Strongly interacting, dynamically disordered and with no small parameter, liquids took a
theoretical status between gases and solids with the historical tradition of hydrodynamic …

Important properties of a particle, wave or a statistical system depend on the form of a
dispersion relation (DR). Two commonly-discussed dispersion relations are the gapless …

A large and mostly unexplored part of the phase diagram lies above the critical point. The
supercritical matter was traditionally believed to be physically homogeneous with no …

Fundamental understanding of strongly interacting systems necessarily involves collective
modes, but their nature and evolution is not generally understood in dynamically disordered …

We combine hydrodynamic and field theoretic methods to develop a general theory of
phonons as Goldstone bosons in crystals, glasses, and liquids based on nonaffine …

Of the three basic states of matter, liquid is perhaps the most complex. While its flow
properties are described by fluid mechanics, its thermodynamic properties are often …

We study the GENERIC hydrodynamic theory for relativistic liquids formulated by Öttinger
and collaborators. We use the maximum entropy principle to derive its conditions for linear …

A simple and popular Bridgman's model predicts a linear correlation between the thermal
conductivity coefficient and the sound velocity of dense liquids. A proportionality coefficient …

Although the understanding of excitation spectra in fluids is of great importance, it is still
unclear how different methods of spectral analysis agree with each other and which of them …

Developing predictive thermal property models for liquids based on microscopic principles
has been elusive. The difficulty is that liquids have gas-like and solid-like attributes that are …