Your search keyword '"Mahjoubi, K."' showing total 4 results

1. Copper–Chalcogen Bonds in Olfaction: Accurate ab Initio Characterization of CuSH and CuOH.

Author

Mahjoubi, K., Mehnen, B., Linguerri, R., Hochlaf, M., and Mouhib, H.

Published

2019

2. Spectroscopy and Stability of AlOP: A Possible Progenitor of Interstellar Metal.

Author

Trabelsi, T., Mahjoubi, K., Mehnen, B., Hochlaf, M., and Francisco, J. S.

Published

2019

3. Periodic Dispersion-Corrected Approach for Isolation Spectroscopy of N2 in an Argon Environment: Clusters, Surfaces, and Matrices.

Author

Makina, Y., Mahjoubi, K., Benoit, D. M., Jaidane, N.-E., Al-Mogren, M. Mogren, and Hochlaf, M.

Subjects

*SPECTROSCOPIC imaging, *VIBRATIONAL spectra, *DENSITY functional theory, *CLUSTERING of particles, *ARGON spectra, *ARGON plasmas

Abstract

Ab initio and Perdew, Burke, and Ernzerhof (PBE) density functional theory with dispersion correction (PBE-D3) calculations are performed to study N2-Arn (n ≤ 3) complexes and N2 trapped in Ar matrix (i.e., N2@Ar). For cluster computations, we used both Møller-Plesset (MP2) and PBE-D3 methods. For N2@Ar, we used a periodic-dispersion corrected model for Ar matrix, which consists on a slab of four layers of Ar atoms. We determined the equilibrium structures and binding energies of N2 interacting with these entities. We also deduced the N2 vibrational frequency shifts caused by clustering or embedding compared to an isolated N2 molecule. Upon complexation or embedding, the vibrational frequency of N2 is slightly shifted, while its equilibrium distance remains unchanged. This is due to the weak interactions between N2 and Ar within these compounds. Our calculations show the importance of inclusion of dispersion effects for the accurate description of geometrical and spectroscopic parameters of N2 isolated, in interaction with Ar surfaces, or trapped in Ar matrices. [ABSTRACT FROM AUTHOR]

Published

2017

4. Periodic Dispersion-Corrected Approach for Isolation Spectroscopy of N 2 in an Argon Environment: Clusters, Surfaces, and Matrices.

Author

Makina Y, Mahjoubi K, Benoit DM, Jaidane NE, Al-Mogren MM, and Hochlaf M

Abstract

Ab initio and Perdew, Burke, and Ernzerhof (PBE) density functional theory with dispersion correction (PBE-D3) calculations are performed to study N 2 -Ar n (n ≤ 3) complexes and N 2 trapped in Ar matrix (i.e., N 2 @Ar). For cluster computations, we used both Møller-Plesset (MP2) and PBE-D3 methods. For N 2 @Ar, we used a periodic-dispersion corrected model for Ar matrix, which consists on a slab of four layers of Ar atoms. We determined the equilibrium structures and binding energies of N 2 interacting with these entities. We also deduced the N 2 vibrational frequency shifts caused by clustering or embedding compared to an isolated N 2 molecule. Upon complexation or embedding, the vibrational frequency of N 2 is slightly shifted, while its equilibrium distance remains unchanged. This is due to the weak interactions between N 2 and Ar within these compounds. Our calculations show the importance of inclusion of dispersion effects for the accurate description of geometrical and spectroscopic parameters of N 2 isolated, in interaction with Ar surfaces, or trapped in Ar matrices.

Published

2017