Quantum phase transition of correlated iron-based superconductivity in LiFe₁₋ₓCoₓAs

Authors

Jia-Xin Yin; Songtian S. Zhang; Guangyang Dai; Yuanyuan Zhao; Andreas Kreisel; Gennevieve Macam; Xianxin Wu; Hu Miao; Zhi-Quan Huang; Johannes H. J. Martiny; Brian M. Andersen; Nana Shumiya; Daniel Multer; Maksim Litskevich; Zijia Cheng; Xian Yang; Tyler A. Cochran; Guoqing Chang; Ilya Belopolski; Lingyi Xing; Xiancheng Wang; Yi Gao; Feng-Chuan Chuang; Hsin Lin; Ziqiang Wang; Changqing Jin; Yunkyu Bang; M. Zahid Hasan

Source

Phys. Rev. Lett. 123, 217004 (2019). DOI: 10.1103/PhysRevLett.123.217004

Preprint

arXiv:1910.11396

Abstract

The interplay between unconventional Cooper pairing and quantum states associated with atomic scale defects is a frontier of research with many open questions. So far, only a few of the high-temperature superconductors allow this intricate physics to be studied in a widely tunable way. We use scanning tunneling microscopy to image the electronic impact of Co atoms on the ground state of the LiFe₁₋ₓCoₓAs system. We observe that impurities progressively suppress the global superconducting gap and introduce low energy states near the gap edge, with the superconductivity remaining in the strong-coupling limit. Unexpectedly, the fully opened gap evolves into a nodal state before the Cooper pair coherence is fully destroyed. Our systematic theoretical analysis shows that these new observations can be quantitatively understood by the nonmagnetic Born-limit scattering effect in an s±-wave superconductor, unveiling the driving force of the superconductor to metal quantum phase transition.