JWST Observations of Young protoStars (JOYS) Overview of program and early results

E. F. van Dishoeck; Tychoniec; W. R.M. Rocha; K. Slavicinska; L. Francis; M. L. van Gelder; T. P. Ray; H. Beuther; A. Caratti o Garatti; N. G.C. Brunken; Y. Chen; R. Devaraj; V. C. Geers; C. Gieser; T. P. Greene; K. Justtanont; V. J.M. Le Gouellec; P. J. Kavanagh; P. D. Klaassen; A. G.M. Janssen; M. G. Navarro; P. Nazari; S. Notsu; G. Perotti; M. E. Ressler; S. D. Reyes; A. D. Sellek; B. Tabone; C. Tap; N. C.M.A. Theijssen; L. Colina; M. Güdel; Th Henning; P. O. Lagage; G. Östlin; B. Vandenbussche; G. S. Wright

doi:10.1051/0004-6361/202554444

JWST Observations of Young protoStars (JOYS) Overview of program and early results

E. F. van Dishoeck
, Tychoniec
, W. R.M. Rocha
, K. Slavicinska
, L. Francis
, M. L. van Gelder
, T. P. Ray
, H. Beuther
, A. Caratti o Garatti
, N. G.C. Brunken
, Y. Chen
, R. Devaraj
, V. C. Geers
, C. Gieser
, T. P. Greene
, K. Justtanont
, V. J.M. Le Gouellec
, P. J. Kavanagh
, P. D. Klaassen
, A. G.M. Janssen

M. G. Navarro, P. Nazari, S. Notsu, G. Perotti, M. E. Ressler, S. D. Reyes, A. D. Sellek, B. Tabone, C. Tap, N. C.M.A. Theijssen, L. Colina, M. Güdel, Th Henning, P. O. Lagage, G. Östlin, B. Vandenbussche, G. S. Wright

