Your search keyword '"Tychoniec, L."' showing total 19 results

1. JOYS : MIRI/MRS spectroscopy of gas-phase molecules from the high-mass star-forming region IRAS 23385+6053

Author

Francis, L., van Gelder, M. L., van Dishoeck, E. F., Gieser, C., Beuther, H., Tychoniec, L., Perotti, G., Garatti, A. Caratti O., Kavanagh, P. J., Ray, T., Klaassen, P., Justtanont, K., Linnartz, H., Rocha, W. R. M., Slavicinska, K., Güdel, M., Henning, T., Lagage, P. -O., Östlin, Göran, Francis, L., van Gelder, M. L., van Dishoeck, E. F., Gieser, C., Beuther, H., Tychoniec, L., Perotti, G., Garatti, A. Caratti O., Kavanagh, P. J., Ray, T., Klaassen, P., Justtanont, K., Linnartz, H., Rocha, W. R. M., Slavicinska, K., Güdel, M., Henning, T., Lagage, P. -O., and Östlin, Göran

Abstract

Context. Space-based mid-infrared (IR) spectroscopy is a powerful tool for the characterization of important star formation tracers of warm gas which are unobservable from the ground. The previous mid-IR spectra of bright high-mass protostars with the Infrared Space Observatory (ISO) in the hot-core phase typically show strong absorption features from molecules such as CO2, C2H2, and HCN. However, little is known about their fainter counterparts at earlier stages. Aims. We aim to characterize the gas-phase molecular features in James Webb Space Telescope Mid-Infrared Instrument Medium Resolution Spectrometer (MIRI/MRS) spectra of the young and clustered high-mass star-forming region IRAS 23385+6053. Methods. Spectra were extracted from several locations in the MIRI/MRS field of view, targeting two mid-IR sources tracing embedded massive protostars as well as three H2 bright outflow knots at distances of >8000 au from the multiple. Molecular features in the spectra were fit with local thermodynamic equilibrium (LTE) slab models, with their caveats discussed in detail. Results. Rich molecular spectra with emission from CO, H2, HD, H2O, C2H2, HCN, CO2, and OH are detected towards the two mid-IR sources. However, only CO and OH are seen towards the brightest H2 knot positions, suggesting that the majority of the observed species are associated with disks or hot core regions rather than outflows or shocks. The LTE model fits to 12CO2, C2H2, HCN emission suggest warm 120–200 K emission arising from a disk surface around one or both protostars. The abundances of CO2 and C2H2 of ~10−7 are consistent with previous observations of high-mass protostars. Weak ~500 K H2O emission at ~6–7 µm is detected towards one mid-IR source, whereas 250–1050 K H2O absorption is found in the other. The H2O absorption may occur in the disk atmosphere due to strong accretion-heating of the midplane, or in a disk wind viewed at an ideal angle for absorption. CO emission may originate in the h

Published

2024

2. JOYS: MIRI/MRS spectroscopy of gas-phase molecules from the high-mass star-forming region IRAS 23385+6053

Author

Francis, L., van Gelder, M. L., van Dishoeck, E. F., Gieser, C., Beuther, H., Tychoniec, L., Perotti, G., Garatti, A. Caratti o, Kavanagh, P. J., Ray, T., Klaassen, P., Justtanont, K., Linnartz, H., Rocha, W. R. M., Slavicinska, K., Güdel, M., Henning, T., Lagage, P. O., Östlin, G., Francis, L., van Gelder, M. L., van Dishoeck, E. F., Gieser, C., Beuther, H., Tychoniec, L., Perotti, G., Garatti, A. Caratti o, Kavanagh, P. J., Ray, T., Klaassen, P., Justtanont, K., Linnartz, H., Rocha, W. R. M., Slavicinska, K., Güdel, M., Henning, T., Lagage, P. O., and Östlin, G.

Abstract

Space-based mid-IR spectroscopy provides tracers of warm gas in star-forming regions that are inaccessible from the ground. Past mid-IR spectra of bright high-mass protostars in the hot-core phase typically showed strong absorption features from molecules such as CO$_2$, C$_2$H$_2$, and HCN. However, little is known about their fainter counterparts at earlier stages. We thus aim to characterize the gas-phase molecular features in JWST MIRI/MRS observations of the young high-mass star-forming region IRAS 23385+6053. Spectra were extracted from two mid-IR sources and three H$_2$ bright outflow knots in the MIRI/MRS field of view. Rich molecular spectra with emission from CO, H$_2$, HD, H$_2$O, C$_2$H$_2$, HCN, CO$_2$, and OH are detected towards the two mid-IR sources. However, only CO and OH are seen towards the brightest H$_2$ knots, suggesting that the majority of the observed species are associated with disks or hot core regions rather than outflows. Simple Local thermodynamic equilibrium (LTE) slab models were used to fit the observed molecular features. The LTE model fits to $^{12}$CO$_{2}$, C$_{2}$H$_{2}$, and HCN emission suggest warm $120-200$ K emission arising from a disk surface around one or both protostars. Weak $\sim500$ K H$_2$O emission at $\sim$ 6-7 $\mu$m is detected towards one mid-IR source, whereas $250-1050$ K H$_2$O absorption is found in the other. The H$_2$O absorption may occur in the disk atmosphere due to strong accretion-heating of the midplane, or in a disk wind viewed at an ideal angle for absorption. CO emission may originate in the hot inner disk or outflow shocks. OH emission is likely excited in a non-LTE manner through water photodissociation or chemical formation. The observations are consistent with disks having already formed in the young IRAS 23385+6053 system, but further observations are needed to disentangle the effects of geometry and evolution., Comment: 21 Pages, 16 Figures. Accepted for publication in Astronomy and Astrophysics

