There
is a need for molecular-structure-based predictive models
that guide the molecular design of materials with desired properties.
Herein, we developed a general model based on group-contribution (GC)
theory and vibrational theory that predicts the thermal conductivity
of different types of liquids which are used as working media in energy
conversion and environmental protection, including three types of
organic molecular liquids, ionic liquids, and their mixtures. We also
derive the pressure dependencies of the thermal conductivities of
these liquids for the first time. The GC model is extended to determining
the thermal conductivities of mixtures by developing a group division
method and mixing rules that operate without knowing the thermal conductivity
of each component. The excellent performance of the presented model
is verified by comparing the predicted thermal conductivities with
experimental data and those from other models. On the basis of the
developed model, group sequences are established according to their
contributions to thermal conductivity, and the sensitivity of thermal
conductivity to temperature and pressure is analyzed to guide the
molecular design of liquids.