A Quieter State of Charge -- Ultra-Low-Noise Collective Current in Charge-Density-Wave Nanowires

Abstract: In quasi-one-dimensional (quasi-1D) charge-density-wave (CDW) systems, electric current comprises normal electrons and a collective, electron-lattice condensate current associated with CDW sliding. While achieving the dissipation-less Frohlich current of the sliding condensate is impossible in real materials, one can imagine an important related target, namely reaching the electron transport regime where electronic noise is inhibited due to the collective, strongly-correlated nature of the electron-lattice condensate current. Here we report that in nanowires of the fully-gapped CDW material (TaSe4)2I, low-frequency electronic noise is suppressed below the limit of thermalized charge carriers in passive resistors. When the current is dominated by the sliding Frohlich condensate, the normalized noise spectral density decreases linearly with current -- a striking departure from the constant value observed in conventional conductors. This discovery signals intrinsically lower current fluctuations within a correlated transport regime. The dominant noise source due to fluctuations in the CDW depinning threshold is extrinsic and caused by lattice imperfections that locally pin the condensate. Once the bias voltage is well past threshold and the sliding mode is established, the normalized noise drops below the noise of normal electrons. No residual minimum noise level is observed for the current of the condensate. Since flicker noise limits phase stability in communication systems, reduces the sensitivity and selectivity of sensors, and degrades coherence in quantum devices, our discovery introduces a fundamentally new strategy for achieving ultra-low-noise performance in nanoscale and quantum electronics using strongly correlated materials.