Abstract
There is no consensus as yet to account for the significant presence of water on the terrestrial planets, but suggested sources include direct hydrogen adsorption from the parent molecular cloud after the planets’ formation, and delivery of hydrous material via comets or asteroids external to the zone of the terrestrial planets. Alternatively, a more recent idea is that water may have directly adsorbed onto the interstellar dust grains involved in planetary formation. In this work, we use electronic structure calculations based on the density functional theory to investigate and compare the bulk and {010} surface structures of the magnesium and iron end-members of the silicate mineral olivine, namely forsterite and fayalite, respectively. We also report our results on the adsorption of atomic hydrogen at the mineral surfaces, where our calculations show that there is no activation barrier to the adsorption of atomic hydrogen at these surfaces. Furthermore, different surface sites activate the atom to form either adsorbed hydride or proton species in the form of hydroxy groups on the same surface, which indicates that these mineral surfaces may have acted as catalytic sites in the immobilization and reaction of hydrogen atoms to form dihydrogen gas or water molecules.
Highlights
Introductionmolecular clouds (MCs) are considered to act as ‘stellar nurseries’ as their denser core areas collapse under gravity to form clusters of protostars—a type of young stellar object (YSO), or early-stage star—which develop circumstellar discs in orbital motion around themselves, accreting material gradually from the parent MC
We have modelled the bulk and {010} surface of the olivine material, and compared the differences between the Mg and Fe end-members of the material, which showed that the effect of the cation type on the surface structure is insignificant
We have considered a range of hydrogen adsorption scenarios on both the defect-free {010} surfaces of forsterite and fayalite, as well as hydrogen adsorption near cation vacancies in the surface
Summary
MCs are considered to act as ‘stellar nurseries’ as their denser core areas collapse under gravity to form clusters of protostars—a type of young stellar object (YSO), or early-stage star—which develop circumstellar discs in orbital motion around themselves, accreting material gradually from the parent MC. These accretion discs are largely made up of gases and dust particles, which comprise carbonaceous and siliceous materials. Surface adsorption could aid in the reaction of two hydrogen atoms to form gaseous H2 It is this latter process that has been investigated in the most depth in previous studies. The possible activity of small clusters (less than 15 Å diameter) with structures based on pyroxene has been considered using computational methods [17]
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