Modular, multi-robot integration of laboratories: an autonomous workflow for solid-state chemistry

Amy M Lunt; Hatem Fakhruldeen; Gabriella Pizzuto; Louis Longley; Alexander White; Nicola Rankin; Rob Clowes; Ben Alston; Lucia Gigli; Graeme M Day; Andrew I Cooper; Samantha Y Chong

doi:10.1039/d3sc06206f

Modular, multi-robot integration of laboratories: an autonomous workflow for solid-state chemistry

Chem Sci. 2023 Dec 26;15(7):2456-2463. doi: 10.1039/d3sc06206f. eCollection 2024 Feb 14.

Authors

Amy M Lunt^{1

2}, Hatem Fakhruldeen¹, Gabriella Pizzuto¹, Louis Longley¹, Alexander White¹, Nicola Rankin^{1

2}, Rob Clowes¹, Ben Alston^{1

2}, Lucia Gigli³, Graeme M Day³, Andrew I Cooper^{1

2}, Samantha Y Chong^{1

2}

Affiliations

¹ Department of Chemistry and Materials Innovation Factory, University of Liverpool L7 3NY UK aicooper@liverpool.ac.uk schong@liverpool.ac.uk.
² Leverhulme Research Centre for Functional Materials Design, University of Liverpool Liverpool L7 3NY UK.
³ Computational Systems Chemistry, School of Chemistry, University of Southampton SO17 1BJ UK.

Abstract

Automation can transform productivity in research activities that use liquid handling, such as organic synthesis, but it has made less impact in materials laboratories, which require sample preparation steps and a range of solid-state characterization techniques. For example, powder X-ray diffraction (PXRD) is a key method in materials and pharmaceutical chemistry, but its end-to-end automation is challenging because it involves solid powder handling and sample processing. Here we present a fully autonomous solid-state workflow for PXRD experiments that can match or even surpass manual data quality, encompassing crystal growth, sample preparation, and automated data capture. The workflow involves 12 steps performed by a team of three multipurpose robots, illustrating the power of flexible, modular automation to integrate complex, multitask laboratories.