Professor Sara Walker is an astrobiologist and theoretical physicist. Her work focuses on the origins and nature of life, and in particular whether or not there are universal ‘laws of life’ that would allow predicting when life emerges and can guide our search for other examples on other worlds. Her research integrates diverse perspectives ranging from chemistry, biology, geology, astronomy and the foundations of physics, to computer science, cheminformatics, artificial life, artificial intelligence and consciousness. At Arizona State University she is Deputy Director of the Beyond Center for Fundamental Concepts in Science, Associate Director of the ASU-Santa Fe Institute Center for Biosocial Complex Systems and Professor in the School of Earth and Space Exploration. She is also a member of the External Faculty at the Santa Fe Institute. She is active in public engagement in science, with appearances on “Through the Wormhole”, NPR’s Science Friday, and on a number of international science festivals and podcasts. She has published in leading research journals and is an internationally recognized thought leader in the study of the origins of life, alien life and the search for a deeper understanding of ourselves in our universe.
Leroy (Lee) Cronin is the Regius Professor of Chemistry in Glasgow. Since the age of 9 Lee has wanted to explore chemistry using electronics to control matter. His research spans many disciplines and has four main aims: the construction of an artificial life form; the digitization of chemistry; the use of artificial intelligence in chemistry including the construction of ‘wet’ chemical computers; the exploration of complexity and information in chemistry. His recent work on the digitization of chemistry has resulted in a new programming paradigm for matter and organic synthesis and discovery – chemputation – which uses the worlds first domain specific and universal programming language for chemistry – XDL, see XDL-standard.com. His team designs and builds all their own robots from the ground up and the team currently has 25 different robotic systems operating across four domains: Organic synthesis; Energy materials discovery; Nanomaterials discovery; Formulation discovery. All the systems use XDL and are easily programmable for both manufacture and discovery. His group is organised and assembled transparently around ideas, avoids hierarchy, and aims to mentor researchers using a problem-based approach. Nothing is impossible until it is tried.