Department of Astrophysics

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

Context. The embedded phase of star formation is a crucial period in the development of a young star when the system still accretes matter, emerges from its natal cloud with assistance from powerful jets and outflows, and forms a disk, thus setting the stage for the birth of a planetary system. The mid-infrared spectral line observations now possible with unprecedented sensitivity, spectral resolution, and sharpness from the James Webb Space Telescope (JWST) are key for probing many of the physical and chemical processes on subarcsecond scales that occur in highly extincted regions. They provide unique diagnostics and complement millimeter observations. Aims. The aim of the JWST Observations of Young protoStars (JOYS) program is to address a wide variety of topics ranging from protostellar accretion and the nature of primeval jets, winds, and outflows to the chemistry of gas and ice in hot cores and cold dense protostellar environments to the characteristics of the embedded disks. We introduce the JOYS program and show representative results. Methods. The JWST Mid-InfraRed Instrument (MIRI) Medium Resolution Spectrometer (MRS) Integral Field Unit (IFU) 5–28 µm maps of 17 low-mass targets (23 if binary components are counted individually) and six high-mass protostellar sources were taken with resolving powers R = λ/∆λ = 1500–4000. We used small mosaics ranging from 1 × 1 to 3 × 3 MRS tiles to cover ∼4^′′ to 20^′′ fields of view, providing spectral imaging on spatial scales down to ∼30 au (low mass) and ∼600 au (high mass). For HH 211, the complete ∼1^′ blue outflow lobe was mapped with the MRS. Atomic lines were interpreted with published shock models, whereas molecular lines were analyzed with simple rotation diagrams and local thermodynamic equilibrium slab models. We stress the importance of taking infrared pumping into account. Inferred abundance ratios were compared with detailed hot core chemical models including X-rays, whereas ice spectra were fit through comparison with laboratory spectra. Results. The JWST MIRI-MRS spectra show a wide variety of features, with their spatial distribution providing key insight into their physical origin. The atomic line maps differ among refractory (e.g., Fe), semi-refractory (e.g., S), and volatile elements (e.g., Ne) and are linked to their different levels of depletion and local (shock) conditions. Jets are prominently seen in lines of [Fe II] and other refractory elements, whereas the pure rotational H₂ lines probe hot (∼1000 K) and warm (few ×10² K) gas inside the cavity, as well as gas associated with jets, entrained outflows, and cavity walls for both low- and high-mass sources. Wide-angle winds are found in low-J H₂ lines. Nested stratified jet structures containing an inner ionized core with an outer molecular layer are commonly seen in the youngest sources. While [S I] follows the jet as seen in [Fe II] in the youngest protostars, it is different in more evolved sources, where it is concentrated on source. Noble gas lines such as [Ne II] 12.8 µm reveal a mix of jet shock and photoionized emission. The H I recombination lines serve as a measure of protostellar accretion rates but are also associated with more extended jets. Gaseous molecular emission (CO₂, C₂H₂, HCN, H₂O, CH₄, SO₂, SiO) is seen toward several sources, but it is cool compared with what is found in more evolved disks, with excitation temperatures of only 100–250 K, and likely associated with the warm inner envelopes (“hot cores”) . Along the outflow, CO₂ is often extended, thus contrasting with C₂H₂, which is usually centered on source. Water emission is commonly detected on source, even if relatively weak. Off source, it is seen only in the highest density shocks, such as those associated with NGC 1333 IRAS4B. Some sources show gaseous molecular lines in absorption, including NH₃ in one case. Deep ice features are seen toward the protostars, revealing not just the major ice components but also ions (as part of salts) and complex organic molecules, with comparable abundances from low- to high-mass sources. The relative abundances of some gas and ice species are similar, which is consistent with ice sublimation in hot cores. We present a second detection of HDO ice in a solar-mass source, with an HDO/H₂O ice ratio of ∼0.4%, thus providing a link with HDO/H₂O in disks and comets. A deep search for solid O₂ suggests that it is not a significant oxygen reservoir. Only a few embedded Class I disks show the same forest of water lines as Class II disks. This may be due to significant dust extinction of the upper layers in young disks caused by less settling of small dust as well as radial drift bringing in fresh dust. Conclusions. This paper illustrates the wide range of science questions that a single MIRI-MRS IFU data set can address. Our data suggest many similarities between low- and high-mass sources. Large source samples across evolutionary stages and luminosities are needed to further develop these diagnostics of the physics and chemistry of protostellar systems.

Original language	English
Article number	A361
Number of pages	46
Journal	Astronomy and Astrophysics
Volume	699
DOIs	https://doi.org/10.1051/0004-6361/202554444
Publication status	Published - 22 Jul 2025

