Rate My Professor Jenny Pringle

Professor Jenny Pringle is a Professor in the Institute for Frontier Materials within the Faculty of Science, Engineering and Built Environment at Deakin University. She earned her first-class BSc Honours and PhD from the University of Edinburgh in 2001, with her doctoral research focused on the synthesis and use of ionic liquids. Following her PhD, she joined Monash University in 2002, where she advanced her expertise in ionic electrolytes. From 2008 to 2012, she held a prestigious Australian Research Council (ARC) Queen Elizabeth II Fellowship, investigating ionic electrolytes for dye-sensitized solar cells. In 2013, she moved to Deakin University as a Senior Research Fellow, progressing to her current professorial role. Pringle is recognized as a leader in research and research training on new materials for energy applications. She serves as Director of the ARC Industrial Transformation Training Centre for Future Energy Storage Technologies (StorEnergy) and as a Chief Investigator in the ARC Centre of Excellence for Electromaterials Science (ACES).

Her research specializes in the development and application of ionic liquids and organic ionic plastic crystals as electrolytes for advanced energy technologies, including thermal energy harvesting, CO2 separation, and solid-state lithium batteries. Key publications include 'Organic ionic plastic crystals having colossal barocaloric effects' (Science, 2025), 'Ionic liquids for energy, materials, and medicine' (Chemical Communications, 2014), 'Redox-active quasi-solid-state electrolytes for thermal energy harvesting' (Physical Chemistry Chemical Physics, 2016), and 'Modulation of Sodium-Metal Interphase through Ionic Liquid Electrolytes' (ACS Applied Energy Materials, 2016). She is a Fellow of the Royal Society of Chemistry and has served on international advisory boards. Pringle contributes to professional activities through plenary lectures, such as at the International Conference on Nanomaterials for Batteries (ICNaB 2025), and editorial roles. Her work has significant impact, advancing sustainable energy solutions through innovative electromaterials.