Imaging the coherent propagation of collective modes in the excitonic insulator candidate Ta$_2$NiSe$_5$ at room temperature

Excitonic insulating (EI) materials are predicted to host a condensate of electron-hole pairs in their ground state, giving rise to collective many-body effects. Although several bulk materials have been proposed as EIs recently, a direct observation of the characteristic collective behavior is still missing. Here, we use ultrafast, spatially-resolved, pump-probe microscopy to investigate the propagation of photoinduced excitations in a proposed EI, Ta$_2$NiSe$_5$. Below the critical temperature for the EI phase (328 K), we observe the propagation, for distances of up to 1 $\mu$m, of coherent oscillatory modes in the THz range at velocities of the order of 10$^5$ m/s. We develop a theoretical framework to explain these findings and suggest that this behavior results from the hybridization of phonon modes with the phase mode of the EI. We infer that the ordered EI phase is driven predominantly by interorbital Coulomb interactions and that this system falls into the BCS-BEC crossover regime. This study provides a route for the investigation of collective properties in strongly correlated materials and paves the way for applications that can take advantage of these quantum phenomena up to room temperature.