Author: ["Mark D. Symes","Philip J. Kitson","Jun Yan","Craig J. Richmond","Geoffrey J. T. Cooper","Richard W. Bowman","Turlif Vilbrandt","Leroy Cronin"]
CITE.CC academic search helps you expand the influence of your papers.
Abstract
Three-dimensional (3D) printing has the potential to transform science and technology by creating bespoke, low-cost appliances that previously required dedicated facilities to make. An attractive, but unexplored, application is to use a 3D printer to initiate chemical reactions by printing the reagents directly into a 3D reactionware matrix, and so put reactionware design, construction and operation under digital control. Here, using a low-cost 3D printer and open-source design software we produced reactionware for organic and inorganic synthesis, which included printed-in catalysts and other architectures with printed-in components for electrochemical and spectroscopic analysis. This enabled reactions to be monitored in situ so that different reactionware architectures could be screened for their efficacy for a given process, with a digital feedback mechanism for device optimization. Furthermore, solely by modifying reactionware architecture, reaction outcomes can be altered. Taken together, this approach constitutes a relatively cheap, automated and reconfigurable chemical discovery platform that makes techniques from chemical engineering accessible to typical synthetic laboratories. A low-cost 3D printer is used to combine chemical reactions and the reactor to produce an active ‘reactionware’ system for organic and inorganic synthesis. Active elements such as catalysts can be incorporated into the walls of printed reactors, and other printed-in components that enable electrochemical and spectroscopic analysis can also be included. Cite this article
Symes, M., Kitson, P., Yan, J. et al. Integrated 3D-printed reactionware for chemical synthesis and analysis. Nature Chem 4, 349–354 (2012). https://doi.org/10.1038/nchem.1313 