High-temperature superconductivity in monolayer Bi2Sr2CaCu2O8+δ
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nature-s41586-019-1718-x
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r r Z E eV g eV g eV ( , = ) ≡ ( , + )/ ( , − ), which eliminates systematic errors related to the tunnelling setpoint associated with directly mapping the conductance r g eV ( , ) (ref. 26 ). Figure 4a displays an example of the conductance ratio map of monolayer Bi-2212 obtained at E = 20 meV. The Fourier transform of the conductance ratio map, q Z E eV ( , = ), shows clear maxima at q i that are fully consistent with the octet model, except that peaks at q 4 and q 5 are too weak to be detected (Fig. 4f). As the tun- nelling bias V is varied, we observe that the measured q i disperse with energy E = eV, and the dispersions q i (E) are again consistent with those expected from the octet model (Extended Data Figs. 7 and 8). The dis- persions q i (E) allow us to extract the energy-dependent locations of the octet ends of the ‘bananas’ in k space, and the obtained loci can be inter- preted as the normal-state Fermi surface 24 . Our result, shown in Fig. 4i, is consistent with a cylindrical Fermi surface centred at (π,π) that is observed in bulk Bi-2212 and various other bulk copper oxide superconductors 26 . Finally, we determine the superconducting gap dispersion Δ kk ( ) from q E ( ) i . Figure 4j displays the measured supercon- ducting gap energy of the monolayer as a function of θ k along the Fermi surface. The data agree with the d-wave superconducting gap disper- sion of bulk Bi-2212 at similar doping level 23 . We therefore conclude that reducing the material’s dimensions from three to two does not fundamentally alter the superconducting gap structure. Download 5.82 Mb. Do'stlaringiz bilan baham: 
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