Intertwined density waves in a metallic nickelate
Junjie Zhang, Daniel Phelan, Antía S. Botana, Yu‐Sheng Chen, Hong Zheng, Matthew Krogstad, SuYin Grass Wang, Yiming Qiu, J. A. Rodriguez‐Rivera, R. Osborn, Stephan Rosenkranz, M. R. Norman, J. F. Mitchell
Abstract
Abstract Nickelates are a rich class of materials, ranging from insulating magnets to superconductors. But for stoichiometric materials, insulating behavior is the norm, as for most late transition metal oxides. Notable exceptions are the 3D perovskite LaNiO 3 , an unconventional paramagnetic metal, and the layered Ruddlesden-Popper phases R 4 Ni 3 O 10 , (R = La, Pr, Nd). The latter are particularly intriguing because they exhibit an unusual metal-to-metal transition. Here, we demonstrate that this transition results from an incommensurate density wave with both charge and magnetic character that lies closer in its behavior to the metallic density wave seen in chromium metal than the insulating stripes typically found in single-layer nickelates like La 2- x Sr x NiO 4 . We identify these intertwined density waves as being Fermi surface-driven, revealing a novel ordering mechanism in this nickelate that reflects a coupling among charge, spin, and lattice degrees of freedom that differs not only from the single-layer materials, but from the 3D perovskites as well.