Funding

The authors thank the referee for their constructive comments and the entire JOYS+ team, Adwin Boogert, John Black, Brunella Nisini, Teresa Giannini, and Christoffel Waelkens for useful discussions. Collaboration with Catherine Walsh on hot core chemical models is much appreciated. This work is based on observations made with the NASA/ESA/CSA James Webb Space Telescope. The data were obtained from the Mikulski Archive for Space Telescopes at the Space Telescope Science Institute, which is operated by the Association of Universities for Research in Astronomy, Inc., under NASA contract NAS 5-03127 for JWST. These observations are associated with programs 1290 and 1257. The following National and International Funding Agencies funded and supported the MIRI development: NASA; ESA; Belgian Science Policy Office (BELSPO); Centre Nationale d’Études Spatiales (CNES); Danish National Space Centre; Deutsches Zentrum fur Luft und Raumfahrt (DLR); Enterprise Ireland; Ministerio De Economiá y Competividad; The Netherlands Research School for Astronomy (NOVA); The Netherlands Organisation for Scientific Research (NWO); Science and Technology Facilities Council; Swiss Space Office; Swedish National Space Agency; and UK Space Agency. Astrochemistry in Leiden is supported by funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation program (grant agreement No. 291141 MOLDISK), and by NOVA and NWO through TOP-1 grant 614.001.751 and its Dutch Astrochemistry Program (DANII). The present work is closely connected to ongoing research within InterCat, the Center for Interstellar Catalysis located in Aarhus, Denmark. TR acknowledges support from ERC grant no. 743029 EASY and TH from ERC grant no. 832428 Origins. ACG acknowledges support from PRINMUR 2022 20228JPA3A “The path to star and planet formation in the JWST era (PATH)” funded by NextGeneration EU and by INAF-GoG 2022 “NIR-dark Accretion Outbursts in Massive Young stellar objects (NAOMY)” and Large Grant INAF 2022 “YSOs Outflows, Disks and Accretion: toward a global framework for the evolution of planet forming systems (YODA)”. KJ and GÖ acknowledge support from the Swedish National Space Agency (SNSA), and LC from grant PIB2021-127718NB-100 from the Spanish Ministry of Science and Innovation/State Agency of Research MCIN/AEI/10.13039/50110001103. PJK acknowledges financial support from the Research Ireland Pathway programme under Grant Number 21/PATH-S/9360. VJML’s research is supported by an appointment to the NASA Postdoctoral Program at the NASA Ames Research Center, administered by Oak Ridge Associated Universities under contract with NASA. PN acknowledges support from the ESO Fellowship and IAU Gruber Foundation Fellowship programs. SN is grateful for support from Grants-in-Aid for JSPS (Japan Society for the Promotion of Science) Fellows Grant Number JP23KJ0329, MEXT/JSPS Grants-in-Aid for Scientific Research (KAKENHI) Grant Numbers JP23K13155 and JP24K00674, and Start-up Research Grant as one of the University of Tokyo Excellent Young Researcher 2024. GP gratefully acknowledges support from the Max Planck Society and from the Carlsberg Foundation, grant CF23-0481. This paper makes use of the following ALMA data: ADS/JAO.ALMA#ALMA 2015.1.00354.S, ADS/JAO.ALMA#ALMA 2017.1.01350.S, ADS/JAO.ALMA#ALMA 2019.1.00931.S. ALMA is a partnership of ESO (representing its member states), NSF (USA) and NINS (Japan), together with NRC (Canada), NSTC and ASIAA (Taiwan), and KASI (Republic of Korea), in cooperation with the Republic of Chile. The Joint ALMA Observatory is operated by ESO, AUI/NRAO and NAOJ. The authors thank the referee for their constructive comments and the entire JOYS+ team, Adwin Boogert, John Black, Brunella Nisini, Teresa Giannini, and Christoffel Waelkens for useful discussions. Collaboration with Catherine Walsh on hot core chemical models is much appreciated. This work is based on observations made with the NASA/ESA/CSA James Webb Space Telescope. The data were obtained from the Mikulski Archive for Space Telescopes at the Space Telescope Science Institute, which is operated by the Association of Universities for Research in Astronomy, Inc., under NASA con tract NAS 5-03127 for JWST. These observations are associated with programs 1290 and 1257. The following National and International Funding Agencies funded and supported the MIRI development: NASA; ESA; Belgian Science Policy Office (BELSPO); Centre Nationale d’Études Spatiales (CNES); Danish National Space Centre; Deutsches Zentrum fur Luft und Raumfahrt (DLR); Enterprise Ireland; Ministerio De Economiá y Competividad; The Netherlands Research School for Astronomy (NOVA); The Netherlands Organisation for Scientific Research (NWO); Science and Technology Facilities Council; Swiss Space Office; Swedish National Space Agency; and UK Space Agency. Astro chemistry in Leiden is supported by funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation program (grant agreement No. 291141 MOLDISK), and by NOVA and NWO through TOP-1 grant 614.001.751 and its Dutch Astrochemistry Pro gram (DANII). The present work is closely connected to ongoing research within InterCat, the Center for Interstellar Catalysis located in Aarhus, Den mark. TR acknowledges support from ERC grant no. 743029 EASY and TH from ERC grant no. 832428 Origins. ACG acknowledges support from PRIN-MUR 2022 20228JPA3A “The path to star and planet formation in the JWST era (PATH)” funded by NextGeneration EU and by INAF-GoG 2022 “NIR-dark Accretion Outbursts in Massive Young stellar objects (NAOMY)” and Large Grant INAF 2022 “YSOs Outflows, Disks and Accretion: toward a global framework for the evolution of planet forming systems (YODA)”. KJ and GÖ acknowledge support from the Swedish National Space Agency (SNSA), and LC from grant PIB2021-127718NB-100 from the Spanish Ministry of Science and Innovation/State Agency of Research MCIN/AEI/10.13039/50110001103. PJK acknowledges financial support from the Research Ireland Pathway programme under Grant Number 21/PATH-S/9360. VJML’s research is supported by an appointment to the NASA Postdoctoral Program at the NASA Ames Research Center, administered by Oak Ridge Associated Universities under contract with NASA. PN acknowledges support from the ESO Fellowship and IAU Gruber Foundation Fellowship programs. SN is grateful for support from Grants-in-Aid for JSPS (Japan Society for the Promotion of Science) Fellows Grant Number JP23KJ0329, MEXT/JSPS Grants-in-Aid for Scientific Research (KAKENHI) Grant Numbers JP23K13155 and JP24K00674, and Start-up Research Grant as one of the University of Tokyo Excellent Young Researcher 2024. GP gratefully acknowledges support from the Max Planck Society and from the Carlsberg Foundation, grant CF23-0481. This paper makes use of the following ALMA data: ADS/JAO.ALMA#ALMA 2015.1.00354.S, ADS/JAO.ALMA#ALMA 2017.1.01350.S, ADS/JAO.ALMA#ALMA 2019.1.00931.S. ALMA is a partner ship of ESO (representing its member states), NSF (USA) and NINS (Japan), together with NRC (Canada), NSTC and ASIAA (Taiwan), and KASI (Republic of Korea), in cooperation with the Republic of Chile. The Joint ALMA Observatory is operated by ESO, AUI/NRAO and NAOJ.