Published

2024

3. JOYS : Disentangling the warm and cold material in the high-mass IRAS 23385+6053 cluster

Author

Gieser, C., Beuther, H., van Dishoeck, E. F., Francis, L., van Gelder, M. L., Tychoniec, L., Kavanagh, P. J., Perotti, G., Caratti o Garatti, A., Ray, T. P., Klaassen, P., Justtanont, K., Linnartz, H., Rocha, W. R. M., Slavicinska, K., Colina, L., Güdel, M., Henning, Th., Lagage, P. -O., Östlin, Göran, Vandenbussche, B., Waelkens, C., Wright, G., Gieser, C., Beuther, H., van Dishoeck, E. F., Francis, L., van Gelder, M. L., Tychoniec, L., Kavanagh, P. J., Perotti, G., Caratti o Garatti, A., Ray, T. P., Klaassen, P., Justtanont, K., Linnartz, H., Rocha, W. R. M., Slavicinska, K., Colina, L., Güdel, M., Henning, Th., Lagage, P. -O., Östlin, Göran, Vandenbussche, B., Waelkens, C., and Wright, G.

Abstract

Context. High-mass star formation occurs in a clustered mode where fragmentation is observed from an early stage onward. Young protostars can now be studied in great detail with the recently launched James Webb Space Telescope (JWST). Aims. We study and compare the warm (>100 K) and cold (<100 K) material toward the high-mass star-forming region (HMSFR) IRAS 23385+6053 (IRAS 23385 hereafter) combining high-angular-resolution observations in the mid-infrared (MIR) with the JWST Observations of Young protoStars (JOYS) project and with the NOrthern Extended Millimeter Array (NOEMA) at millimeter (mm) wavelengths at angular resolutions of ≈0.″2–1.″0. Methods. We investigated the spatial morphology of atomic and molecular species using line-integrated intensity maps. We estimated the temperature and column density of different gas components using H2 transitions (warm and hot component) and a series of CH3CN transitions as well as 3 mm continuum emission (cold component). Results. Toward the central dense core of IRAS 23385, the material consists of relatively cold gas and dust (≈50 K), while multiple outflows create heated and/or shocked H2 and show enhanced temperatures (≈400 K) along the outflow structures. An energetic outflow with enhanced emission knots of [Fe II] and [Ni II] suggests J-type shocks, while two other outflows have enhanced emission of only H2 and [S I] caused by C-type shocks. The latter two outflows are also more prominent in molecular line emission at mm wavelengths (e.g., SiO, SO, H2CO, and CH3OH). Data of even higher angular resolution are needed to unambiguously identify the outflow-driving sources given the clustered nature of IRAS 23385. While most of the forbidden fine structure transitions are blueshifted, [Ne II] and [Ne III] peak at the source velocity toward the MIR source A/mmA2 suggesting that the emission is originating from closer to the protostar. Conclusions. The warm and cold gas traced by MIR and mm observations, respectivel

Published

2023

4. Outflows from the youngest stars are mostly molecular

Author

Ray, T. P., Mccaughrean, M. J., o Garatti, A. Caratti, Kavanagh, P. J., Justtanont, K., van Dishoeck, E. F., Reitsma, M., Beuther, H., Francis, L., Gieser, C., Klaassen, P., Perotti, G., Tychoniec, L., van Gelder, M., Colina, L., Greve, Th. R., Guedel, M., Henning, Th., Lagage, P. O., Östlin, Göran, Vandenbussche, B., Waelkens, C., Wright, G., Ray, T. P., Mccaughrean, M. J., o Garatti, A. Caratti, Kavanagh, P. J., Justtanont, K., van Dishoeck, E. F., Reitsma, M., Beuther, H., Francis, L., Gieser, C., Klaassen, P., Perotti, G., Tychoniec, L., van Gelder, M., Colina, L., Greve, Th. R., Guedel, M., Henning, Th., Lagage, P. O., Östlin, Göran, Vandenbussche, B., Waelkens, C., and Wright, G.

Abstract

The formation of stars and planets is accompanied not only by the build-up of matter, namely accretion, but also by its expulsion in the form of highly supersonic jets that can stretch for several parsecs1,2. As accretion and jet activity are correlated and because young stars acquire most of their mass rapidly early on, the most powerful jets are associated with the youngest protostars3. This period, however, coincides with the time when the protostar and its surroundings are hidden behind many magnitudes of visual extinction. Millimetre interferometers can probe this stage but only for the coolest components3. No information is provided on the hottest (greater than 1,000 K) constituents of the jet, that is, the atomic, ionized and high-temperature molecular gases that are thought to make up the jet's backbone. Detecting such a spine relies on observing in the infrared that can penetrate through the shroud of dust. Here we report near-infrared observations of Herbig-Haro 211 from the James Webb Space Telescope, an outflow from an analogue of our Sun when it was, at most, a few times 104 years old. These observations reveal copious emission from hot molecules, explaining the origin of the 'green fuzzies'4-7 discovered nearly two decades ago by the Spitzer Space Telescope8. This outflow is found to be propagating slowly in comparison to its more evolved counterparts and, surprisingly, almost no trace of atomic or ionized emission is seen, suggesting its spine is almost purely molecular. Near-infrared imagery and spectroscopy from JWST of the Herbig-Haro 211 system, an analogue of the young Sun, reveals supersonic jets of hot molecules that can explain the origin of the 'green fuzzies' phenomenon.

