Your search keyword '"ISOKOSKI, KAROLIINA"' showing total 10 results

1. Chemistry of massive young stellar objects with a disk-like structure

Author

Isokoski, Karoliina, Bottinelli, Sandrine, and van Dishoeck, Ewine

Subjects

Astrophysics - Astrophysics of Galaxies

Abstract

Our goal is to take an inventory of complex molecules in three well-known high-mass protostars for which disks or toroids have been claimed and to study the similarities and differences with a sample of massive YSOs without evidence of such flattened disk-like structures. With a disk-like geometry, UV radiation can escape more readily and potentially affect the ice and gas chemistry on hot-core scales. A partial submillimeter line survey, targeting CH3OH, H2CO, C2H5OH, HCOOCH3, CH3OCH3, CH3CN, HNCO, NH2CHO, C2H5CN, CH2CO, HCOOH, CH3CHO, and CH3CCH, was made toward three massive YSOs with disk-like structures, IRAS20126+4104, IRAS18089-1732, and G31.41+0.31. Rotation temperatures and column densities were determined by the rotation diagram method, as well as by independent spectral modeling. The molecular abundances were compared with previous observations of massive YSOs without evidence of any disk structure, targeting the same molecules with the same settings and using the same analysis method. Consistent with previous studies, different complex organic species have different characteristic rotation temperatures and can be classified either as warm (>100 K) or cold (<100 K). The excitation temperatures and abundance ratios are similar from source to source and no significant difference can be established between the two source types. Acetone, CH3COCH3, is detected for the first time in G31.41+0.31 and IRAS18089-1732. Temperatures and abundances derived from the two analysis methods generally agree within factors of a few. The lack of chemical differentiation between massive YSOs with and without observed disks suggest either that the chemical complexity is already fully established in the ices in the cold prestellar phase or that the material experiences similar physi- cal conditions and UV exposure through outflow cavities during the short embedded lifetime.

Published

2013

2. Anomalous CO2 Ice Toward HOPS-68: A Tracer of Protostellar Feedback

Author

Poteet, Charles A., Pontoppidan, Klaus M., Megeath, S. Thomas, Watson, Dan M., Isokoski, Karoliina, Bjorkman, Jon E., Sheehan, Patrick D., and Linnartz, Harold

Subjects

Astrophysics - Solar and Stellar Astrophysics, Astrophysics - Astrophysics of Galaxies

Abstract

We report the detection of a unique CO2 ice band toward the deeply embedded, low-mass protostar HOPS-68. Our spectrum, obtained with the Infrared Spectrograph onboard the Spitzer Space Telescope, reveals a 15.2 micron CO2 ice bending mode profile that cannot modeled with the same ice structure typically found toward other protostars. We develop a modified CO2 ice profile decomposition, including the addition of new high-quality laboratory spectra of pure, crystalline CO2 ice. Using this model, we find that 87-92% of the CO2 is sequestered as spherical, CO2-rich mantles, while typical interstellar ices show evidence of irregularly-shaped, hydrogen-rich mantles. We propose that (1) the nearly complete absence of unprocessed ices along the line-of-sight is due to the flattened envelope structure of HOPS-68, which lacks cold absorbing material in its outer envelope, and possesses an extreme concentration of material within its inner (10 AU) envelope region and (2) an energetic event led to the evaporation of inner envelope ices, followed by cooling and re-condensation, explaining the sequestration of spherical, CO2 ice mantles in a hydrogen-poor mixture. The mechanism responsible for the sublimation could be either a transient accretion event or shocks in the interaction region between the protostellar outflow and envelope. The proposed scenario is consistent with the rarity of the observed CO2 ice profile, the formation of nearly pure CO2 ice, and the production of spherical ice mantles. HOPS-68 may therefore provide a unique window into the protostellar feedback process, as outflows and heating shape the physical and chemical structure of protostellar envelopes and molecular clouds., Comment: Accepted to the Astrophysical Journal, 2013 February 15: 14 pages, 9 figures, 3 tables

Published

2013

3. Vibration–rotation Fourier transform infrared spectrum of the C–D and C [tbnd]C stretching fundamental, ν1 and ν2, band systems of deuterated monobromoacetylene

Author

Vaittinen, Olavi, Martinez, R.Z., Suero, Piritta, Isokoski, Karoliina, and Halonen, Lauri

Published

2006

4. HXeOBr in a xenon matrix.

Author

Khriachtchev, Leonid, Tapio, Salla, Domanskaya, Alexandra V., Räsänen, Markku, Isokoski, Karoliina, and Lundell, Jan

Subjects

XENON, NOBLE gases, MOLECULES, THERMAL properties of gases, LOW temperatures, PHOTOCHEMISTRY, NITROUS oxide

Abstract

We report on a new noble-gas molecule HXeOBr prepared in a low-temperature xenon matrix from the HBr and N2O precursors by UV photolysis and thermal annealing. This molecule is assigned with the help of deuteration experiments and ab initio calculations including anharmonic methods. The H-Xe stretching frequency of HXeOBr is observed at 1634 cm-1, which is larger by 56 cm-1 than the frequency of HXeOH identified previously. The experiments show a higher thermal stability of HXeOBr molecules in a xenon matrix compared to HXeOH. [ABSTRACT FROM AUTHOR]

Published

2011

5. A small neutral molecule with two noble-gas atoms: HXeOXeH

Author

Khriachtchev, Leonid, Isokoski, Karoliina, Cohen, Arik, Rasanen, Markku, and Gerber, R. Benny

Subjects

Infrared spectroscopy -- Usage, Oxygen -- Chemical properties, Xenon -- Chemical properties, Chemistry

Abstract

Infrared (IR) spectroscopy is used for identifying a novel noble-gas compound, HXeOXeH, which seems to be the smallest known neutral molecule with two noble-gas atoms. HXeOXeH has represented a first step toward the preparation of [(Xe-O).sub.] chains and it might be relevant to the terrestrial missing xenon problem.

