Mode-dependent H atom tunneling dynamics of the S₁ phenol is resolved by the simple topographic view of the potential energy surfaces along the conical intersection seam
Mode-dependent H atom tunneling dynamics of the O-H bond predissociation of the S1 phenol has been theoretically analyzed. As the tunneling is governed by the complicated multi-dimensional potential energy surfaces that are dynamically shaped by the upper-lying S1(ππ*)/S2(πσ*) conical intersection,...
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sg-ntu-dr.10356-1693692023-07-17T15:34:57Z Mode-dependent H atom tunneling dynamics of the S₁ phenol is resolved by the simple topographic view of the potential energy surfaces along the conical intersection seam Kim, Junggil Woo, Kyung Chul Kim, Sang Kyu School of Physical and Mathematical Sciences Science::Chemistry Molecular Physics Potential Energy Mode-dependent H atom tunneling dynamics of the O-H bond predissociation of the S1 phenol has been theoretically analyzed. As the tunneling is governed by the complicated multi-dimensional potential energy surfaces that are dynamically shaped by the upper-lying S1(ππ*)/S2(πσ*) conical intersection, the mode-specific tunneling dynamics of phenol (S1) has been quite formidable to be understood. Herein, we have examined the topography of the potential energy surface along the particular S1 vibrational mode of interest at the nuclear configurations of the S1 minimum and S1/S2 conical intersection. The effective adiabatic tunneling barrier experienced by the reactive flux at the particular S1 vibrational mode excitation is then uniquely determined by the topographic shape of the potential energy surface extended along the conical intersection seam coordinate associated with the particular vibrational mode. The resultant multi-dimensional coupling of the specific vibrational mode to the tunneling coordinate is then reflected in the mode-dependent tunneling rate as well as nonadiabatic transition probability. Remarkably, the mode-specific experimental result of the S1 phenol tunneling reaction [K. C. Woo and S. K. Kim, J. Phys. Chem. A 123, 1529-1537 (2019)] (in terms of the qualitative and relative mode-dependent dynamic behavior) could be well rationalized by semi-classical calculations based on the mode-specific topography of the effective tunneling barrier, providing the clear conceptual insight that the skewed potential energy surfaces along the conical intersection seam (strongly or weakly coupled to the tunneling reaction coordinate) may dictate the tunneling dynamics in the proximity of the conical intersection. Published version This work was financially supported by the National Research Foundation (NRF) of Korea under the projects: Grant Nos. 2019K1A3A1A14064258 and 2019R1A6A1A10073887. 2023-07-17T02:46:04Z 2023-07-17T02:46:04Z 2023 Journal Article Kim, J., Woo, K. C. & Kim, S. K. (2023). Mode-dependent H atom tunneling dynamics of the S₁ phenol is resolved by the simple topographic view of the potential energy surfaces along the conical intersection seam. Journal of Chemical Physics, 158(10), 104301-. https://dx.doi.org/10.1063/5.0143655 0021-9606 https://hdl.handle.net/10356/169369 10.1063/5.0143655 36922134 2-s2.0-85149904012 10 158 104301 en Journal of Chemical Physics © 2023 Author(s). All rights reserved. This article may be downloaded for personal use only. Any other use requires prior permission of the author and AIP Publishing. This article appeared in Kim, J., Woo, K. C. & Kim, S. K. (2023). Mode-dependent H atom tunneling dynamics of the S₁ phenol is resolved by the simple topographic view of the potential energy surfaces along the conical intersection seam. Journal of Chemical Physics, 158(10), 104301-, and may be found at https://doi.org/10.1063/5.0143655. application/pdf |
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Science::Chemistry Molecular Physics Potential Energy Kim, Junggil Woo, Kyung Chul Kim, Sang Kyu Mode-dependent H atom tunneling dynamics of the S₁ phenol is resolved by the simple topographic view of the potential energy surfaces along the conical intersection seam |
| description |
Mode-dependent H atom tunneling dynamics of the O-H bond predissociation of the S1 phenol has been theoretically analyzed. As the tunneling is governed by the complicated multi-dimensional potential energy surfaces that are dynamically shaped by the upper-lying S1(ππ*)/S2(πσ*) conical intersection, the mode-specific tunneling dynamics of phenol (S1) has been quite formidable to be understood. Herein, we have examined the topography of the potential energy surface along the particular S1 vibrational mode of interest at the nuclear configurations of the S1 minimum and S1/S2 conical intersection. The effective adiabatic tunneling barrier experienced by the reactive flux at the particular S1 vibrational mode excitation is then uniquely determined by the topographic shape of the potential energy surface extended along the conical intersection seam coordinate associated with the particular vibrational mode. The resultant multi-dimensional coupling of the specific vibrational mode to the tunneling coordinate is then reflected in the mode-dependent tunneling rate as well as nonadiabatic transition probability. Remarkably, the mode-specific experimental result of the S1 phenol tunneling reaction [K. C. Woo and S. K. Kim, J. Phys. Chem. A 123, 1529-1537 (2019)] (in terms of the qualitative and relative mode-dependent dynamic behavior) could be well rationalized by semi-classical calculations based on the mode-specific topography of the effective tunneling barrier, providing the clear conceptual insight that the skewed potential energy surfaces along the conical intersection seam (strongly or weakly coupled to the tunneling reaction coordinate) may dictate the tunneling dynamics in the proximity of the conical intersection. |
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School of Physical and Mathematical Sciences |
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School of Physical and Mathematical Sciences Kim, Junggil Woo, Kyung Chul Kim, Sang Kyu |
| format |
Article |
| author |
Kim, Junggil Woo, Kyung Chul Kim, Sang Kyu |
| author_sort |
Kim, Junggil |
| title |
Mode-dependent H atom tunneling dynamics of the S₁ phenol is resolved by the simple topographic view of the potential energy surfaces along the conical intersection seam |
| title_short |
Mode-dependent H atom tunneling dynamics of the S₁ phenol is resolved by the simple topographic view of the potential energy surfaces along the conical intersection seam |
| title_full |
Mode-dependent H atom tunneling dynamics of the S₁ phenol is resolved by the simple topographic view of the potential energy surfaces along the conical intersection seam |
| title_fullStr |
Mode-dependent H atom tunneling dynamics of the S₁ phenol is resolved by the simple topographic view of the potential energy surfaces along the conical intersection seam |
| title_full_unstemmed |
Mode-dependent H atom tunneling dynamics of the S₁ phenol is resolved by the simple topographic view of the potential energy surfaces along the conical intersection seam |
| title_sort |
mode-dependent h atom tunneling dynamics of the s₁ phenol is resolved by the simple topographic view of the potential energy surfaces along the conical intersection seam |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/169369 |
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1773551245283295232 |