Published

2023

5. JWST Observations of Young protoStars (JOYS) Outflows and accretion in the high-mass star-forming region IRAS 23385+6053

Author

Beuther, H., van Dishoeck, E. F., Tychoniec, L., Gieser, C., Kavanagh, P. J., Perotti, G., van Gelder, M. L., Klaassen, P., Garatti, A. Caratti o, Francis, L., Rocha, W. R. M., Slavicinska, K., Ray, T., Justtanont, K., Linnartz, H., Waelkens, C., Colina, L., Greve, T., Guedel, M., Henning, T., Lagage, P-O, Vandenbussche, B., Östlin, Göran, Wright, G., Beuther, H., van Dishoeck, E. F., Tychoniec, L., Gieser, C., Kavanagh, P. J., Perotti, G., van Gelder, M. L., Klaassen, P., Garatti, A. Caratti o, Francis, L., Rocha, W. R. M., Slavicinska, K., Ray, T., Justtanont, K., Linnartz, H., Waelkens, C., Colina, L., Greve, T., Guedel, M., Henning, T., Lagage, P-O, Vandenbussche, B., Östlin, Göran, and Wright, G.

Abstract

Context. Understanding the earliest stages of star formation, and setting it in the context of the general cycle of matter in the interstellar medium, is a central aspect of research with the James Webb Space Telescope (JWST). Aims. The JWST program JOYS (JWST Observations of Young protoStars) aims to characterize the physical and chemical properties of young high- and low-mass star-forming regions, in particular the unique mid-infrared diagnostics of the warmer gas and solid-state components. We present early results from the high-mass star formation region IRAS 23385+6053. Methods. The JOYS program uses the Mid-Infrared Instrument (MIRI) Medium Resolution Spectrometer (MRS) with its integral field unit (IFU) to investigate a sample of high- and low-mass star-forming protostellar systems. Results. The full 5-28 mu m MIRI MRS spectrum of IRAS 23385+6053 shows a plethora of interesting features. While the general spectrum is typical for an embedded protostar, we see many atomic and molecular gas lines boosted by the higher spectral resolution and sensitivity compared to previous space missions. Furthermore, ice and dust absorption features are also present. Here, we focus on the continuum emission, outflow tracers such as the H-2(0-0)S(7), [FeII](F-4(9/2)-D-6(9/2)), and [NeII](P-2(1/2)-P-2(3/2)) lines, and the potential accretion tracer Humphreys alpha HI(7-6). The short-wavelength MIRI data resolve two continuum sources, A and B; mid-infrared source A is associated with the main millimeter continuum peak. The combination of mid-infrared and millimeter data reveals a young cluster in the making. Combining the mid-infrared outflow tracers H-2, [FeII], and [NeII] with millimeter SiO data reveals a complex interplay of at least three molecular outflows driven by protostars in the forming cluster. Furthermore, the Humphreys alpha line is detected at a 3-4 sigma level toward the mid-infrared sources A and B. One can roughly estimate both accretion luminosities and corresp

Published

2023

6. Outflows from the Youngest Stars are Mostly Molecular

Author

Ray, T. P., McCaughrean, M. J., Caratti O Garatti, A., Kavanagh, P. J., Justtanont, K., van Dishoeck, E. F., Reitsma, M., Beuther, H., Francis, L., Gieser, C., Klaassen, P., Perotti, G., Tychoniec, L., van Gelder, M., Colina, L, Greve, Th. R., Güdel, M., Henning, Th., Lagage, P. O., Östlin, G., Vandenbussche, B., Waelkens, C., Wright, G, Ray, T. P., McCaughrean, M. J., Caratti O Garatti, A., Kavanagh, P. J., Justtanont, K., van Dishoeck, E. F., Reitsma, M., Beuther, H., Francis, L., Gieser, C., Klaassen, P., Perotti, G., Tychoniec, L., van Gelder, M., Colina, L, Greve, Th. R., Güdel, M., Henning, Th., Lagage, P. O., Östlin, G., Vandenbussche, B., Waelkens, C., and Wright, G

Abstract

The formation of stars and planets is accompanied not only by the build-up of matter, i.e., accretion, but also by its expulsion in the form of highly supersonic jets that can stretch for several parsecs1,2. As accretion and jet activity are correlated and because young stars acquire most of their mass rapidly early on, the most powerful jets are associated with the youngest protostars3. This period, however, coincides with the time when the protostar and its surroundings are hidden behind many magnitudes of visual extinction. Millimetre interferometers can probe this stage but only for the coolest components3. No information is provided on the hottest ( > 1000 K) constituents of the jet, i. e. the atomic, ionized, and high temperature molecular gas that are thought to make up the jet's backbone. Can we detect such a high temperature spine and what is it made up of? Here we report near-infrared JWST observations of Herbig-Haro 211, an outflow from an analogue of our Sun when it was at most a few times 104 years old. These reveal copious emission from hot molecules explaining the origin of the so-called "Green Fuzzies"4-7 discovered nearly two decades ago by the Spitzer Space Telescope8. This outflow is found to be propagating slowly in comparison to its more evolved counterparts and, surprisingly, almost no trace of atomic or ionized emission is seen suggesting its spine is almost purely molecular.

Published

2023

7. PENELLOPE V. The magnetospheric structure and the accretion variability of the classical T Tauri star HM Lup

Author

Armeni, A., Stelzer, B., Claes, R. A. B., Manara, C. F., Frasca, A., Alcalá, J. M., Walter, F. M., Kóspál, Á., Campbell-White, J., Gangi, M., Mauco, K., Tychoniec, L., Armeni, A., Stelzer, B., Claes, R. A. B., Manara, C. F., Frasca, A., Alcalá, J. M., Walter, F. M., Kóspál, Á., Campbell-White, J., Gangi, M., Mauco, K., and Tychoniec, L.

