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Literature DB >> 30190625

Formation and Destruction of SiS in Space.

Alexandre Zanchet¹, Octavio Roncero¹, Marcelino Agúndez¹, José Cernicharo¹.

Abstract

The presence of SiS in space seems to be restricted to a few selected types of astronomical environments. It is long known to be present in circumstellar envelopes around evolved stars and it has also been detected in a handful of star-forming regions with evidence of outflows, like Sgr B2, Orion KL and more recently L1157-B1. The kinetics of reactions involving SiS is very poorly known and here we revisit the chemistry of SiS in space by studying some potentially important reactions of formation and destruction of this molecule. We calculated ab initio potential energy surfaces of the SiOS system and computed rate coefficients in the temperature range 50-2500 K for the reaction of destruction of SiS, in collisions with atomic O, and of its formation, through the reaction between Si and SO. We find that both reactions are rapid, with rate coefficients of a few times 10-10 cm3 s-1, almost independent of temperature. In the reaction between Si and SO, SiO production is 5-7 times more efficient than SiS formation. The reaction of SiS with O atoms can play an important role in destroying SiS in envelopes around evolved stars. We built a simple chemical model of a postshock gas to study the chemistry of SiS in protostellar outflows and we found that SiS forms with a lower abundance and later than SiO, that SiS is efficiently destroyed through reaction with O, and that the main SiS-forming reactions are Si + SO and Si + SO2.

Entities: Chemical

Year: 2018 PMID： 30190625 PMCID： PMC6122588 DOI： 10.3847/1538-4357/aaccff

Source DB: PubMed Journal: Astrophys J ISSN： 0004-637X Impact factor: 5.874

7 in total

1. SiS in Orion-KL: evidence for "outflow" chemistry.

Authors: L M Ziurys
Journal: Astrophys J Date: 1988-01-01 Impact factor: 5.874

2. A comparative study of the Au + H₂, Au⁺ + H₂, and Au⁻ + H₂ systems: Potential energy surfaces and dynamics of reactive collisions.

Authors: Anaís Dorta-Urra; Alexandre Zanchet; Octavio Roncero; Alfredo Aguado
Journal: J Chem Phys Date: 2015-04-21 Impact factor: 3.488

3. Study of the C(3P) + OH(X2Pi) --> CO(X1Sigma(g)+) + H(2S) reaction: a fully global ab initio potential energy surface of the X2A' state.

Authors: Alexandre Zanchet; Beatrice Bussery-Honvault; Pascal Honvault
Journal: J Phys Chem A Date: 2006-11-02 Impact factor: 2.781

4. Study of the C(3P) + OH(X2Pi) --> CO(a3Pi) + H(2S) reaction: fully global ab initio potential energy surfaces of the 12A'' and 14A'' excited states and non adiabatic couplings.

Authors: Alexandre Zanchet; Béatrice Bussery-Honvault; Mohamed Jorfi; Pascal Honvault
Journal: Phys Chem Chem Phys Date: 2009-05-26 Impact factor: 3.676

1 in total

1. Nonadiabatic reaction dynamics to silicon monosulfide (SiS): A key molecular building block to sulfur-rich interstellar grains.

Authors: Srinivas Doddipatla; Chao He; Shane J Goettl; Ralf I Kaiser; Breno R L Galvão; Tom J Millar
Journal: Sci Adv Date: 2021-06-25 Impact factor: 14.136