Intermolecular Interaction Studies in Binary and Higher Order Liquid Mixtures, Ionic Liquids and their thermophysical properties find many applications in chemical industries, mass and heat transfer processes, design and engineering calculations of industrial plants. These include thermodynamic, transport, interfacial, optical, radiative and an abundance of other properties. A comprehensive study of the thermophysical properties of liquid mixtures gives us a better understanding of their intermolecular interactions and their properties provide an in-depth insight into the nature and the extent of the interactions thereby providing valuable information pertaining to the behaviour of these systems.
Investigation of thermophysical properties of binary and higher order liquid mixtures continues to engage an abundance of researchers both the academia and industry. This research topic will address these by including both experimental and theoretical investigations of the nature of these intermolecular interactions. It will also include research related to solution and mixture thermodynamics, excess and allied properties, transport, optical, thermoacoustic and surface properties which have shown profound growth in the past few years and exhibit high degree of interest for researchers involved in industrial applications such as biomaterials, proteins, new molecules, etc.
We welcome Original Research, Review, Mini Review and Perspective articles on themes including, but not limited to:
• Solution Thermodynamics, biological effects in solutions and industrial applications
• Thermodynamic and Transport properties: Ultrasonic velocity, density, heat capacity, enthalpy, entropy, excess viscosity, thermal expansion, critical data, thermoacoustic and thermal conductivity
• Optical and Radiative Properties: refractive index, emissivity, absorptivity
• Data Correlation: Data Evaluation, property prediction and evaluation
• P-V-T behaviour studies
• Properties of aqueous systems
• Properties of Ionic Liquids (ILs) and Deep Eutectic Solvents (DES) based systems
Intermolecular Interaction Studies in Binary and Higher Order Liquid Mixtures, Ionic Liquids and their thermophysical properties find many applications in chemical industries, mass and heat transfer processes, design and engineering calculations of industrial plants. These include thermodynamic, transport, interfacial, optical, radiative and an abundance of other properties. A comprehensive study of the thermophysical properties of liquid mixtures gives us a better understanding of their intermolecular interactions and their properties provide an in-depth insight into the nature and the extent of the interactions thereby providing valuable information pertaining to the behaviour of these systems.
Investigation of thermophysical properties of binary and higher order liquid mixtures continues to engage an abundance of researchers both the academia and industry. This research topic will address these by including both experimental and theoretical investigations of the nature of these intermolecular interactions. It will also include research related to solution and mixture thermodynamics, excess and allied properties, transport, optical, thermoacoustic and surface properties which have shown profound growth in the past few years and exhibit high degree of interest for researchers involved in industrial applications such as biomaterials, proteins, new molecules, etc.
We welcome Original Research, Review, Mini Review and Perspective articles on themes including, but not limited to:
• Solution Thermodynamics, biological effects in solutions and industrial applications
• Thermodynamic and Transport properties: Ultrasonic velocity, density, heat capacity, enthalpy, entropy, excess viscosity, thermal expansion, critical data, thermoacoustic and thermal conductivity
• Optical and Radiative Properties: refractive index, emissivity, absorptivity
• Data Correlation: Data Evaluation, property prediction and evaluation
• P-V-T behaviour studies
• Properties of aqueous systems
• Properties of Ionic Liquids (ILs) and Deep Eutectic Solvents (DES) based systems