Abstract

HM Lup is a young M-type star that accretes material from a circumstellar disk through a magnetosphere. Our aim is to study the inner disk structure of HM Lup and to characterize its variability. We used spectroscopic data from HST/STIS, X-Shooter, and ESPRESSO taken in the framework of the ULLYSES and PENELLOPE programs, together with photometric data from TESS and AAVSO. The 2021 TESS light curve shows variability typical for young stellar objects of the "accretion burster" type. The spectra cover the temporal evolution of the main burst in the 2021 TESS light curve. We compared the strength and morphology of emission lines from different species and ionization stages. We determined the mass accretion rate from selected emission lines and from the UV continuum excess emission at different epochs, and we examined its relation to the photometric light curves. The emission lines in the optical spectrum of HM Lup delineate a temperature stratification along the accretion flow. While the wings of the H I and He I lines originate near the star, the lines of species such as Na I, Mg I, Ca I, Ca II, Fe I, and Fe II are formed in an outer and colder region. The shape and periodicity of the 2019 and 2021 TESS light curves, when qualitatively compared to predictions from magnetohydrodynamic models, suggest that HM Lup was in a regime of unstable ordered accretion during the 2021 TESS observation due to an increase in the accretion rate. Although HM Lup is not an extreme accretor, it shows enhanced emission in the metallic species during this high accretion state that is produced by a density enhancement in the outer part of the accretion flow., Comment: 15 pages, 14 figures. Accepted for publication in A&A

Published

2023

8. JOYS: Disentangling the warm and cold material in the high-mass IRAS 23385+6053 cluster

Author

Gieser, C., Beuther, H., van Dishoeck, E. F., Francis, L., van Gelder, M. L., Tychoniec, L., Kavanagh, P. J., Perotti, G., Garatti, A. Caratti o, Ray, T. P., Klaassen, P., Justtanont, K., Linnartz, H., Rocha, W. R. M., Slavicinska, K., Colina, L., Güdel, M., Henning, Th., Lagage, P. -O., Östlin, G., Vandenbussche, B., Waelkens, C., Wright, G., Gieser, C., Beuther, H., van Dishoeck, E. F., Francis, L., van Gelder, M. L., Tychoniec, L., Kavanagh, P. J., Perotti, G., Garatti, A. Caratti o, Ray, T. P., Klaassen, P., Justtanont, K., Linnartz, H., Rocha, W. R. M., Slavicinska, K., Colina, L., Güdel, M., Henning, Th., Lagage, P. -O., Östlin, G., Vandenbussche, B., Waelkens, C., and Wright, G.

Abstract

(abridged) We study and compare the warm (>100 K) and cold (<100 K) material toward the high-mass star-forming region IRAS 23385+6053 (IRAS 23385 hereafter) combining high angular resolution observations in the mid-infrared (MIR) with the JWST Observations of Young protoStars (JOYS) project and with the NOEMA at mm wavelengths at angular resolutions of 0.2"-1". The spatial morphology of atomic and molecular species is investigated by line integrated intensity maps. The temperature and column density of different gas components is estimated using H2 transitions (warm and hot component) and a series of CH3CN transitions as well as 3 mm continuum emission (cold component). Toward the central dense core in IRAS 23385 the material consists of relatively cold gas and dust (~50 K), while multiple outflows create heated and/or shocked H2 and show enhanced temperatures (~400 K) along the outflow structures. An energetic outflow with enhanced emission knots of [Fe II] and [Ni II] hints at J-type shocks, while two other outflows have enhanced emission of only H2 and [S I] caused by C-type shocks. The latter two outflows are also more prominent in molecular line emission at mm wavelengths (e.g., SiO, SO, H2CO, and CH3OH). Even higher angular resolution data are needed to unambiguously identify the outflow driving sources given the clustered nature of IRAS 23385. While most of the forbidden fine structure transitions are blueshifted, [Ne II] and [Ne III] peak at the source velocity toward the MIR source A/mmA2 suggesting that the emission is originating from closer to the protostar., Comment: 15 pages, 7 figures, accepted for publication in A&A

Published

2023

9. The diverse chemistry of protoplanetary disks as revealed by JWST

Author

van Dishoeck, Ewine F., Grant, S., Tabone, B., van Gelder, M., Francis, L., Tychoniec, L., Bettoni, G., Arabhavi, A. M., Gasman, D., Nazari, P., Vlasblom, M., Kavanagh, P., Christiaens, V., Klaassen, P., Beuther, H., Henning, Th., Kamp, I., van Dishoeck, Ewine F., Grant, S., Tabone, B., van Gelder, M., Francis, L., Tychoniec, L., Bettoni, G., Arabhavi, A. M., Gasman, D., Nazari, P., Vlasblom, M., Kavanagh, P., Christiaens, V., Klaassen, P., Beuther, H., Henning, Th., and Kamp, I.

Abstract

Early results from the JWST-MIRI guaranteed time programs on protostars (JOYS) and disks (MINDS) are presented. Thanks to the increased sensitivity, spectral and spatial resolution of the MIRI spectrometer, the chemical inventory of the planet-forming zones in disks can be investigated with unprecedented detail across stellar mass range and age. Here data are presented for five disks, four around low-mass stars and one around a very young high-mass star. The mid-infrared spectra show some similarities but also significant diversity: some sources are rich in CO2, others in H2O or C2H2. In one disk around a very low-mass star, booming C2H2 emission provides evidence for a ``soot'' line at which carbon grains are eroded and sublimated, leading to a rich hydrocarbon chemistry in which even di-acetylene (C4H2) and benzene (C6H6) are detected (Tabone et al. 2023). Together, the data point to an active inner disk gas-phase chemistry that is closely linked to the physical structure (temperature, snowlines, presence of cavities and dust traps) of the entire disk and which may result in varying CO2/H2O abundances and high C/O ratios >1 in some cases. Ultimately, this diversity in disk chemistry will also be reflected in the diversity of the chemical composition of exoplanets., Comment: 17 pages, 8 figures. Author's version of paper submitted to Faraday Discussions January 18 2023, Accepted March 16 2023

Published

2023

10. JOYS: JWST Observations of Young protoStars: Outflows and accretion in the high-mass star-forming region IRAS23385+605

