Classical dynamics of dissociative adsorption for a nonactivated system: The role of zero point energy
We present dissociative adsorption probabilities of H2 on Pd(111) computed with the classical trajectory method. We perform both classical (C) and quasiclassical (QC) calculations, the latter including, by contrast with the former, the initial zero point energy (ZPE) of H2. We analyze in detail the...
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| Veröffentlicht in: | The Journal of chemical physics 2002-05, Vol.116 (20), p.9005-9013 |
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| container_title | The Journal of chemical physics |
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| creator | Busnengo, H. F. Crespos, C. Dong, W. Rayez, J. C. Salin, A. |
| description | We present dissociative adsorption probabilities of H2 on Pd(111) computed with the classical trajectory method. We perform both classical (C) and quasiclassical (QC) calculations, the latter including, by contrast with the former, the initial zero point energy (ZPE) of H2. We analyze in detail the role played by the ZPE and demonstrate the strong and weak points of both C and QC calculations. We show that ZPE is crucial in accelerating the molecules toward the surface through vibrational softening. However, at low energies, dynamic trapping is quenched in QC calculations by processes of vibration to rotation energy transfer that would be associated with closed channels in a quantum approach. In this study we use a new representation of the H2/Pd(111) potential energy surface (obtained by interpolation of ab initio data) with a significantly better accuracy in the entrance channel region which plays a decisive role in the dissociation dynamics. |
| doi_str_mv | 10.1063/1.1471248 |
| format | Article |
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However, at low energies, dynamic trapping is quenched in QC calculations by processes of vibration to rotation energy transfer that would be associated with closed channels in a quantum approach. 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We perform both classical (C) and quasiclassical (QC) calculations, the latter including, by contrast with the former, the initial zero point energy (ZPE) of H2. We analyze in detail the role played by the ZPE and demonstrate the strong and weak points of both C and QC calculations. We show that ZPE is crucial in accelerating the molecules toward the surface through vibrational softening. However, at low energies, dynamic trapping is quenched in QC calculations by processes of vibration to rotation energy transfer that would be associated with closed channels in a quantum approach. In this study we use a new representation of the H2/Pd(111) potential energy surface (obtained by interpolation of ab initio data) with a significantly better accuracy in the entrance channel region which plays a decisive role in the dissociation dynamics.</abstract><doi>10.1063/1.1471248</doi><tpages>9</tpages></addata></record> |
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| ispartof | The Journal of chemical physics, 2002-05, Vol.116 (20), p.9005-9013 |
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| language | eng |
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| source | AIP Journals Complete; AIP Digital Archive |
| title | Classical dynamics of dissociative adsorption for a nonactivated system: The role of zero point energy |
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