Observation of Coherent Ferrons

Abstract: Excitation of ordered phases produces quasiparticles and collective modes, as exemplified by magnons that emerge from magnetic order, with applications in information transmission and quantum interconnects. Extending this paradigm to ferroelectric materials suggests the existence of ferrons, i.e. fundamental quanta of the collective excitation of ferroelectric order5 developed theoretically by Bauer and coworkers. While coherent magnons are observed in a broad range of experiments, coherent ferrons have eluded experimental detection. This discrepancy is particularly intriguing given that electric dipole interactions (FE) are inherently stronger than their magnetic counterparts. Here, we report the generation and transport of coherent ferrons in the van der Waals (vdW) ferroelectric material NbOI2. By launching collective oscillations of the ferroelectric dipoles using a short laser pulse, we identify coherent ferrons from intense and narrow-band terahertz (THz) emission and observe their propagations along the polar direction at extremely hypersonic velocities exceeding 10^5 m/s. The THz emission is a second-order nonlinear process that requires ferroelectric order, as is confirmed in the structurally related ferroelectric WO2Br2 and non-ferroelectric TaOBr2. The discovery of coherent ferrons paves the way for numerous applications, including narrow-band THz emission, ferronic information processing, and quantum interconnects.