Quantum electron liquid and its possible phase transition.
Sunghun KimJoonho BangChan-Young LimSeung Yong LeeJounghoon HyunGyubin LeeYeonghoon LeeJonathan D DenlingerSoonsang HuhChangyoung KimSang Yong SongJungpil SeoDinesh ThapaSeong-Gon KimYoung Hee LeeYeongkwan KimSung Wng KimPublished in: Nature materials (2022)
Purely quantum electron systems exhibit intriguing correlated electronic phases by virtue of quantum fluctuations in addition to electron-electron interactions. To realize such quantum electron systems, a key ingredient is dense electrons decoupled from other degrees of freedom. Here, we report the discovery of a pure quantum electron liquid that spreads up to ~3 Å in a vacuum on the surface of an electride crystal. Its extremely high electron density and weak hybridization with buried atomic orbitals show the quantum and pure nature of the electrons, which exhibit a polarized liquid phase, as demonstrated by our spin-dependent measurement. Furthermore, upon enhancing the electron correlation strength, the dynamics of the quantum electrons change to that of a non-Fermi liquid along with an anomalous band deformation, suggestive of a transition to a hexatic liquid crystal phase. Our findings develop the frontier of quantum electron systems and serve as a platform for exploring correlated electronic phases in a pure fashion.