Optical band gap of cross-linked, curved, and radical polyaromatic hydrocarbons
n this work, the optical band gaps of polycyclic aromatic hydrocarbons (PAHs) crosslinked via an aliphatic bond, curved via pentagon integration and with radical character were computed using density functional theory. A variety of different functionals were benchmarked against optical band gaps (OB...
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sg-ntu-dr.10356-1522902023-12-29T06:45:11Z Optical band gap of cross-linked, curved, and radical polyaromatic hydrocarbons Menon, Angiras Dreyer, Jochen A. H. Martin, Jacob W. Akroyd, Jethro Robertson, John Kraft, Markus School of Chemical and Biomedical Engineering Cambridge Centre for Advanced Research and Education in Singapore (CARES) Engineering::Chemical engineering Polycyclic Aromatic Hydrocarbons Energy Gap n this work, the optical band gaps of polycyclic aromatic hydrocarbons (PAHs) crosslinked via an aliphatic bond, curved via pentagon integration and with radical character were computed using density functional theory. A variety of different functionals were benchmarked against optical band gaps (OBGs) measured by ultraviolet-visible spectroscopy with HSE06 being most accurate with a percentage error of 6% for a moderate basis set. Pericondensed aromatics with different symmetries were calculated with this improved functional providing new scaling relationships for the OBG versus size. Further calculations showed crosslinks cause a small decrease in the OBG of the monomers which saturates after 3–4 crosslinks. Curvature in PAHs was shown to increase the optical band gap due to the resulting change in hybridisation of the system, but this increase saturated at larger sizes. The increase in OBG between a flat PAH and a strained curved one was shown to be equivalent to a difference of several rings in size for pericondensed aromatic systems. The effect of σ-radicals on the optical band gap was also shown to be negligible, however, π-radicals were found to decrease the band gap by ∼0.5 eV. These findings have applications in understanding the molecular species involved in soot formation. National Research Foundation (NRF) Accepted version AM acknowledges Johnson Matthey for financial support. The authors also acknowledge the financial support of the Singapore National Research Foundation (NRF) through the Campus for Research Excellence and Technological Enterprise (CREATE) program. MK gratefully acknowledges the support of the Alexander von Humboldt foundation. 2021-07-29T05:39:36Z 2021-07-29T05:39:36Z 2019 Journal Article Menon, A., Dreyer, J. A. H., Martin, J. W., Akroyd, J., Robertson, J. & Kraft, M. (2019). Optical band gap of cross-linked, curved, and radical polyaromatic hydrocarbons. Physical Chemistry Chemical Physics, 21(29), 16240-16251. https://dx.doi.org/10.1039/C9CP02363A 1463-9076 https://hdl.handle.net/10356/152290 10.1039/C9CP02363A 29 21 16240 16251 en Physical Chemistry Chemical Physics © 2019 The Owner Societies. All rights reserved. This paper was published by Royal Society of Chemistry in Physical Chemistry Chemical Physics and is made available with permission of The Owner Societies. application/pdf application/pdf |
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Engineering::Chemical engineering Polycyclic Aromatic Hydrocarbons Energy Gap |
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Engineering::Chemical engineering Polycyclic Aromatic Hydrocarbons Energy Gap Menon, Angiras Dreyer, Jochen A. H. Martin, Jacob W. Akroyd, Jethro Robertson, John Kraft, Markus Optical band gap of cross-linked, curved, and radical polyaromatic hydrocarbons |
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n this work, the optical band gaps of polycyclic aromatic hydrocarbons (PAHs) crosslinked via an aliphatic bond, curved via pentagon integration and with radical character were computed using density functional theory. A variety of different functionals were benchmarked against optical band gaps (OBGs) measured by ultraviolet-visible spectroscopy with HSE06 being most accurate with a percentage error of 6% for a moderate basis set. Pericondensed aromatics with different symmetries were calculated with this improved functional providing new scaling relationships for the OBG versus size. Further calculations showed crosslinks cause a small decrease in the OBG of the monomers which saturates after 3–4 crosslinks. Curvature in PAHs was shown to increase the optical band gap due to the resulting change in hybridisation of the system, but this increase saturated at larger sizes. The increase in OBG between a flat PAH and a strained curved one was shown to be equivalent to a difference of several rings in size for pericondensed aromatic systems. The effect of σ-radicals on the optical band gap was also shown to be negligible, however, π-radicals were found to decrease the band gap by ∼0.5 eV. These findings have applications in understanding the molecular species involved in soot formation. |
| author2 |
School of Chemical and Biomedical Engineering |
| author_facet |
School of Chemical and Biomedical Engineering Menon, Angiras Dreyer, Jochen A. H. Martin, Jacob W. Akroyd, Jethro Robertson, John Kraft, Markus |
| format |
Article |
| author |
Menon, Angiras Dreyer, Jochen A. H. Martin, Jacob W. Akroyd, Jethro Robertson, John Kraft, Markus |
| author_sort |
Menon, Angiras |
| title |
Optical band gap of cross-linked, curved, and radical polyaromatic hydrocarbons |
| title_short |
Optical band gap of cross-linked, curved, and radical polyaromatic hydrocarbons |
| title_full |
Optical band gap of cross-linked, curved, and radical polyaromatic hydrocarbons |
| title_fullStr |
Optical band gap of cross-linked, curved, and radical polyaromatic hydrocarbons |
| title_full_unstemmed |
Optical band gap of cross-linked, curved, and radical polyaromatic hydrocarbons |
| title_sort |
optical band gap of cross-linked, curved, and radical polyaromatic hydrocarbons |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/152290 |
| _version_ |
1787136412177399808 |