P. D. Godfrey scite author profile

We report the astronomical detections of several ammonia inversion transitions involving nonmetastable levels with energies as high s 1090 K above the ground state. The (J, K) = (9, 6) inversion transition shows maser-like emission in the directions of W51, NGC 7538, W49, and DR 21(OH). The NH3 (6, 3) line exhibits similar characteristics in W51 but is seen in absorption in NGC 7538. These are the first definite detections of ammonia masers in space. The intensities and narrow line widths (0.5-1.5 km s-1) for the emission features are in contrast to the previously detected broad, weak, nonmetastable lines attributed to thermal emission in these sources. Temporal variability appears to be evident in the (9, 6) emission in W49 over a 4 month period. The highly excited (J, K) = (9, 6) and (6, 3) ammonia lines are found in regions containing compact H II regions and strong infrared sources with associated H2O and OH masers; i.e., in regions of active star formation.

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A new interstellar polyatomic molecule - Detection of propynal in the cold cloud TMC-1

Irvine¹,

Brown²,

Cragg³

et al. 1988

ApJ

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Spectroscopic evidence for interstellar ices in comet Hyakutake

Irvine

Bockelée‐Morvan

Lis

et al. 1996

Nature

120

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Volatile compounds in comets are the most pristine materials surviving from the time of formation of the Solar System, and thus potentially provide information about conditions that prevailed in the primitive solar nebula. Moreover, comets may have supplied a substantial fraction of the volatiles on the terrestrial planets, perhaps including organic compounds that played a role in the origin of life on Earth. Here we report the detection of hydrogen isocyanide (HNC) in comet Hyakutake. The abundance of HNC relative to hydrogen cyanide (HCN) is very similar to that observed in quiescent interstellar molecular clouds, and quite different from the equilibrium ratio expected in the outermost solar nebula, where comets are thought to form. Such a departure from equilibrium has long been considered a hallmark of gas-phase chemical processing in the interstellar medium, suggesting that interstellar gases have been incorporated into the comet's nucleus, perhaps as ices frozen onto interstellar grains. If this interpretation is correct, our results should provide constraints on the temperature of the solar nebula, and the subsequent chemical processes that occurred in the region where comets formed.

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Microwave Emission of the 211?212 Rotational Transition in Interstellar Acetaldehyde

Fourikis¹,

Sinclair²,

Robinson³

et al. 1974

Aust. J. Phys.

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P. D. Godfrey

New interstellar masers in nonmetastable ammonia

A new interstellar polyatomic molecule - Detection of propynal in the cold cloud TMC-1

Spectroscopic evidence for interstellar ices in comet Hyakutake

Microwave Emission of the 211?212 Rotational Transition in Interstellar Acetaldehyde

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