Hydrodynamic fields in fluctuating environment: the emergent phononic and tachyonic-like excitations
Abstract
Using functional methods, we investigate in a low-temperature liquid, the sound quanta defined by the quantized hydrodynamic fields, under the effects of high-energy processes on the atomic/molecular scale. To obtain in the molecular level the excitation spectra of liquids, we assume that the quantum fields are coupled to an additive delta-correlated in space and time quantum noise field. The hydrodynamic fields are defined in a fluctuating environment. After defining the generating functional of connected correlation fuctions in the presence of the noise field, we perform a functional integral over all noise field configurations. This is done using a formal object inspired by the distributional zeta-function method, named configurational zeta-function. We obtain a new generating functional written in terms of an analytically tractable functional series. Each term of the series describes in the liquid the emergent non-interacting elementary excitations with the usual gapless phonon-like dispersion relation and additional excitations with dispersion relations with gaps in pseudo-momenta space, i.e., tachyonic-like excitations. Furthermore, the Fourier representation of the two-point correlation functions of the model with the contribution coming from all phononic and tachyonic-like fields is presented. Finally, our analysis reveals that the emergent tachyonic-like and phononic excitations yield a distinctive thermodynamic signature - a quadratic temperature dependence of specific heat ($C_V \propto T^2$) at low temperatures, providing a theoretical foundation for experiments in confined and supercooled liquids.