Inverse-current quantum electro-oscillations in a charge-density wave insulator

Quantum magneto-oscillations have long been a vital subject in condensed matter physics with ubiquitous quantum phenomena and various underlying physical mechanisms. Here, we demonstrate the intrinsic and reproducible d.c.-currentdriven quantum electro-oscillations with a periodicity in the inverse of current (1/I), in quasi-one-dimensional charge-density-wave (CDW) insulator (TaSe$_4$)$_2$I and TaS$_3$ nanowires. Such oscillations manifest in the nearly infinite Frohlich conductivity region where the CDW depinning occurs in a finite electric current, and finally disappear after the oscillation index n reaches 1. A systematic investigation on the effect of temperature and magnetic field establishes that the observed electro-oscillations are a coherent quantum phenomenon. A possible mechanism is proposed based on zero-phason-assisted resonant tunneling, associated with sliding-driven inherent Floquet sidebands. Our results introduce a new member in the quantum oscillations family, and shed light on plausible routes to explore novel physics and potential applications of coherent density-wave condensates.