Continuous and scalable synthesis of a porous organic cage by twin screw extrusion (TSE)

Benjamin D Egleston; Michael C Brand; Francesca Greenwell; Michael E Briggs; Stuart L James; Andrew I Cooper; Deborah E Crawford; Rebecca L Greenaway

doi:10.1039/d0sc01858a

Continuous and scalable synthesis of a porous organic cage by twin screw extrusion (TSE)

Chem Sci. 2020 May 11;11(25):6582-6589. doi: 10.1039/d0sc01858a. eCollection 2020 Jul 7.

Authors

Benjamin D Egleston¹, Michael C Brand¹, Francesca Greenwell¹, Michael E Briggs¹, Stuart L James², Andrew I Cooper¹, Deborah E Crawford³, Rebecca L Greenaway^{1

4}

Affiliations

¹ Department of Chemistry and Materials Innovation Factory , University of Liverpool , 51 Oxford Street , Liverpool , L7 3NY , UK.
² School of Chemistry and Chemical Engineering , Queen's University Belfast , 39-123 Stranmillis Road , Belfast , Northern Ireland BT9 5AG , UK.
³ School of Chemistry and Biosciences , University of Bradford , Richmond Road , Bradford , BD7 1DP , UK . Email: d.crawford@bradford.ac.uk.
⁴ Department of Chemistry , Imperial College London , White City Campus, Wood Lane , London , W12 0BZ , UK . Email: r.greenaway@imperial.ac.uk.

Abstract

The continuous and scalable synthesis of a porous organic cage (CC3), obtained through a 10-component imine polycondensation between triformylbenzene and a vicinal diamine, was achieved using twin screw extrusion (TSE). Compared to both batch and flow syntheses, the use of TSE enabled the large scale synthesis of CC3 using minimal solvent and in short reaction times, with liquid-assisted grinding (LAG) also promoting window-to-window crystal packing to form a 3-D diamondoid pore network in the solid state. A new kinetically trapped [3+5] product was also observed alongside the formation of the targeted [4+6] cage species. Post-synthetic purification by Soxhlet extraction of the as-extruded 'technical grade' mixture of CC3 and [3+5] species rendered the material porous.