Proceedings

EPJ D Highlight - Atmospheric chemistry hinges on better physics model

Details: Published on 29 September 2014

Representations of a component of the wave packet of the N₂O molecule during photoabsorption. © M. N. Daud

Improved theoretical model of photoabsorption of nitrous oxide matters because its by-product, nitric oxide, is involved in the catalytic destruction of stratospheric ozone

New theoretical physics models could help us better grasp the atmospheric chemistry of ozone depletion. Indeed, understanding photoabsorption of nitrous oxide (N₂O)-- a process which involves the transfer of the energy of a photo to the molecule--matters because a small fraction of N₂O reacts with oxygen atoms in the stratosphere to produce, among other things, nitric oxide (NO). The latter participates to the catalytic destruction of ozone (O₃). Now, new theoretical work unveils the actual dynamic of the photoabsorption of nitrous oxide (N₂O) molecules. These findings by Mohammad Noh Daud from the University of Malaya, Kuala Lumpur in Malaysia, have just been published in EPJ D. The work has led to new calculations of the probability of an absorption process taking place, also referred to as absorption cross section, which confirm experimental results.

In this study, the author introduces improvements in an established calculation approach, referred to as the ab initio time-dependent method. It helps calculate the absorption cross section, or spectrum, of nitrous oxide. The advantage of this approach is that it immediately yields the energy dependence of cross section or spectrum from a single calculation. By taking into account key factors such as the correct angular momentum coupling of the molecule and the component of the transition dipole moment vector, the theoretical model of calculated spectrum has produced better results than previously obtained and more closely matches experimental observations.

Daud’s calculation thus provides an improved theoretical prediction of how nitrous oxide evolves and breaks down over time, thus contributing to the nitrous oxide photoabsorption process. Because such processes occur in a small gap between the absorption band of oxygen and that of ozone, the predicted major dissociation pathway allows us to understand the involvement of nitrous oxide in the formation of ozone at molecular level.

M. N. Daud (2014), Accurate treatment of total photoabsorption cross sections by an ab initio time-dependent method , European Physical Journal D, DOI: 10.1140/epjd/e2014-50400-4

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