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Article Abstract
SiO is a widespread molecule found in interstellar space, and its dissociation requires a substantial input of energy due to its high bond energy of 8.34 eV. The present study initially demonstrated across a broad range of ultraviolet (UV) wavelengths (243-288 nm) the one-photon and two-photon dissociation of SiO molecules, which were generated from the laser ablation of a Si rod colliding with an oxygen molecular beam. The images of Si products obtained through time-sliced ion velocity mapping have revealed the existence of distinct dissociation channels, encompassing Si(P) + O(P), Si(D) + O(P), Si(D) + O(D) and Si(S) + O(D) from the photodissociation of vibrationally excited SiO(XΣ, ) and low-lying electronically excited SiO(CΣ, DΔ, aΣ, bΠ, dΔ and eΣ) states. These findings contribute to a more comprehensive understanding of silicon chemistry during the combustion of silica-rich meteorites in the Earth's atmosphere, and have wider implications in the fields of atmospheric chemistry, astrochemistry, and combustion science.
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