High-resolution Infrared Observations

HighlightsFeaturesDescription
Discovery of molecular species in IRC+10216Diacetylene (C4H2)Major emission arises at 50 AU or less from the star in the dust formation zone. Constraints on chemical models
Distribution of molecular emission in IRC+10216Ethylene (C2H4)Part of the emission arises in the inner dust formation zone contrary to previous findings. Constraints on chemical models
Detection of molecular emission in R LeoCO2 Infrared fluorescence More systematic study of the CO2 emission in O-rich stars to understand how CO2 forms
Major NANOCOSMOS highlights in “High spectral resolution IR observations” (see dedicated descriptions below)

High spectral resolution infrared observations of circumstellar envelopes – CSEs – in AGB stars are essential to study important molecular species with no permanent dipole moment (e.g. H2, O2, CO2, SiH4, C2H4). This lack makes them undetectable in the millimeter range due to the absence of rotational transitions. Hence, the best possible observation of these molecules is through its vibration–rotation lines in the mid infrared range.

These observations are vital to study the amount of ejected matter in the pulsation phase and determine the chemical interactions between the ejected molecules in the CSEs. These studies help improve the underlying assumptions of currently available chemical models.

Therefore, we observed the carbon-rich star IRC+10216 with the Texas Echelon-cross-Echelle Spectrograph (TEXES) on the 3 m Infrared Telescope Facility (IRTF). We carried out observations of the oxygen rich star R Leo with the Stratospheric Observatory for Infrared Astronomy (SOFIA) with the high spectral resolution Echelon-cross-Echelle Spectrograph (EXES). Finally, we used both SOFIA/EXES and IRTF/TEXES to observe the carbon rich semi-regular star Y CVn.

Our IR observations have led to the discovery of diacetylene (C4H2) in the envelope of IRC+10216 with the major emission arising in the dust formation zone at less than 50 AU from the center of the star. Ethylene (C2H4) shows emission from the inner dust formation zone in IRC+10216 contrary to previous findings. These studies pose further constraints on current chemical models.

Summary of oustanding results with the NANOCOSMOS high-resolution infrared observations of CSEs in AGB stars

Multi-frequency high spectral resolution observations of HCN toward the circumstellar envelope of Y CVn (J. P. Fonfría et al., A&A, 07/2021)

  • Analysis and Identification of 130 lines of HCN and H13CN with either P-Cygni profiles or pure absorption profiles
  • Dust grains could be mostly made of silicon carbide SiC in the inner layers of the CSE (~ 3.5 stellar radii) and of amorphous carbon in the outer envelope (up to 200 stellar radii)
  • The observed mid-IR lines are broader than expected due to possible high velocity matter ejections or photospheric movements related to stellar pulsation or convection.
  • HCN rotational and vibrational temperatures are out of local thermodynamics equilibrium so collisions do not play any role in the gas thermalization


Detection of infrared fluorescence of carbon dioxide in R Leonis with SOFIA/EXES (J. P. Fonfría et al., A&A, 11/2020)

  • CO2 (≃240 emission lines in the range 12.8−14.3 μm) New detection in R Leo
  • The observed CO2 lines can be grouped into three different populations, (warm, hot, and very hot), with approximate temperatures of 550, 1150, and 1600 K
  • The CO2 emitting regions at 1600, 1150, and 550 K are located at 2.2, 3.5, and 10 stellar radii from the center of R Leo
  • We need a systematic study of the CO2 emission in O-rich stars to understand how this molecule forms and the possible dependence of the column density on the mass-loss rate


Carbon Chemistry in IRC+10216: Infrared Detection of Diacetylene (J. P. Fonfría et al., ApJ, 01/2018)

  • C4H2 (24 absorption features in the range 8.0 to 8.1 μm) First detection in IRC+10216
  • The major emission of C4H2 arises in the dust formation zone at radii lower than 20 stellar radii (50 Astronomical Units) from the center of IRC+10216
  • Our photochemical models underestimate the observed C4H2 abundance. This finding could imply that the molecules in the envelope are photodissociated in shells closer to the star than is commonly assumed
  • More info on diacetylene: Astromolecule of the Month


The Abundance of C2H4 in the Circumstellar Envelope of IRC+10216 (J. P. Fonfría et al., ApJ, 01/2017)

  • C2H4 (80 ro-vibrational features in absorption) Part of the emission arises in the inner dust formation zone contrary to previous findings
  • Part of the emission of ethylene arises in the dust formation zone at radii between 14 and 28 stellar radii from the center of IRC+10216, with no evidence of C2H4 closer to the star. Previous findings supposed all C2H4 arises in the far outer envelopes.
  • Our photochemical models underestimate the observed C2H4 terminal abundance by a factor of 4. We estimate that a fraction of the ethylene gas-phase could condense onto the dust grains around 20 stellar radii. this fact could affect the chemistry evolution of the envelope

NANOCOSMOS astronomers will map Orion with SOFIA

A legacy program to map the far-IR fine structure line of C+ at 158 microns with the Stratospheric Observatory for Infrared Astronomy (SOFIA) has been recently awarded to a small international team led by Prof. Tielens (Leiden Observatory, The Netherlands) and including 3 members of the NANOCOSMOS project, Dr. J. R. Goicoechea (ICMM-CSIC), Dr. O. Berné (IRAP, CNRS) and Prof. J. Cernicharo (ICMM-CSIC). The observing time to map the Orion molecular cloud will be more than 50 hours, which means several flights on board SOFIA!!

[CII] 158μm emission image taken by Herschel with the locations of famous regions in the cloud identified (Goicoechea et al. 2015)
[CII] 158μm emission image taken by Herschel with the locations of famous regions in the cloud identified (Goicoechea et al. 2015). SOFIA will map an area 20 times larger than the region covered by Herschel.

The ionized carbon emission dominates the gas cooling of the low density interstellar medium and it is the brightest emission line in the IR spectrum of galaxies. In the next 2 years, astronomers will use the instrument upGREAT flying on board SOFIA to map an area of more than 20 times the central region of Orion recently observed with the Herschel Space Telescope (Goicoechea et al. 2015, ApJ, 812, 75, see the publications section). This project will allow to uniquely determine the use of the C+ line as a star formation rate indicator, derive the amount of molecular cloud mass not measured by CO (so-called “CO-dark” gas), and semi-empirically determine the photo-electric heating efficiency on Polycyclic Aromatic Hydrocarbons (PAHs) and interstellar dust grains.

The Stratospheric Observatory For Infrared Astronomy (SOFIA) is a joint project between NASA and the German Aerospace Center (DLR) consisting of a custom-modified Boeing 747SP aircraft with an effective aperture of 2.5 m mounted in an open cavity towards the tail of the aircraft.

SOFIA air-to-air over the Sierra Nevada Mountains (Credit: NASA, USRA (Universities Space Research Association), and L-3 Communications Integrated Systems/Jim Ross)
SOFIA air-to-air over the Sierra Nevada Mountains (Credit: NASA, USRA (Universities Space Research Association), and L-3 Communications Integrated Systems/Jim Ross)