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Nonlocal interactions in doped cuprates: Correlated motion of Zhang-Rice polarons

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Hozoi,  L.
Former Departments, Max Planck Institute for Solid State Research, Max Planck Society;

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Citation

Hozoi, L., Nishimoto, S., Kalosakas, G., Bodea, D. B., & Burdin, S. (2007). Nonlocal interactions in doped cuprates: Correlated motion of Zhang-Rice polarons. Physical Review B, 75(2): 024517.


Cite as: https://hdl.handle.net/21.11116/0000-000E-B6D9-0
Abstract
Intercarrier correlations in hole doped cuprates are investigated by ab initio multiconfiguration calculations. The dressed carriers display features that are reminiscent of both Zhang-Rice (ZR) CuO4 states and Jahn-Teller polarons. The interaction between these quasiparticles is repulsive. At dopings that are high enough, the interplay between long-range unscreened Coulomb interactions and long-range phase coherence among the O-ion half-breathing vibrations on the ZR plaquettes may lead to a strong reduction of the effective adiabatic energy barrier associated to each polaronic state. Tunneling effects cannot be neglected for a relatively flat, multiwell energy landscape. We suggest that the coherent, superconducting quantum state is the result of such coherent quantum lattice fluctuations involving in-plane O ions. Our findings appear to support phenomenological models where the superconductivity is related to a lowering of the in-plane kinetic energy.