2015
DOI: 10.1088/1367-2630/17/1/013025
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Charge order in the pseudogap phase of cuprate superconductors

Abstract: Charge ordering instabilities are studied in a multiorbital model of the cuprate superconductors. A known, key feature of this model is that the large local Coulomb interaction in the Cud x 2 −y 2 orbitals generates local moments with short range antiferromagnetic correlations. The strong simplifying ansatz that these moments are static and ordered allows us to explore a regime not generally accessible to weakcoupling approaches. The antiferromagnetic correlations lead to a pseudogap-like reconstruction of the… Show more

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Cited by 95 publications
(149 citation statements)
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“…Nevertheless, electron-lattice interactions are not by themselves sufficient to explain the phase diagram of the dFF-DW (refs 11-13) because, for example, they also exist in the overdoped regime where the dFF-DW is absent. Moreover, theoretical models involving k-space instabilities 26,27,29,40 which are consistent with the results herein, emphasize that a density wave with this Q and form factor symmetry cannot emerge from a large Fermi surface; instead, a pre-existing reorganization of k-space due to the pseudogap would be required. Overall, our data support a microscopic picture in which the exotic electronic structure of the pseudogap is parent to the dFF-DW state and not vice versa, where the energy scale and wavevectors of the dFF-DW are intimately linked to those of the pseudogap, and in which the d-symmetry DW competes directly for spectral weight with the d-symmetry superconductor at the k-space 'hot frontier' between superconductivity and the pseudogap.…”
supporting
confidence: 84%
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“…Nevertheless, electron-lattice interactions are not by themselves sufficient to explain the phase diagram of the dFF-DW (refs 11-13) because, for example, they also exist in the overdoped regime where the dFF-DW is absent. Moreover, theoretical models involving k-space instabilities 26,27,29,40 which are consistent with the results herein, emphasize that a density wave with this Q and form factor symmetry cannot emerge from a large Fermi surface; instead, a pre-existing reorganization of k-space due to the pseudogap would be required. Overall, our data support a microscopic picture in which the exotic electronic structure of the pseudogap is parent to the dFF-DW state and not vice versa, where the energy scale and wavevectors of the dFF-DW are intimately linked to those of the pseudogap, and in which the d-symmetry DW competes directly for spectral weight with the d-symmetry superconductor at the k-space 'hot frontier' between superconductivity and the pseudogap.…”
supporting
confidence: 84%
“…Such a state is then described by A(r) = D(r) cos(φ(r) + φ 0 (r)), where A(r) represents whatever is the modulating electronic degree of freedom, φ(r) = Q x · r is the DW spatial phase at location r, φ 0 (r) represents disorder related spatial phase shifts, and D(r) is the magnitude of the d-symmetry form factor 14,21,23 . To distinguish between the various microscopic mechanisms proposed for the Q = (Q, 0); (0, Q) dFF-DW state of cuprates [17][18][19][20][21][22][23][24][25][26][27][28][29] , it is essential to establish its atomic-scale phenomenology, including the momentum space (k-space) eigenstates contributing to its spectral weight, the relationship (if any) between modulations occurring above and below the Fermi energy, whether the modulating states in the DW are associated with a characteristic energy gap, and how the dFF-DW evolves with doping.To visualize such phenomena directly as in Fig. 1c, we use sublattice-phase-resolved imaging of the electronic structure 14 of the CuO 2 plane.…”
mentioning
confidence: 99%
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“…RPA calculations for the three-band Hubbard model have also found nematic phases in certain parameter regimes [31][32][33] . Earlier DMRG calculations for a 3-orbital model of a two-leg CuO 2 ladder showed the expected local asymmetric chargetransfer behavior in which doped holes tend to predominantly go on the 2pσ orbitals while doped electrons go on the Cu 3d x 2 −y 2 orbitals 34,35 .…”
mentioning
confidence: 99%
“…Recent experiments in cuprates have revealed ample evidence for incommensurate charge modulations with wavevectors oriented along the crystalline axes, i.e., at 45˝off the SDW vector as well [8,[44][45][46][47][48][49][50][51][52][53][54]. A theoretical investigation examining a multiorbital model of cuprates finds support for such an axial charge order [46] in contrast to previous calculations, which reported wave vectors along the Brillouin zone diagonal.…”
Section: Charge Order In Cuprates and Other Unconventional Supercondumentioning
confidence: 72%