2024-03-29T05:18:18Zhttp://digital.csic.es/dspace-oai/requestoai:digital.csic.es:10261/1589202020-12-10T15:59:18Zcom_10261_14181com_10261_4col_10261_14182
Bartolomei, Massimiliano
Pérez de Tudela, Ricardo
Arteaga, Kilian
González-Lezana, Tomás
Hernández, Marta I.
Campos-Martínez, José
Villarreal, Pablo
Hernández-Rojas, Javier
Bretón, José
Pirani, Fernando
2018-01-09T09:26:46Z
2018-01-09T09:26:46Z
2017-09-05
Physical Chemistry Chemical Physics 19: 26358- 26368 (2017)
http://hdl.handle.net/10261/158920
10.1039/c7cp03819d
http://dx.doi.org/10.13039/501100003329
Benchmark interaction energies between coronene, CH, and molecular hydrogen, H, have been computed by means of high level electronic structure calculations. Binding energies, equilibrium distances and strengths of the long range attraction, evaluated for the basic configurations of the H-CH complex, indicate that the system is not too affected by the relative orientations of the diatom, suggesting that its behavior can be approximated to that of a pseudoatom. The obtained energy profiles have confirmed the noncovalent nature of the bonding and serve to tune-up the parameters of a new force field based on the atom-bond approach which correctly describes the main features of the H-coronene interaction. The structure and binding energies of (para-H)-coronene clusters have been investigated with an additive model for the above mentioned interactions and exploiting basin-hopping and path integral Monte Carlo calculations for N = 1-16 at T = 2 K. Differences with respect to the prototypical (rare gas)-coronene aggregates have been discussed.
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openAccess
Adsorption of molecular hydrogen on coronene with a new potential energy surface
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