Author

Beuther, H., van Dishoeck, E. F., Tychoniec, L., Gieser, C., Kavanagh, P. J., Perotti, G., van Gelder, M. L., Klaassen, P., Garatti, A. Caratti o, Francis, L., Rocha, W. R. M., Slavicinska, K., Ray, T., Justtanont, K., Linnartz, H., Weakens, C., Colina, L., Greve, T., Guedel, M., Henning, T., Lagage, P. O., Vandenbussche, B., Oestlin, G., Wright, G., Beuther, H., van Dishoeck, E. F., Tychoniec, L., Gieser, C., Kavanagh, P. J., Perotti, G., van Gelder, M. L., Klaassen, P., Garatti, A. Caratti o, Francis, L., Rocha, W. R. M., Slavicinska, K., Ray, T., Justtanont, K., Linnartz, H., Weakens, C., Colina, L., Greve, T., Guedel, M., Henning, T., Lagage, P. O., Vandenbussche, B., Oestlin, G., and Wright, G.

Abstract

Aims: The JWST program JOYS (JWST Observations of Young protoStars) aims at characterizing the physical and chemical properties of young high- and low-mass star-forming regions, in particular the unique mid-infrared diagnostics of the warmer gas and solid-state components. We present early results from the high-mass star formation region IRAS23385+6053. Methods: The JOYS program uses the MIRI MRS with its IFU to investigate a sample of high- and low-mass star-forming protostellar systems. Results: The 5 to 28mum MIRI spectrum of IRAS23385+6053 shows a plethora of features. While the general spectrum is typical for an embedded protostar, we see many atomic and molecular gas lines boosted by the higher spectral resolution and sensitivity compared to previous space missions. Furthermore, ice and dust absorption features are also present. Here, we focus on the continuum emission, outflow tracers like the H2, [FeII] and [NeII] lines as well as the potential accretion tracer Humphreys alpha HI(7--6). The short-wavelength MIRI data resolve two continuum sources A and B, where mid-infrared source A is associated with the main mm continuum peak. The combination of mid-infrared and mm data reveals a young cluster in its making. Combining the mid-infrared outflow tracer H2, [FeII] and [NeII] with mm SiO data shows a complex interplay of at least three molecular outflows driven by protostars in the forming cluster. Furthermore, the Humphreys alpha line is detected at a 3-4sigma level towards the mid-infrared sources A and B. Following Rigliaco et al. (2015), one can roughly estimate accretion luminosities and corresponding accretion rates between ~2.6x10^-6 and ~0.9x10^-4 M_sun/yr. This is discussed in the context of the observed outflow rates. Conclusions: The analysis of the MIRI MRS observations for this young high-mass star-forming region reveals connected outflow and accretion signatures., Comment: 12 pages, 9 figures, accepted for Astronomy & Astrophysics, the paper is also available at https://www2.mpia-hd.mpg.de/homes/beuther/papers.html

Published

2023

11. Vertically extended and asymmetric CN emission in the Elias 2-27 protoplanetary disk

Author

Paneque-Carreño, T., Miotello, A., van Dishoeck, E. F., Pérez, L. M., Facchini, S., Izquierdo, A., Tychoniec, L., Testi, L., Paneque-Carreño, T., Miotello, A., van Dishoeck, E. F., Pérez, L. M., Facchini, S., Izquierdo, A., Tychoniec, L., and Testi, L.

Abstract

Elias 2-27 is a young star that hosts an extended, bright and inclined disk of dust and gas. The inclination and extreme flaring of the disk make Elias 2-27 an ideal target to study the vertical distribution of molecules, particularly CN. We directly trace the emission of CN in Elias 2-27 and compare it to previously published CO isotopologue data. CN $N = 3-2$ emission is analyzed in two different transitions $J = 7/2 - 5/2$ and $J = 5/2 - 3/2$, for which we detect two hyperfine group transitions. The vertical location of CN emission is traced directly from the channel maps, following geometrical methods that have been previously used to analyze the CO emission of Elias 2-27. Analytical models are used to parametrize the vertical profile of each molecule and study the extent of each tracer, additionally we compute radial profiles of column density and optical depth. We show that the vertical location of CN and CO isotopologues in Elias 2-27 is layered and consistent with predictions from thermochemical models. A north/south asymmetry in the radial extent of CN is detected and we find that the CN emission is mostly optically thin and constrained vertically to a thin slab at $z/r \sim$0.5. A column density of 10$^{14}$\,cm$^{-2}$ is measured in the inner disk which for the north side decreases to 10$^{12}$\,cm$^{-2}$ and for the south side to 10$^{13}$\,cm$^{-2}$ in the outer regions. In Elias 2-27, CN traces a vertically elevated region above the midplane, very similar to that traced by $^{12}$CO. The inferred CN properties are consistent with thermo-chemical disk models, in which CN formation is initiated by the reaction of N with UV-pumped H$_2$. The observed north/south asymmetry may be caused by either ongoing infall or by a warped inner disk. This study highlights the importance of tracing the vertical location of various molecules to constrain the disk physical conditions., Comment: Accepted for publication in A&A, 19 pages, 14 figures

Published

2022

12. Early planet formation in embedded protostellar disks: Setting the stage for the first generation of planetesimals

Author

Cridland, A. J., Rosotti, G. P., Tabone, B., Tychoniec, L., McClure, M., van Dishoeck, E. F., Cridland, A. J., Rosotti, G. P., Tabone, B., Tychoniec, L., McClure, M., and van Dishoeck, E. F.

