7 research outputs found
An Observational Study of Molecular Dust Precursors in Circumstellar Envelopes
Tesis doctoral inĂ©dita leĂda en la Universidad AutĂłnoma de Madrid, Facultad de Ciencias, Departamento de FĂsica TeĂłrica. Fecha de lectura: 18-12-2020CSIC. Instituto de FĂsica Fundamental (IFF
Discovery of the elusive carbonic acid (HOCOOH) in space
After a quarter century since the detection of the last interstellar
carboxylic acid, acetic acid (CHCOOH), we report the discovery of a new
one, the cis-trans form of carbonic acid (HOCOOH), toward the Galactic Center
molecular cloud G+0.693-0.027. HOCOOH stands as the first interstellar molecule
containing three oxygen atoms and also the third carboxylic acid detected so
far in the interstellar medium. Albeit the limited available laboratory
measurements (up to 65 GHz), we have also identified several pairs of unblended
lines directly in the astronomical data (between 75-120 GHz), which allowed us
to slightly improve the set of spectroscopic constants. We derive a column
density for cis-trans HOCOOH of = (6.4 0.4) 10
cm, which yields an abundance with respect to molecular H of 4.7
10. Meanwhile, the extremely low dipole moment (about fifteen
times lower) of the lower-energy conformer, cis-cis HOCOOH, precludes its
detection. We obtain an upper limit to its abundance with respect to H of
1.2 10, which suggests that cis-cis HOCOOH might be
fairly abundant in interstellar space, although it is nearly undetectable by
radio astronomical observations. We derive a cis-cis/cis-trans ratio 25,
consistent with the smaller energy difference between both conformers compared
with the relative stability of trans- and cis-formic acid (HCOOH). Finally, we
compare the abundance of these acids in different astronomical environments,
further suggesting a relationship between the chemical content found in the
interstellar medium and the chemical composition of the minor bodies of the
Solar System, which could be inherited during the star formation process.Comment: Accepted for publication in The Astrophysical Journa
First glycine isomer detected in the interstellar medium: glycolamide (NHC(O)CHOH)
We report the first detection in the interstellar medium of a
CHON isomer: -glycolamide (NHC(O)CHOH). The exquisite
sensitivity at sub-mK levels of an ultra-deep spectral survey carried out with
the Yebes 40m and IRAM 30m telescopes towards the G+0.693-0.027 molecular cloud
have allowed us to unambiguously identify multiple transitions of this species.
We derived a column density of (7.4 0.7)10 cm,
which implies a molecular abundance with respect to H of
5.510. The other CHON isomers, including the
higher-energy conformer of glycolamide, and two conformers of glycine,
were not detected. The upper limit derived for the abundance of glycine
indicates that this amino acid is surely less abundant than its isomer
glycolamide in the ISM. The abundances of the CHON isomers cannot
be explained in terms of thermodynamic equilibrium, and thus chemical kinetics
need to be invoked. While the low abundance of glycine might not be surprising,
based on the relative low abundances of acids in the ISM compared to other
compounds (e.g. alcohols, aldehydes or amines), several chemical pathways can
favour the formation of its isomer glycolamide. It can be formed through
radical-radical reactions on the surface of dust grains. The abundances of
these radicals can be significantly boosted in an environment affected by a
strong ultraviolet field induced by cosmic rays, such as that expected in
G+0.693-0.027. Therefore, as shown by several recent molecular detections
towards this molecular cloud, it stands out as the best target to discover new
species with carbon, oxygen and nitrogen with increasing chemical complexity.Comment: Accepted in The Astrophysical Journal Letter
Precursors of the RNA-world in space: Detection of ()-1,2-ethenediol in the interstellar medium, a key intermediate in sugar formation
We present the first detection of ()-1,2-ethenediol, (CHOH), the enol
form of glycolaldehyde, in the interstellar medium towards the G+0.693-0.027
molecular cloud located in the Galactic Center. We have derived a column
density of (1.80.1)10 cm, which translates into a
molecular abundance with respect to molecular hydrogen of
1.310. The abundance ratio between glycolaldehyde and
()-1,2-ethenediol is 5.2. We discuss several viable formation routes
through chemical reactions from precursors such as HCO, HCO, CHOH or
CHCHOH. We also propose that this species might be an important precursor
in the formation of glyceraldehyde (HOCHCHOHCHO) in the interstellar medium
through combination with the hydroxymethylene (CHOH) radical.Comment: Accepted for publication in The Astrophysical Journal Letter
First Glycine Isomer Detected in the Interstellar Medium: Glycolamide (NH2C(O)CH2OH)
We report the first detection in the interstellar medium (ISM) of a C _2 H _5 O _2 N isomer: syn -glycolamide (NH _2 C(O)CH _2 OH). The exquisite sensitivity at sub-mK levels of an ultradeep spectral survey carried out with the Yebes 40 m and IRAM 30 m telescopes toward the G+0.693â0.027 molecular cloud has allowed us to unambiguously identify multiple transitions of this species. We derived a column density of (7.4 ± 0.7) Ă 10 ^12 cm ^â2 , which implies a molecular abundance with respect to H _2 of 5.5 Ă 10 ^â11 . The other C _2 H _5 O _2 N isomers, including the higher-energy anti conformer of glycolamide and two conformers of glycine, were not detected. The upper limit derived for the abundance of glycine indicates that this amino acid is surely less abundant than its isomer glycolamide in the ISM. The abundances of the C _2 H _5 O _2 N isomers cannot be explained in terms of thermodynamic equilibrium; thus, chemical kinetics need to be invoked. While the low abundance of glycine might not be surprising, based on the relative low abundances of acids in the ISM compared to other compounds (e.g., alcohols, aldehydes, or amines), several chemical pathways can favor the formation of its isomer glycolamide. It can be formed through radicalâradical reactions on the surface of dust grains. The abundances of these radicals can be significantly boosted in an environment affected by a strong ultraviolet field induced by cosmic rays, such as that expected in G+0.693â0.027. Therefore, as shown by several recent molecular detections toward this molecular cloud, it stands out as the best target to discover new species with carbon, oxygen, and nitrogen with increasing chemical complexity