Ivan R. Medvedev scite author profile

Context. Urea, NH 2 C(O)NH 2 , is a molecule of great importance in organic chemistry and biology. Two searches for urea in the interstellar medium have been reported in the past, but neither were conclusive. Aims. We want to take advantage of the increased sensitivity and angular resolution provided by the Atacama Large Millimeter/submillimeter Array (ALMA) to search for urea toward the hot molecular cores embedded in the high-mass-star-forming region Sgr B2(N). Methods. We used the new spectral line survey named ReMoCA (Re-exploring Molecular Complexity with ALMA) that was performed toward Sgr B2(N) with ALMA in its observing cycle 4 between 84 GHz and 114 GHz. The spectra were analyzed under the local thermodynamic equilibrium approximation. We constructed a full synthetic spectrum that includes all the molecules identified so far. We used new spectroscopic predictions for urea in its vibrational ground state and first vibrationally excited state to search for this complex organic molecule in the ReMoCA data set. We employed the gas-grain chemical kinetics model MAGICKAL to interpret the astronomical observations. Results. We report the secure detection of urea toward the hot core Sgr B2(N1) at a position called N1S slightly offset from the continuum peak, which avoids obscuration by the dust. The identification of urea relies on nine clearly detected transitions. We derive a column density of 2.7 × 10 16 cm −2 for urea, two orders of magnitude lower than the column density of formamide, and one order of magnitude below that of methyl isocyanate, acetamide, and N-methylformamide. The latter molecule is reliably identified toward N1S with 60 clearly detected lines, confirming an earlier claim of its tentative interstellar detection. We report the first interstellar detections of NH 2 CH 18 O and 15 NH 2 CHO. We also report the nondetection of urea toward the secondary hot core Sgr B2(N2) with an abundance relative to the other four species at least one order of magnitude lower than toward the main hot core. Our chemical model roughly reproduces the relative abundances of formamide, methyl isocyanate, acetamide, and N-methylformamide, but it overproduces urea by at least one order of magnitude. Conclusions. Urea is clearly detected in one of the hot cores. Comparing the full chemical composition of Sgr B2(N1S) and Sgr B2(N2) may help understand why urea is at least one order of magnitude less abundant in the latter source.

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Rotational spectrum of trans–trans diethyl ether in the ground and three excited vibrational states

Kisiel

Pszczółkowski

Medvedev

et al. 2005

Journal of Molecular Spectroscopy

266

209

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A rigorous detection of interstellar CH₃NCO: An important missing species in astrochemical networks

Cernicharo

Kisiel

Tercero

et al. 2016

A&A

101

200

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The recent analysis of the composition of the frozen surface of comet 67P/Churyumov-Gerasimenko has revealed a significant number of complex organic molecules. Methyl isocyanate (CH 3 NCO) is one of the more abundant species detected on the comet surface. In this work we report extensive characterization of its rotational spectrum resulting in a list of 1269 confidently assigned laboratory lines and its detection in space towards the Orion clouds where 399 lines of the molecule have been unambiguously identified. We find that the limited mm-wave laboratory data reported prior to our work require some revision. The abundance of CH 3 NCO in Orion is only a factor of ten below those of HNCO and CH 3 CN. Unlike the molecular abundances in the coma of comets, which correlate with those of warm molecular clouds, molecular abundances in the gas phase in Orion are only weakly correlated with those measured on the comet surface. We also compare our abundances with those derived recently for this molecule towards Sgr B2 (Halfen et al. 2015, ApJ, 812, L5). A more accurate abundance of CH 3 NCO is provided for this cloud based on our extensive laboratory work.

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Determination of precise relative energies of conformers of n-propanol by rotational spectroscopy

Kisiel

Dorosh

Maeda

et al. 2010

Phys. Chem. Chem. Phys.

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The rotational spectrum of n-propanol (n-CH(3)CH(2)CH(2)OH) was studied with several techniques of contemporary broadband rotational spectroscopy at frequencies from 8 to 550 GHz. Rotational transitions in all five conformers of the molecule, Gt, Gg, Gg', Tt, and Tg, have been unambiguously assigned. Over 6700 lines of the Gt, Gg, and Gg' species, for quantum number values reaching K(a) = 33 and J = 67, were fitted in a joint analysis leading to the determination of DeltaE(Gg-Gt) = 47.82425(25) cm(-1) and DeltaE (Gg'-Gg) = 3.035047(11) cm(-1). Stark effect measurements in supersonic expansion were used to further confirm the assignment. The results are compared with those for the ethanol molecule and with ab initio calculations, allowing several inferences to be drawn concerning the differences in the large amplitude torsional potential of the hydroxyl group in the two molecules.

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Ivan R. Medvedev

Re-exploring Molecular Complexity with ALMA (ReMoCA): interstellar detection of urea

Rotational spectrum of trans–trans diethyl ether in the ground and three excited vibrational states

A rigorous detection of interstellar CH₃NCO: An important missing species in astrochemical networks

Determination of precise relative energies of conformers of n-propanol by rotational spectroscopy

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About

Ivan R. Medvedev

Re-exploring Molecular Complexity with ALMA (ReMoCA): interstellar detection of urea

Rotational spectrum of trans–trans diethyl ether in the ground and three excited vibrational states

A rigorous detection of interstellar CH3NCO: An important missing species in astrochemical networks

Determination of precise relative energies of conformers of n-propanol by rotational spectroscopy

Contact Info

Product

Resources

About

A rigorous detection of interstellar CH₃NCO: An important missing species in astrochemical networks