Abstract

(Abridged) Recent surveys of young star formation regions have shown that the average Class II object does not have enough dust mass to make the cores of giant planets. Younger Class 0/I objects have enough dust in their embedded disk, which begs the questions: can the first steps of planet formation occur in these younger systems? The first step is building the first planetesimals, generally believed to be the product of the streaming instability. Hence the question can be restated: are the physical conditions of embedded disks conducive to the growth of the streaming instability? Here we model the collapse of a `dusty' proto-stellar cloud to show that if there is sufficient drift between the falling gas and dust, regions of the embedded disk can become sufficiently enhanced in dust to drive the streaming instability. We include four models, three with different dust grain sizes and one with a different initial cloud angular momentum to test a variety of collapse trajectories. We find a `sweet spot' for planetesimal formation for grain sizes of a few 10s of micron since they fall sufficiently fast relative to the gas to build a high dust-to-gas ratio along the disk midplane, but have slow enough radial drift speeds in the embedded disk to maintain the high dust-to-gas ratio. Unlike the gas, which is held in hydrostatic equilibrium for a time due to gas pressure, the dust can begin collapsing from all radii at a much earlier time. The streaming instability can produce at least between 7-35 M$_\oplus$ of planetesimals in the Class 0/I phase of our smooth embedded disks, depending on the size of the falling dust grains. This first generation of planetesimals could represent the first step in planet formation, and occurs earlier in the lifetime of the young star than is traditionally thought., Comment: Accepted for publication in A&A, 22 pages, 19 figures

Published

2021

13. Early planet formation in embedded protostellar disks: Setting the stage for the first generation of planetesimals

Author

Cridland, A. J., Rosotti, G. P., Tabone, B., Tychoniec, L., McClure, M., van Dishoeck, E. F., Cridland, A. J., Rosotti, G. P., Tabone, B., Tychoniec, L., McClure, M., and van Dishoeck, E. F.

Abstract

(Abridged) Recent surveys of young star formation regions have shown that the average Class II object does not have enough dust mass to make the cores of giant planets. Younger Class 0/I objects have enough dust in their embedded disk, which begs the questions: can the first steps of planet formation occur in these younger systems? The first step is building the first planetesimals, generally believed to be the product of the streaming instability. Hence the question can be restated: are the physical conditions of embedded disks conducive to the growth of the streaming instability? Here we model the collapse of a `dusty' proto-stellar cloud to show that if there is sufficient drift between the falling gas and dust, regions of the embedded disk can become sufficiently enhanced in dust to drive the streaming instability. We include four models, three with different dust grain sizes and one with a different initial cloud angular momentum to test a variety of collapse trajectories. We find a `sweet spot' for planetesimal formation for grain sizes of a few 10s of micron since they fall sufficiently fast relative to the gas to build a high dust-to-gas ratio along the disk midplane, but have slow enough radial drift speeds in the embedded disk to maintain the high dust-to-gas ratio. Unlike the gas, which is held in hydrostatic equilibrium for a time due to gas pressure, the dust can begin collapsing from all radii at a much earlier time. The streaming instability can produce at least between 7-35 M$_\oplus$ of planetesimals in the Class 0/I phase of our smooth embedded disks, depending on the size of the falling dust grains. This first generation of planetesimals could represent the first step in planet formation, and occurs earlier in the lifetime of the young star than is traditionally thought., Comment: Accepted for publication in A&A, 22 pages, 19 figures

Published

2021

14. The prebiotic molecular inventory of Serpens SMM1 I. An investigation of the isomers CH3NCO and HOCH2CN

Author

Ligterink, N. F. W., Ahmadi, A., Coutens, A., Tychoniec, L., Calcutt, H., van Dishoeck, E. F., Linnartz, H., Jorgensen, J. K., Garrod, R. T., Bouwman, J., Ligterink, N. F. W., Ahmadi, A., Coutens, A., Tychoniec, L., Calcutt, H., van Dishoeck, E. F., Linnartz, H., Jorgensen, J. K., Garrod, R. T., and Bouwman, J.

Abstract

Aims. Methyl isocyanate (CH3NCO) and glycolonitrile (HOCH2CN) are isomers and prebiotic molecules that are involved in the formation of peptide structures and the nucleobase adenine, respectively. These two species are investigated to study the interstellar chemistry of cyanides (CN) and isocyanates (NCO) and to gain insight into the reservoir of interstellar prebiotic molecules.Methods. ALMA observations of the intermediate-mass Class 0 protostar Serpens SMM1-a and ALMA-PILS data of the low-mass Class 0 protostar IRAS 16293B are used. Spectra are analysed with the CASSIS line analysis software package in order to identify and characterise molecules.Results. CH3NCO, HOCH2CN, and various other molecules are detected towards SMM1-a. HOCH2CN is identified in the PILS data towards IRAS 16293B in a spectrum extracted at a half-beam offset position from the peak continuum. CH3NCO and HOCH2CN are equally abundant in SMM1-a at [X]/[CH3OH] of 5.3 x 10(-4) and 6.2x 10(-4), respectively. A comparison between SMM1-a and IRAS 16293B shows that HOCH2CN and HNCO are more abundant in the former source, but CH3NCO abundances do not differ significantly. Data from other sources are used to show that the [CH3NCO]/[HNCO] ratio is similar in all these sources within similar to 10%.Conclusions. The new detections of CH3NCO and HOCH2CN are additional evidence for a large interstellar reservoir of prebiotic molecules that can contribute to the formation of biomolecules on planets. The equal abundances of these molecules in SMM1-a indicate that their formation is driven by kinetic processes instead of thermodynamic equilibrium, which would drive the chemistry to one product. HOCH2 CN is found to be much more abundant in SMM1-a than in IRAS 16293B. From the observational data, it is difficult to indicate a formation pathway for HOCH2CN, but the thermal Strecker-like reaction of CN- with H2CO is a possibility. The similar [CH3NCO]/[HNCO] ratios found in the available s

Published

2021

15. The prebiotic molecular inventory of Serpens SMM1 I. An investigation of the isomers CH3NCO and HOCH2CN

Author

Ligterink, N. F. W., Ahmadi, A., Coutens, A., Tychoniec, L., Calcutt, H., van Dishoeck, E. F., Linnartz, H., Jorgensen, J. K., Garrod, R. T., Bouwman, J., Ligterink, N. F. W., Ahmadi, A., Coutens, A., Tychoniec, L., Calcutt, H., van Dishoeck, E. F., Linnartz, H., Jorgensen, J. K., Garrod, R. T., and Bouwman, J.

