopic Hamiltonian, and a corresponding HartreeFock treatment, to generate any of these physical properties in the superconducting state, a proper understanding of the physics should require that they emerge naturally from some deeper principle
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