Observation of Kondo hybridization wave in UTe2

TL;DR

This study reports the first observation of a Kondo hybridization wave in UTe2, revealing a new ordered phase that coexists with superconductivity and offers insights into strong correlation physics.

Contribution

First experimental detection of a translational-symmetry-breaking Kondo hybridization wave in UTe2 using STM, demonstrating an ordered hybridization phase in a Kondo lattice system.

Findings

Identification of a Kondo hybridization wave as a periodically modulated Fano lattice

Observation of a coexisting charge density wave and energy gap near the Fermi level

Evidence of an ordered hybridization state coexisting with superconductivity

Abstract

Condensed matter systems with strong electronic correlations often manifest a variety of intertwined ordered phases of charge, spin, orbital and other degrees of freedom. As a prototypical strongly correlated electronic system, the Kondo lattice provides fertile soil for many fascinating quantum states, including quantum criticality, unconventional superconductivity, hidden order and topological Kondo insulator/semimetal. The foundation of Kondo physics lies in the hybridization between localized moments and itinerant electrons. Generally, the evolution of Kondo hybridization is characterized as a broad crossover rather than a phase transition. Thus far, an ordered hybridization phase has not been observed. Here, we use scanning tunneling microscopy (STM) to identify a translational-symmetry-breaking order of Kondo hybridization wave(KHW) for the first time on the surface of the spin-triplet heavy-fermion superconductor UTe2. The unprecedented phase of KHW manifests as a periodically modulated Fano lattice, accompanied by a commensurate charge density wave (CDW) and a pronounced energy gap opening near the Fermi level. This KHW-imprinted CDW has an intriguing real-space texture of complementary occupation of the heavy f and conduction charges, thereby forming a Kondo superlattice. The KHW is coexistent with superconductivity in UTe2, which may provide valuable insight into its controversial spin-triplet pairing symmetry and the underlying mechanism. Our first experimental evidence for an ordered hybridization state potentially sheds new light on the strong correlation physics of Kondo lattice system.