Deciphering complexity in Pd–catalyzed cross-couplings

George E. Clarke; James D. Firth; Lyndsay A. Ledingham; Chris S. Horbaczewskyj; Richard A. Bourne; Joshua T. W. Bray; Poppy L. Martin; Jonathan B. Eastwood; Rebecca Campbell; Alex Pagett; Duncan J. MacQuarrie; John M. Slattery; Jason M. Lynam; Adrian C. Whitwood; Jessica Milani; Sam Hart; Julie Wilson; Ian J. S. Fairlamb

doi:10.1038/s41467-024-47939-5

Nature Communications (May 2024)

Deciphering complexity in Pd–catalyzed cross-couplings

George E. Clarke,
James D. Firth,
Lyndsay A. Ledingham,
Chris S. Horbaczewskyj,
Richard A. Bourne,
Joshua T. W. Bray,
Poppy L. Martin,
Jonathan B. Eastwood,
Rebecca Campbell,
Alex Pagett,
Duncan J. MacQuarrie,
John M. Slattery,
Jason M. Lynam,
Adrian C. Whitwood,
Jessica Milani,
Sam Hart,
Julie Wilson,
Ian J. S. Fairlamb

Affiliations

George E. Clarke: Department of Chemistry, University of York
James D. Firth: Department of Chemistry, University of York
Lyndsay A. Ledingham: Department of Chemistry, University of York
Chris S. Horbaczewskyj: Department of Chemistry, University of York
Richard A. Bourne: Institute of Process Research and Development, School of Chemistry & School of Chemical and Process Engineering, University of Leeds
Joshua T. W. Bray: Department of Chemistry, University of York
Poppy L. Martin: Department of Chemistry, University of York
Jonathan B. Eastwood: Department of Chemistry, University of York
Rebecca Campbell: Department of Chemistry, University of York
Alex Pagett: Department of Chemistry, University of York
Duncan J. MacQuarrie: Department of Chemistry, University of York
John M. Slattery: Department of Chemistry, University of York
Jason M. Lynam: Department of Chemistry, University of York
Adrian C. Whitwood: Department of Chemistry, University of York
Jessica Milani: Department of Chemistry, University of York
Sam Hart: Department of Chemistry, University of York
Julie Wilson: Department of Mathematics, University of York
Ian J. S. Fairlamb: Department of Chemistry, University of York

DOI: https://doi.org/10.1038/s41467-024-47939-5
Journal volume & issue: Vol. 15, no. 1
pp. 1 – 15

Abstract

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Abstract Understanding complex reaction systems is critical in chemistry. While synthetic methods for selective formation of products are sought after, oftentimes it is the full reaction signature, i.e., complete profile of products/side-products, that informs mechanistic rationale and accelerates discovery chemistry. Here, we report a methodology using high-throughput experimentation and multivariate data analysis to examine the full signature of one of the most complicated chemical reactions catalyzed by palladium known in the chemical literature. A model Pd-catalyzed reaction was selected involving functionalization of 2-bromo-N-phenylbenzamide and multiple bond activation pathways. Principal component analysis, correspondence analysis and heatmaps with hierarchical clustering reveal the factors contributing to the variance in product distributions and show associations between solvents and reaction products. Using robust data from experiments performed with eight solvents, for four different reaction times at five different temperatures, we correlate side-products to a major dominant N-phenyl phenanthridinone product, and many other side products.

Published in Nature Communications

ISSN: 2041-1723 (Online)
Publisher: Nature Portfolio
Country of publisher: United Kingdom
LCC subjects: Science
Website: https://www.nature.com/ncomms/

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