Cooper-pair density modulation state in an iron-based superconductor

Article

Kong, Lingyuan; Papaj, Michal; Kim, Hyunjin; Zhang, Yiran; Baum, Eli; Li, Hui; Watanabe, Kenji; Taniguchi, Takashi; Gu, Genda; Lee, Patrick A.; Nadj-Perge, Stevan

California Institute of Technology; California Institute of Technology; University of Houston System; University of Houston; University of California System; University of California Berkeley; California Institute of Technology; Northwestern University; National Institute for Materials Science; United States Department of Energy (DOE); Brookhaven National Laboratory; Massachusetts Institute of Technology (MIT)

Nature

0028-3218

10.1038/s41586-025-08703-x

2025-04-03

Superconducting (SC) states that break space-group symmetries of the underlying crystal can exhibit nontrivial spatial modulation of the order parameter. Previously, such states were intimately associated with the breaking of translational symmetry1,2, resulting in the density-wave orders3, 4, 5, 6, 7-8, with wavelengths spanning several unit cells9, 10, 11, 12, 13, 14, 15, 16, 17, 18-19. However, a related basic concept has long been overlooked20: when only intra-unit-cell symmetries of the space group are broken, the SC states can show a distinct type of nontrivial modulation preserving long-range lattice translation. Here we refer to this new concept as the pair density modulation (PDM) and report the first observation of a PDM state in exfoliated thin flakes of the iron-based superconductor FeTe0.55Se0.45. Using scanning tunnelling microscopy (STM), we discover robust SC gap modulation with the wavelength corresponding to the lattice periodicity and the amplitude exceeding 30% of the gap average. Notably, we find that the observed modulation originates from the large difference in SC gaps on the two nominally equivalent iron sublattices. The experimental findings, backed up by model calculations, suggest that, in contrast to the density-wave orders, the PDM state is driven by the interplay of sublattice symmetry breaking and a peculiar nematic distortion specific to the thin flakes. Our results establish new frontiers for exploring the intertwined orders in strong-correlated electronic systems and open a new chapter for iron-based superconductors.