Abstract
Amines are among the most important and frequently used chemical compounds due to their biological activity and a wide range of applications in industry. Reductive amination reactions are an efficient and facile route to synthesize long chain amines from sustainable sources by using a different available aldehydes and ketones, and a large variety of amines including primary, secondary and tertiary forms. The pathway of the reaction process is critically dependent on reaction parameters such as the pH of the reaction medium, choice of solvent (explicitly coordinating solvent) and process conditions. These parameters are affecting the reaction performance and the selectivity but are still not fully rationalized. Here, we investigate the microkinetics and thermodynamics of the individual steps of the reductive amination reaction by exploring the systems' parameters. Explicit water coordination to the aldehyde leads to a stepwise rather than concerted nucleophilic addition with a lower activation barrier by 6-10 kcal mol−1. At low pH, the pathway is changed by a direct protonation of the amine substrate. This protonation does not strongly affect the kinetics of the reaction, but the thermodynamic equilibria. The presence of an acid as a co-catalyst leads to the formation of an iminium intermediate and this drives the reaction forward. Thus, the presence of an acid as a co-catalyst clearly renders this pathway the thermodynamically preferred one. Consequently, altering the reaction parameters does not only influence the reaction kinetics, but also the thermodynamic profile of the pathways in all cases. Further understanding of the reaction dynamics is essential to develop a microkinetic model of the reaction to then control and engineer the process in order to rationally design routes to tailor-made products.
Original language | English |
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Pages (from-to) | 36662-36674 |
Number of pages | 13 |
Journal | RSC Advances |
Volume | 8 |
Issue number | 64 |
DOIs | |
Publication status | Published - 2018 |
Bibliographical note
Publisher Copyright:© The Royal Society of Chemistry.
Funding
We thank the Max Planck Society for the Advancement of Science for nancial support and the President of the MPG for a High-Impact Scholarship to EB. This work is part of the Collaborative Research Centre “Integrated Chemical Processes in Liquid Multiphase Systems” (project A4). Financial support by the Deutsche Forschungsgemeinscha (DFG) is gratefully acknowledged (TR 63). We gratefully acknowledge the computational source provided by the National High Performance Computing Center at Istanbul Technical University (Grant No. 5004722017) and ITU BAP (Project No. 38209).
Funders | Funder number |
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Deutsche Forschungsgemeinscha | |
ITU BAP | 38209 |
Center for High Performance Computing | |
Deutsche Forschungsgemeinschaft | TR 63 |
Istanbul Teknik Üniversitesi | 5004722017 |