Published

2008

6. ANOMALOUS CO2ICE TOWARD HOPS-68: A TRACER OF PROTOSTELLAR FEEDBACK

Author

Poteet, Charles A., primary, Pontoppidan, Klaus M., additional, Megeath, S. Thomas, additional, Watson, Dan M., additional, Isokoski, Karoliina, additional, Bjorkman, Jon E., additional, Sheehan, Patrick D., additional, and Linnartz, Harold, additional

Published

2013

7. Solid State Pathways towards Molecular Complexity in Space

Author

Linnartz, Harold, primary, Bossa, Jean-Baptiste, additional, Bouwman, Jordy, additional, Cuppen, Herma M., additional, Cuylle, Steven H., additional, van Dishoeck, Ewine F., additional, Fayolle, Edith C., additional, Fedoseev, Gleb, additional, Fuchs, Guido W., additional, Ioppolo, Sergio, additional, Isokoski, Karoliina, additional, Lamberts, Thanja, additional, Öberg, Karin I., additional, Romanzin, Claire, additional, Tenenbaum, Emily, additional, and Zhen, Junfeng, additional

Published

2011

8. ChemInform Abstract: A Small Neutral Molecule with Two Noble‐Gas Atoms: HXeOXeH.

Author

Khriachtchev, Leonid, primary, Isokoski, Karoliina, additional, Cohen, Arik, additional, Raesaenen, Markku, additional, and Gerber, R. Benny, additional

Published

2008

9. ANOMALOUS CO2 ICE TOWARD HOPS-68: A TRACER OF PROTOSTELLAR FEEDBACK.

Author

POTEET, CHARLES A., PONTOPPIDAN, KLAUS M., THOMAS MEGEATH, S., WATSON, DAN M., ISOKOSKI, KAROLIINA, BJORKMAN, JON E., SHEEHAN, PATRICK D., and LINNARTZ, HAROLD

Subjects

DRY ice, PROTOSTARS, INFRARED spectroscopy, CRYSTAL structure, MOLECULAR clouds

Abstract

We report the detection of a unique CO2 ice band toward the deeply embedded, low-mass protostar HOPS-68. Our spectrum, obtained with the Infrared Spectrograph on board the Spitzer Space Telescope, reveals a 15.2μmCO2 ice bending mode profile that cannot be modeled with the same ice structure typically found toward other protostars.We develop a modified CO2 ice profile decomposition, including the addition of new high-quality laboratory spectra of pure, crystalline CO2 ice. Using this model, we find that 87%-92% of the CO2 is sequestered as spherical, CO2-rich mantles, while typical interstellar ices show evidence of irregularly shaped, hydrogen-rich mantles.We propose that (1) the nearly complete absence of unprocessed ices along the line of sight is due to the flattened envelope structure of HOPS-68, which lacks cold absorbing material in its outer envelope, and possesses an extreme concentration of material within its inner (10 AU) envelope region and (2) an energetic event led to the evaporation of inner envelope ices, followed by cooling and re-condensation, explaining the sequestration of spherical, CO2 ice mantles in a hydrogen-poor mixture. The mechanism responsible for the sublimation could be either a transient accretion event or shocks in the interaction region between the protostellar outflow and envelope. The proposed scenario is consistent with the rarity of the observed CO2 ice profile, the formation of nearly pure CO2 ice, and the production of spherical ice mantles. HOPS-68 may therefore provide a unique window into the protostellar feedback process, as outflows and heating shape the physical and chemical structure of protostellar envelopes and molecular clouds. [ABSTRACT FROM AUTHOR]

Published

2013

10. Vibration–rotation Fourier transform infrared spectrum of the C–D and Cing fundamental, ν 1 and ν 2, band systems of deuterated monobromoacetylene

Author

Vaittinen, Olavi, Martinez, R.Z., Suero, Piritta, Isokoski, Karoliina, and Halonen, Lauri

Subjects

*VIBRATIONAL spectra, *MOLECULAR rotation, *FOURIER transform spectroscopy, *SPECTRUM analysis

Abstract

Abstract: A high resolution vibration–rotation spectrum of deuterated monobromoacetylene (DCCBr) has been recorded with a Bruker IFS 120 Fourier Spectrometer in the wavenumber region 1700–2800cm−1, which covers the C–D and Cing fundamental (ν 1 and ν 2, respectively) and the Cx2013;Br stretching vibrational combination (ν 2 + ν 3) band systems. The analysis of the spectrum provides accurate vibrational term values and rotational constant for 20 vibration–rotation bands for both isotopic species, DCC79Br and DCC81Br. [Copyright &y& Elsevier]

Published

2006