Infrared Spectral Signatures of Nucleobases in Interstellar Ices I: Purines

Overview

Journal Life (Basel)

Specialty Biology

Date 2023 Nov 25

PMID 38004348

Authors

Caroline Antunes Rosa

Alexandre Bergantini

Peter Herczku

Duncan V Mifsud

Gergo Lakatos

Sandor T S Kovacs

Bela Sulik

Zoltan Juhasz

Sergio Ioppolo

Heidy M Quitian-Lara

Nigel J Mason

Claudia Lage

Affiliations

Soon will be listed here.

Abstract

The purine nucleobases adenine and guanine are complex organic molecules that are essential for life. Despite their ubiquitous presence on Earth, purines have yet to be detected in observations of astronomical environments. This work therefore proposes to study the infrared spectra of purines linked to terrestrial biochemical processes under conditions analogous to those found in the interstellar medium. The infrared spectra of adenine and guanine, both in neat form and embedded within an ice made of HO:NH:CH:CO:CHOH (10:1:1:1:1), were analysed with the aim of determining which bands attributable to adenine and/or guanine can be observed in the infrared spectrum of an astrophysical ice analogue rich in other volatile species known to be abundant in dense molecular clouds. The spectrum of adenine and guanine mixed together was also analysed. This study has identified three purine nucleobase infrared absorption bands that do not overlap with bands attributable to the volatiles that are ubiquitous in the dense interstellar medium. Therefore, these three bands, which are located at 1255, 940, and 878 cm, are proposed as an infrared spectral signature for adenine, guanine, or a mixture of these molecules in astrophysical ices. All three bands have integrated molar absorptivity values () greater than 4 km mol, meaning that they should be readily observable in astronomical targets. Therefore, if these three bands were to be observed together in the same target, then it is possible to propose the presence of a purine molecule (i.e., adenine or guanine) there.

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