Dynamic competition between phason and amplitudon observed by ultrafast multimodal scanning tunneling microscopy (2507.11627v1)

Abstract: The intertwining between two ordered states that arise from the same interactions is reflected in the dynamics of their coupled collective excitations. While the equilibrium phase diagram resulting from such intertwined orders has been extensively studied, the dynamic competition between non-equilibrium modes is a largely unexplored territory. Here, we introduce a novel multimodal STM-based pump-probe technique, which enables the measurement of time-resolved tunneling (trSTM), time-resolved point-contact (trPC), and optical pump-probe reflectance (OPPR) on femtosecond timescales-all within a single instrument. We apply these techniques to investigate the collective excitations of the unconventional charge density wave insulator (TaSe4)2I. Our trSTM and trPC measurements reveal charge oscillations at 0.22 THz, with a temperature dependence that matches the theoretically predicted behavior of the long-sought massive phason gaining mass through the Higgs mechanism. Unexpectedly, the data also reveals a second mode at 0.11 THz exhibiting similar temperature and polarization dependence with comparable mode intensity. These features, along with the robust 1/2 frequency ratio locking suggest that the 0.11 THz phason is a 'daughter mode' that arises from the splitting of the 0.22 THz massive phason into two massless phasons via parametric amplification-analogous to the decay of a neutral pion into two photons. Strikingly, comparison with OPPR data reveals that the daughter phason competes with and suppresses the amplitudon at the same frequency. Our studies reveal an unexplored mechanism for the generation and extinction of collective excitations and pave the way for a microscopic understanding of ultrafast phenomena.