Materials impact most aspects of our lives, including healthcare, energy production, data storage and pollution control. However, the design of functional materials cannot be approached with the certainty and the engineering rules that would be used in planning and constructing a macroscopic object, such as a car or bridge. To be experimentally realisable, candidate materials must be reasonably stable with respect to changes in the crystal packing; to be functionally promising, they must exhibit favourable properties. The stability of a given hypothetical configuration is difficult to predict, and the “possibility space” of different geometric arrangements and chemical compositions – both of which impact the resulting properties -- is enormous and challenging to explore. Even once promising candidates are proposed, the synthesis and characterisation of such materials is not straightforward, potentially requiring a great deal of trial-and-error and exhaustive surveys of synthetic routes and conditions.
Our project aims to change the way that we discover new molecular materials by revolutionizing the exploration process. The programme integrates state-of-the-art computational chemistry methods, synthetic chemistry expertise, and laboratory robotics to transform our materials discovery capabilities. Our vision is of two related scientific “engines”. Firstly, a Computational Engine will perform intelligent, evolutionary exploration of the possibility space, using organic crystal structure prediction (CSP) methods and artificial intelligence (AI, or “machine learning”, ML) to explore the relationships between chemical composition, stable crystal structures, and desirable properties. Secondly, an Experimental Engine will carry out autonomous synthesis, characterisation, and properties testing of proposed materials using cutting-edge, AI-enhanced mobile “robot chemists”. The ultimate vision of ADAM is to couple these two engines together, creating an autonomous discovery platform that amplifies human creativity by searching the vast, unexplored chemical space for new materials with step-change properties.