Nanostructured Ionic-Molecular Hybrid Liquids. This project aims to produce a new class of green, economical, non-toxic, low volatility, designer solvents from mixtures of one or more molecular components, and ionic liquid-inspired salts. By manipulating the intermolecular forces between components of these nanostructured ionic molecular "hybrid liquids" (HLs), we will develop new understanding of how liquid structure arises from the nano- to the colloidal and even micro-scale. HLs will enable ....Nanostructured Ionic-Molecular Hybrid Liquids. This project aims to produce a new class of green, economical, non-toxic, low volatility, designer solvents from mixtures of one or more molecular components, and ionic liquid-inspired salts. By manipulating the intermolecular forces between components of these nanostructured ionic molecular "hybrid liquids" (HLs), we will develop new understanding of how liquid structure arises from the nano- to the colloidal and even micro-scale. HLs will enable the development novel complex fluids, which are liquids containing interacting particles, polymers, and/or surfactants. Lubricants developed from HL based complex fluids will act as a “test-bed” application for the new understanding this project will engender, towards use of HLs in diverse areas.Read moreRead less
Green working liquids for an energy efficient future. Ionic liquids (ILs) have enormous potential as advanced materials due to their unusual properties. This project will develop ILs for use as energy efficient lubricants, electrochemical solvents and heat transfer fluids. These technologies will decrease Australia's energy consumption, reduce carbon dioxide emissions, and stimulate economic growth.