Abstract

Aims. Methyl isocyanate (CH3NCO) and glycolonitrile (HOCH2CN) are isomers and prebiotic molecules that are involved in the formation of peptide structures and the nucleobase adenine, respectively. These two species are investigated to study the interstellar chemistry of cyanides (CN) and isocyanates (NCO) and to gain insight into the reservoir of interstellar prebiotic molecules.Methods. ALMA observations of the intermediate-mass Class 0 protostar Serpens SMM1-a and ALMA-PILS data of the low-mass Class 0 protostar IRAS 16293B are used. Spectra are analysed with the CASSIS line analysis software package in order to identify and characterise molecules.Results. CH3NCO, HOCH2CN, and various other molecules are detected towards SMM1-a. HOCH2CN is identified in the PILS data towards IRAS 16293B in a spectrum extracted at a half-beam offset position from the peak continuum. CH3NCO and HOCH2CN are equally abundant in SMM1-a at [X]/[CH3OH] of 5.3 x 10(-4) and 6.2x 10(-4), respectively. A comparison between SMM1-a and IRAS 16293B shows that HOCH2CN and HNCO are more abundant in the former source, but CH3NCO abundances do not differ significantly. Data from other sources are used to show that the [CH3NCO]/[HNCO] ratio is similar in all these sources within similar to 10%.Conclusions. The new detections of CH3NCO and HOCH2CN are additional evidence for a large interstellar reservoir of prebiotic molecules that can contribute to the formation of biomolecules on planets. The equal abundances of these molecules in SMM1-a indicate that their formation is driven by kinetic processes instead of thermodynamic equilibrium, which would drive the chemistry to one product. HOCH2 CN is found to be much more abundant in SMM1-a than in IRAS 16293B. From the observational data, it is difficult to indicate a formation pathway for HOCH2CN, but the thermal Strecker-like reaction of CN- with H2CO is a possibility. The similar [CH3NCO]/[HNCO] ratios found in the available s

Published

2021

16. Complex organic molecules in low-mass protostars on Solar System scales I. Oxygen-bearing species

Author

van Gelder, M. L., Tabone, B., Tychoniec, L., van Dishoeck, E. F., Beuther, H., Boogert, A. C. A., Garatti, A. Caratti O., Klaassen, P. D., Linnartz, H., Mueller, H. S. P., Taquet, V, van Gelder, M. L., Tabone, B., Tychoniec, L., van Dishoeck, E. F., Beuther, H., Boogert, A. C. A., Garatti, A. Caratti O., Klaassen, P. D., Linnartz, H., Mueller, H. S. P., and Taquet, V

Abstract

Context. Complex organic molecules (COMs) are thought to form on icy dust grains in the earliest phase of star formation. The evolution of these COMs from the youngest Class 0/I protostellar phases toward the more evolved Class II phase is still not fully understood. Since planet formation seems to start early, and mature disks are too cold for characteristic COM emission lines, studying the inventory of COMs on Solar- System scales in the Class 0/I stage is relevant. Aims. Our aim is to determine the abundance ratios of oxygen-bearing COMs in Class 0 protostellar systems on scales of similar to 100 AU radius. We aim to compare these abundances with one another, and to the abundances of other low-mass protostars such as IRAS 16293-2422B and HH 212. Additionally, using both cold and hot COM lines, the gas-phase abundances can be tracked from a cold to a hot component, and ultimately be compared with those in ices to be measured with the James Webb Space Telescope (JWST). The abundance of deuterated methanol allows us to probe the ambient temperature during the formation of this species. Methods. ALMA Band 3 (3 mm) and Band 6 (1 mm) observations are obtained for seven Class 0 protostars in the Perseus and Serpens star-forming regions. By modeling the inner protostellar region using local thermodynamic equilibrium models, the excitation temperature and column densities are determined for several O-bearing COMs including methanol (CH3OH), acetaldehyde (CH3CHO), methyl formate (CH3OCHO), and dimethyl ether (CH3OCH3). Abundance ratios are taken with respect to CH3OH. Results. Three out of the seven of the observed sources, B1-c, B1-bS (both Perseus), and Serpens S68N (Serpens), show COM emission. No clear correlation seems to exist between the occurrence of COMs and source luminosity. The abundances of several COMs such as CH3OCHO, CH3OCH3, acetone (CH3COCH3), and ethylene glycol ((CH2OH)(2)) are remarkably similar for the three COM-rich sources; this similarity also exte

Published

2020

17. Complex organic molecules in low-mass protostars on Solar System scales I. Oxygen-bearing species

Author

van Gelder, M. L., Tabone, B., Tychoniec, L., van Dishoeck, E. F., Beuther, H., Boogert, A. C. A., Garatti, A. Caratti O., Klaassen, P. D., Linnartz, H., Mueller, H. S. P., Taquet, V, van Gelder, M. L., Tabone, B., Tychoniec, L., van Dishoeck, E. F., Beuther, H., Boogert, A. C. A., Garatti, A. Caratti O., Klaassen, P. D., Linnartz, H., Mueller, H. S. P., and Taquet, V

