Laboratory and astronomical discovery of cyanothioketene, NCCHCS, in the cold starless core TMC-1

TL;DR

This study reports the first laboratory and astronomical detection of cyanothioketene (NCCHCS) in the cold starless core TMC-1, characterizing its spectrum and exploring its chemical formation pathways.

Contribution

The paper provides the first laboratory spectral data and astronomical detection of NCCHCS, revealing its abundance and chemical relations in TMC-1.

Findings

Detected 23 lines of NCCHCS in TMC-1 with a column density of 1.2e11 cm^-2.

Found that NCCHCS is more abundant than its oxygen analogs in TMC-1.

Chemical modeling suggests neutral-neutral reactions as formation pathways.

Abstract

We present the detection of cyanothioketene, NCCHCS, in the laboratory and toward TMC-1. This transient species was produced through a discharge of a gas mixture of CH2CHCN and CS2 using argon as carrier gas, and its rotational spectrum between 9 and 40 GHz was characterized using a Balle-Flygare narrowband-type Fourier-transform microwave spectrometer. A total of 21 rotational transitions were detected in the laboratory, all of them exhibiting hyperfine structure induced by the spin of the N nucleus. The spectrum for NCCHCS was predicted in the domain of our line surveys using the derived rotational and distortion constants. The detection in the cold starless core TMC-1 was based on the QUIJOTE line survey performed with the Yebes 40m radio telescope. Twenty-three lines were detected with K_a=0, 1, and 2 and J_u=9 up to 14. The derived column density is (1.2+/-0.1)e11 cm-2 for a rotational temperature of 8.5+/-1 K. The abundance ratio of thioketene and its cyano derivative, H2CCS/NCCHCS, is 6.5+/-1.3. Although ketene is more abundant than thioketene by about 15 times, its cyano derivative NCCHCO surprisingly is not detected with a 3sigma upper level to the column density of 3.0e10 cm-2, which results in an abundance ratio H2CCO/NCCHCO > 430. Hence, the chemistry of CN derivatives seems to be more favored for S-bearing than for O-bearing molecules. We carried out chemical modeling calculations and found that the gas-phase neutral-neutral reactions CCN + H2CS and CN + H2CCS could be a source of NCCHCS in TMC-1.