Theoretical study of catalytic baeyer-villiger oxidation with applications in polyolefin degradation
Baeyer-Villiger oxidation is a common organic reaction used for many different purposes, known for its robustness and diverse substrate scope. With the rising interest in developing environmentally friendlier versions, the reaction that is catalyzed by Co(III) with N,N′-bis(salicylidene)ethylenediam...
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2020
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sg-ntu-dr.10356-1445092023-02-28T23:17:13Z Theoretical study of catalytic baeyer-villiger oxidation with applications in polyolefin degradation Wijaya, Christopher Kevin Naohiko Yoshikai School of Physical and Mathematical Sciences A*STAR Institute of High Performance Computing (IHPC), Singapore Adrian Matthew Mak NYOSHIKAI@ntu.edu.sg, makwk@ihpc.a-star.edu.sg Science::Chemistry::Physical chemistry::Catalysis Science::Chemistry::Physical chemistry::Physical organic chemistry Baeyer-Villiger oxidation is a common organic reaction used for many different purposes, known for its robustness and diverse substrate scope. With the rising interest in developing environmentally friendlier versions, the reaction that is catalyzed by Co(III) with N,N′-bis(salicylidene)ethylenediamine (salen) derivatives is found to be particularly appealing. Various greener improvements were effectively combined compared to the original reaction, while maintaining high yields and good enantioselectivity altogether. Potentially, the catalyst could also be developed further to aid polyethylene degradation. In this work, a theoretical study involving DFT calculations was carried out to study this class of catalysts. The uncatalyzed Baeyer-Villiger oxidation between a model ketone, butanone, and hydrogen peroxide was first investigated to find possible mechanistic pathways. The ground state multiplicity of the model catalyst, Co(III)-salen, was then analyzed further. This information was then used to elucidate the catalytic reaction pathway and mechanism. In short, it was found that the major catalyzed mechanism consists of two major steps, Criegee intermediate formation and alkyl migration. The model catalyst was found to lower the activation energy barrier at every step, thus improving the rate of reaction. To gain further insights into the catalyst mode of action, a modified version of the catalyst was investigated. The modifications affected the cis position relative to the substrate and resulted in modest activation energy lowering compared to that of the original catalyst. Bachelor of Science in Chemistry and Biological Chemistry 2020-11-10T06:42:02Z 2020-11-10T06:42:02Z 2020 Final Year Project (FYP) https://hdl.handle.net/10356/144509 en application/pdf Nanyang Technological University |
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Science::Chemistry::Physical chemistry::Catalysis Science::Chemistry::Physical chemistry::Physical organic chemistry Wijaya, Christopher Kevin Theoretical study of catalytic baeyer-villiger oxidation with applications in polyolefin degradation |
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Baeyer-Villiger oxidation is a common organic reaction used for many different purposes, known for its robustness and diverse substrate scope. With the rising interest in developing environmentally friendlier versions, the reaction that is catalyzed by Co(III) with N,N′-bis(salicylidene)ethylenediamine (salen) derivatives is found to be particularly appealing. Various greener improvements were effectively combined compared to the original reaction, while maintaining high yields and good enantioselectivity altogether. Potentially, the catalyst could also be developed further to aid polyethylene degradation. In this work, a theoretical study involving DFT calculations was carried out to study this class of catalysts. The uncatalyzed Baeyer-Villiger oxidation between a model ketone, butanone, and hydrogen peroxide was first investigated to find possible mechanistic pathways. The ground state multiplicity of the model catalyst, Co(III)-salen, was then analyzed further. This information was then used to elucidate the catalytic reaction pathway and mechanism. In short, it was found that the major catalyzed mechanism consists of two major steps, Criegee intermediate formation and alkyl migration. The model catalyst was found to lower the activation energy barrier at every step, thus improving the rate of reaction. To gain further insights into the catalyst mode of action, a modified version of the catalyst was investigated. The modifications affected the cis position relative to the substrate and resulted in modest activation energy lowering compared to that of the original catalyst. |
| author2 |
Naohiko Yoshikai |
| author_facet |
Naohiko Yoshikai Wijaya, Christopher Kevin |
| format |
Final Year Project |
| author |
Wijaya, Christopher Kevin |
| author_sort |
Wijaya, Christopher Kevin |
| title |
Theoretical study of catalytic baeyer-villiger oxidation with applications in polyolefin degradation |
| title_short |
Theoretical study of catalytic baeyer-villiger oxidation with applications in polyolefin degradation |
| title_full |
Theoretical study of catalytic baeyer-villiger oxidation with applications in polyolefin degradation |
| title_fullStr |
Theoretical study of catalytic baeyer-villiger oxidation with applications in polyolefin degradation |
| title_full_unstemmed |
Theoretical study of catalytic baeyer-villiger oxidation with applications in polyolefin degradation |
| title_sort |
theoretical study of catalytic baeyer-villiger oxidation with applications in polyolefin degradation |
| publisher |
Nanyang Technological University |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/144509 |
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1759857001159983104 |