Abstract

Context. Complex organic molecules (COMs) are thought to form on icy dust grains in the earliest phase of star formation. The evolution of these COMs from the youngest Class 0/I protostellar phases toward the more evolved Class II phase is still not fully understood. Since planet formation seems to start early, and mature disks are too cold for characteristic COM emission lines, studying the inventory of COMs on Solar- System scales in the Class 0/I stage is relevant. Aims. Our aim is to determine the abundance ratios of oxygen-bearing COMs in Class 0 protostellar systems on scales of similar to 100 AU radius. We aim to compare these abundances with one another, and to the abundances of other low-mass protostars such as IRAS 16293-2422B and HH 212. Additionally, using both cold and hot COM lines, the gas-phase abundances can be tracked from a cold to a hot component, and ultimately be compared with those in ices to be measured with the James Webb Space Telescope (JWST). The abundance of deuterated methanol allows us to probe the ambient temperature during the formation of this species. Methods. ALMA Band 3 (3 mm) and Band 6 (1 mm) observations are obtained for seven Class 0 protostars in the Perseus and Serpens star-forming regions. By modeling the inner protostellar region using local thermodynamic equilibrium models, the excitation temperature and column densities are determined for several O-bearing COMs including methanol (CH3OH), acetaldehyde (CH3CHO), methyl formate (CH3OCHO), and dimethyl ether (CH3OCH3). Abundance ratios are taken with respect to CH3OH. Results. Three out of the seven of the observed sources, B1-c, B1-bS (both Perseus), and Serpens S68N (Serpens), show COM emission. No clear correlation seems to exist between the occurrence of COMs and source luminosity. The abundances of several COMs such as CH3OCHO, CH3OCH3, acetone (CH3COCH3), and ethylene glycol ((CH2OH)(2)) are remarkably similar for the three COM-rich sources; this similarity also exte

Published

2020

18. Far infrared CO and H$_2$O emission in intermediate-mass protostars

Author

Matuszak, M., Karska, A., Kristensen, L. E., Herczeg, G. J., Tychoniec, L., van Kempen, T., Fuente, A., Matuszak, M., Karska, A., Kristensen, L. E., Herczeg, G. J., Tychoniec, L., van Kempen, T., and Fuente, A.

Abstract

Intermediate-mass young stellar objects (YSOs) provide a link to understand how feedback from shocks and UV radiation scales from low to high-mass star forming regions. Aims: Our aim is to analyze excitation of CO and H$_2$O in deeply-embedded intermediate-mass YSOs and compare with low-mass and high-mass YSOs. Methods: Herschel/PACS spectral maps are analyzed for 6 YSOs with bolometric luminosities of $L_\mathrm{bol}\sim10^2 - 10^3$ $L_\odot$. The maps cover spatial scales of $\sim 10^4$ AU in several CO and H$_2$O lines located in the $\sim55-210$ $\mu$m range. Results: Rotational diagrams of CO show two temperature components at $T_\mathrm{rot}\sim320$ K and $T_\mathrm{rot}\sim700-800$ K, comparable to low- and high-mass protostars probed at similar spatial scales. The diagrams for H$_2$O show a single component at $T_\mathrm{rot}\sim130$ K, as seen in low-mass protostars, and about $100$ K lower than in high-mass protostars. Since the uncertainties in $T_\mathrm{rot}$ are of the same order as the difference between the intermediate and high-mass protostars, we cannot conclude whether the change in rotational temperature occurs at a specific luminosity, or whether the change is more gradual from low- to high-mass YSOs. Conclusions: Molecular excitation in intermediate-mass protostars is comparable to the central $10^{3}$ AU of low-mass protostars and consistent within the uncertainties with the high-mass protostars probed at $3\cdot10^{3}$ AU scales, suggesting similar shock conditions in all those sources., Comment: Accepted to Astronomy & Astrophysics. 4 pages, 5 figures, 3 tables

Published

2015

19. Far infrared CO and H$_2$O emission in intermediate-mass protostars

Author

Matuszak, M., Karska, A., Kristensen, L. E., Herczeg, G. J., Tychoniec, L., van Kempen, T., Fuente, A., Matuszak, M., Karska, A., Kristensen, L. E., Herczeg, G. J., Tychoniec, L., van Kempen, T., and Fuente, A.

Abstract

Intermediate-mass young stellar objects (YSOs) provide a link to understand how feedback from shocks and UV radiation scales from low to high-mass star forming regions. Aims: Our aim is to analyze excitation of CO and H$_2$O in deeply-embedded intermediate-mass YSOs and compare with low-mass and high-mass YSOs. Methods: Herschel/PACS spectral maps are analyzed for 6 YSOs with bolometric luminosities of $L_\mathrm{bol}\sim10^2 - 10^3$ $L_\odot$. The maps cover spatial scales of $\sim 10^4$ AU in several CO and H$_2$O lines located in the $\sim55-210$ $\mu$m range. Results: Rotational diagrams of CO show two temperature components at $T_\mathrm{rot}\sim320$ K and $T_\mathrm{rot}\sim700-800$ K, comparable to low- and high-mass protostars probed at similar spatial scales. The diagrams for H$_2$O show a single component at $T_\mathrm{rot}\sim130$ K, as seen in low-mass protostars, and about $100$ K lower than in high-mass protostars. Since the uncertainties in $T_\mathrm{rot}$ are of the same order as the difference between the intermediate and high-mass protostars, we cannot conclude whether the change in rotational temperature occurs at a specific luminosity, or whether the change is more gradual from low- to high-mass YSOs. Conclusions: Molecular excitation in intermediate-mass protostars is comparable to the central $10^{3}$ AU of low-mass protostars and consistent within the uncertainties with the high-mass protostars probed at $3\cdot10^{3}$ AU scales, suggesting similar shock conditions in all those sources., Comment: Accepted to Astronomy & Astrophysics. 4 pages, 5 figures, 3 tables

Published

2015