Nature Communications (Sep 2024)

Evolution from a charge-ordered insulator to a high-temperature superconductor in Bi2Sr2(Ca,Dy)Cu2O8+δ

  • Changwei Zou,
  • Jaewon Choi,
  • Qizhi Li,
  • Shusen Ye,
  • Chaohui Yin,
  • Mirian Garcia-Fernandez,
  • Stefano Agrestini,
  • Qingzheng Qiu,
  • Xinqiang Cai,
  • Qian Xiao,
  • Xingjiang Zhou,
  • Ke-Jin Zhou,
  • Yayu Wang,
  • Yingying Peng

DOI
https://doi.org/10.1038/s41467-024-52124-9
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 9

Abstract

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Abstract How Cooper pairs form and condense has been the main challenge in the physics of copper-oxide high-temperature superconductors. Great efforts have been made in the ‘underdoped’ region of the phase diagram, through doping a Mott insulator or cooling a strange metal. However, there is still no consensus on how superconductivity emerges when electron-electron correlations dominate and the Fermi surface is missing. To address this issue, here we carry out high-resolution resonant inelastic X-ray scattering and scanning tunneling microscopy studies on prototype cuprates Bi2Sr2Ca0.6Dy0.4Cu2O8+δ near the onset of superconductivity, combining bulk and surface, momentum- and real-space information. We show that an incipient charge order exists in the antiferromagnetic regime down to 0.04 holes per CuO2 unit, entangled with a particle-hole asymmetric pseudogap. The charge order induces an intensity anomaly in the bond-buckling phonon branch, which exhibits an abrupt increase once the system enters the superconducting dome. Our results suggest that the Cooper pairs grow out of a charge-ordered insulating state, and then condense accompanied by an enhanced interplay between charge excitations and electron-phonon coupling.