Abstract
The universe is molecularly rich, comprising from the simplest molecule (H2) to complex organic molecules (e.g., CH3CHO and NH2CHO), some of which of biological relevance (e.g., amino acids). This chemical richness is intimately linked to the different physical phases forming Solar-like planetary systems, in which at each phase, molecules of increasing complexity form. Interestingly, synthesis of some of these compounds only takes place in the presence of interstellar (IS) grains, i.e., solid-state sub-micron sized particles consisting of naked dust of silicates or carbonaceous materials that can be covered by water-dominated ice mantles. Surfaces of IS grains exhibit particular characteristics that allow the occurrence of pivotal chemical reactions, such as the presence of binding/catalytic sites and the capability to dissipate energy excesses through the grain phonons. The present know-how on the physicochemical features of IS grains has been obtained by the fruitful synergy of astronomical observational with astrochemical modelling and laboratory experiments. However, current limitations of these disciplines prevent us from having a full understanding of the IS grain surface chemistry as they cannot provide fundamental atomic-scale of grain surface elementary steps (i.e., adsorption, diffusion, reaction and desorption). This essential information can be obtained by means of simulations based on computational chemistry methods. One capability of these simulations deals with the construction of atom-based structural models mimicking the surfaces of IS grains, the very first step to investigate on the grain surface chemistry. This perspective aims to present the current state-of-the-art methods, techniques and strategies available in computational chemistry to model (i.e., construct and simulate) surfaces present in IS grains. Although we focus on water ice mantles and olivinic silicates as IS test case materials to exemplify the modelling procedures, a final discussion on the applicability of these approaches to simulate surfaces of other cosmic grain materials (e.g., cometary and meteoritic) is given.
Highlights
Introduction affiliationsThe formation of a Solar-like planetary system is the result of the evolution of a primordial interstellar cloud, which takes place through five physical steps: the prestellar, protostellar, protoplanetary disk, planetesimal and planet formation phases [1]
This represents an enormous advantage with respect to the wave function-based methods because, in density functional theory (DFT), the ρ(r) for a system of N electrons only depends on 3 spatial coordinates, while the corresponding wave function depends on 3N spatial and N spin variables
Either periodic or cluster approaches are used as possible paradigms to represent the external faces of the real material
Summary
The formation of a Solar-like planetary system is the result of the evolution of a primordial interstellar cloud, which takes place through five physical steps: the prestellar, protostellar, protoplanetary disk, planetesimal and planet formation phases [1]. This complex process is associated with an increase in molecular complexity, in which from one phase to the other the chemical composition grows in complexity because molecules formed in the previous steps react to form species that are even more complex [2,3]. Dust grains consist of bare silicates and carbonaceous materials, while the gaseous component, because of the high UV incidence due to the diffuse conditions, is mainly in the form of atoms and simple diatomic species
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