We study experimentally the Raman response of the undoped high-Tc parent compound YBa2Cu3O6, and give a unified theory of the two-magnon Raman peak and optical conductivity based on the Hubbard-Holstein model with electron-phonon coupling (EPC). The Hubbard model without EPC can qualitatively account for the experimentally observed resonance of the Raman response, but only the Hubbard-Holstein model (i) reproduces the asymmetry of the Raman spectrum, (ii) validates the experimental visibility of the two-magnon peak, and (iii) predicts the correct shape and energy of the lower edge of the charge transfer gap in optical conductivity. A comparison of experiments with the theory gives the EPC strength ?=0.6. This result convincingly indicates the vital role of EPC in high-Tc cuprates, providing a clue to the mechanism of high Tc
Electron-phonon coupling in the undoped cuprate YBa2Cu3 O6 estimated from Raman and optical conductivity spectra
De Filippis;Cataudella;
2018
Abstract
We study experimentally the Raman response of the undoped high-Tc parent compound YBa2Cu3O6, and give a unified theory of the two-magnon Raman peak and optical conductivity based on the Hubbard-Holstein model with electron-phonon coupling (EPC). The Hubbard model without EPC can qualitatively account for the experimentally observed resonance of the Raman response, but only the Hubbard-Holstein model (i) reproduces the asymmetry of the Raman spectrum, (ii) validates the experimental visibility of the two-magnon peak, and (iii) predicts the correct shape and energy of the lower edge of the charge transfer gap in optical conductivity. A comparison of experiments with the theory gives the EPC strength ?=0.6. This result convincingly indicates the vital role of EPC in high-Tc cuprates, providing a clue to the mechanism of high TcI documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
