A photochemical approach to extended corannulenes
Graphene sheets with perfect atomic lattice show perfect electronic properties, but structural defects occur during the growth or processing of the material. Due to the inability to precisely control the length and the breadth of an atomically thin structure obtained by large-scale methods such as c...
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Nanyang Technological University
2020
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sg-ntu-dr.10356-1447932023-02-28T23:55:04Z A photochemical approach to extended corannulenes Dzeneta, Halilovic Mihaiela Stuparu School of Physical and Mathematical Sciences mstuparu@ntu.edu.sg Science::Chemistry::Organic chemistry::Aromatic compounds Science::Chemistry::Organic chemistry::Organic synthesis Graphene sheets with perfect atomic lattice show perfect electronic properties, but structural defects occur during the growth or processing of the material. Due to the inability to precisely control the length and the breadth of an atomically thin structure obtained by large-scale methods such as chemical vapor-deposition, tremendous effort has been invested into developing novel methods and strategies to access such unique architectures through rational (‘bottom-up’) synthetic approaches. We envisaged that taking corannulene, a molecule harboring an in-built defect in form of a central five-membered ring, and extending it would allow us to control where the defect will appear and thus control the properties of the extended carbon structures. Previously reported methods for the extension of corannulene scaffold, like flash vacuum pyrolysis and metal-catalyzed processes suffer from many disadvantages, like harsh conditions, low yields, use of expensive and environmentally unfriendly metal-based catalysts, etc. To overcome these disadvantages, we developed a new synthetic approach, which is mild, efficient, inexpensive, and with very good yields. In this approach, corannulene-based compounds that can undergo Wittig olefination or Heck coupling reactions are utilized to access diaryl-ethylene precursors. These compounds can then be subjected to a photochemically induced oxidative-cyclization process to yield a corannulene structure with extended π-framework. The generality of this method allows for the preparation of a myriad of polycyclic aromatic arenes as well as heteroarene structures. Doctor of Philosophy 2020-11-25T00:40:29Z 2020-11-25T00:40:29Z 2020 Thesis-Doctor of Philosophy Dzeneta, H. (2020). A photochemical approach to extended corannulenes. Doctoral thesis, Nanyang Technological University, Singapore. https://hdl.handle.net/10356/144793 10.32657/10356/144793 en This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License (CC BY-NC 4.0). application/pdf Nanyang Technological University |
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Science::Chemistry::Organic chemistry::Aromatic compounds Science::Chemistry::Organic chemistry::Organic synthesis Dzeneta, Halilovic A photochemical approach to extended corannulenes |
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Graphene sheets with perfect atomic lattice show perfect electronic properties, but structural defects occur during the growth or processing of the material. Due to the inability to precisely control the length and the breadth of an atomically thin structure obtained by large-scale methods such as chemical vapor-deposition, tremendous effort has been invested into developing novel methods and strategies to access such unique architectures through rational (‘bottom-up’) synthetic approaches. We envisaged that taking corannulene, a molecule harboring an in-built defect in form of a central five-membered ring, and extending it would allow us to control where the defect will appear and thus control the properties of the extended carbon structures. Previously reported methods for the extension of corannulene scaffold, like flash vacuum pyrolysis and metal-catalyzed processes suffer from many disadvantages, like harsh conditions, low yields, use of expensive and environmentally unfriendly metal-based catalysts, etc. To overcome these disadvantages, we developed a new synthetic approach, which is mild, efficient, inexpensive, and with very good yields. In this approach, corannulene-based compounds that can undergo Wittig olefination or Heck coupling reactions are utilized to access diaryl-ethylene precursors. These compounds can then be subjected to a photochemically induced oxidative-cyclization process to yield a corannulene structure with extended π-framework. The generality of this method allows for the preparation of a myriad of polycyclic aromatic arenes as well as heteroarene structures. |
| author2 |
Mihaiela Stuparu |
| author_facet |
Mihaiela Stuparu Dzeneta, Halilovic |
| format |
Thesis-Doctor of Philosophy |
| author |
Dzeneta, Halilovic |
| author_sort |
Dzeneta, Halilovic |
| title |
A photochemical approach to extended corannulenes |
| title_short |
A photochemical approach to extended corannulenes |
| title_full |
A photochemical approach to extended corannulenes |
| title_fullStr |
A photochemical approach to extended corannulenes |
| title_full_unstemmed |
A photochemical approach to extended corannulenes |
| title_sort |
photochemical approach to extended corannulenes |
| publisher |
Nanyang Technological University |
| publishDate |
2020 |
| url |
https://hdl.handle.net/10356/144793 |
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1759857391923363840 |