Alkane transformations through binding to metals. Alkanes are fully saturated hydrocarbons and they are the major components of petroleum, including natural gas and liquid hydrocarbon fuels. They are abundant but finite, and their primary usage has been as fuels since they burn readily and release energy. Alkanes are relatively low-value, high-volume chemical feedstocks which are not easy to convert into more useful value-added materials. This project focuses on developing positively charged met ....Alkane transformations through binding to metals. Alkanes are fully saturated hydrocarbons and they are the major components of petroleum, including natural gas and liquid hydrocarbon fuels. They are abundant but finite, and their primary usage has been as fuels since they burn readily and release energy. Alkanes are relatively low-value, high-volume chemical feedstocks which are not easy to convert into more useful value-added materials. This project focuses on developing positively charged metal-based compounds that can bind directly to alkanes to increase their reactivity and enable their transformation into higher value products such as alcohols and olefins which are important chemical feedstocks.Read moreRead less
Deciphering ion specificity in complex electrolytes . This project aims to understand how ions influence the behaviour and properties of complex electrolytes (solutions containing either multiple ions, solvent mixtures, high electrolyte concentrations or a variety of interfaces, solutes or polymers). Complex electrolytes are ubiquitous in colloidal and particle technologies and underpin industrial and natural processes. Our team will combine experiment, simulation and theory to deliver a univers ....Deciphering ion specificity in complex electrolytes . This project aims to understand how ions influence the behaviour and properties of complex electrolytes (solutions containing either multiple ions, solvent mixtures, high electrolyte concentrations or a variety of interfaces, solutes or polymers). Complex electrolytes are ubiquitous in colloidal and particle technologies and underpin industrial and natural processes. Our team will combine experiment, simulation and theory to deliver a universal framework for understanding and predicting specific ion effects in complex electrolytes. The project outcomes are expected to deliver new understanding for researchers, robust rules of thumb for technologists and a public resource for data-driven solutions in applications utilising salt solutions. Read moreRead less