Austrian Fields of Science 2012

103003 Astronomy
103004 Astrophysics

Keywords

ISM: atoms
ISM: jets and outflows
ISM: molecules
methods: laboratory: solid state
stars: formation

Access to Document

10.1051/0004-6361/202554444Licence: CC BY 4.0

Cite this

van Dishoeck, E. F., Tychoniec, Rocha, W. R. M., Slavicinska, K., Francis, L., van Gelder, M. L., Ray, T. P., Beuther, H., Caratti o Garatti, A., Brunken, N. G. C., Chen, Y., Devaraj, R., Geers, V. C., Gieser, C., Greene, T. P., Justtanont, K., Le Gouellec, V. J. M., Kavanagh, P. J., Klaassen, P. D., ... Wright, G. S. (2025). JWST Observations of Young protoStars (JOYS) Overview of program and early results. Astronomy and Astrophysics, 699, Article A361. https://doi.org/10.1051/0004-6361/202554444

@article{65105f44cf9441bbb2a9b899ab0314ec,

title = "JWST Observations of Young protoStars (JOYS) Overview of program and early results",

abstract = "Context. The embedded phase of star formation is a crucial period in the development of a young star when the system still accretes matter, emerges from its natal cloud with assistance from powerful jets and outflows, and forms a disk, thus setting the stage for the birth of a planetary system. The mid-infrared spectral line observations now possible with unprecedented sensitivity, spectral resolution, and sharpness from the James Webb Space Telescope (JWST) are key for probing many of the physical and chemical processes on subarcsecond scales that occur in highly extincted regions. They provide unique diagnostics and complement millimeter observations. Aims. The aim of the JWST Observations of Young protoStars (JOYS) program is to address a wide variety of topics ranging from protostellar accretion and the nature of primeval jets, winds, and outflows to the chemistry of gas and ice in hot cores and cold dense protostellar environments to the characteristics of the embedded disks. We introduce the JOYS program and show representative results. Methods. The JWST Mid-InfraRed Instrument (MIRI) Medium Resolution Spectrometer (MRS) Integral Field Unit (IFU) 5–28 µm maps of 17 low-mass targets (23 if binary components are counted individually) and six high-mass protostellar sources were taken with resolving powers R = λ/∆λ = 1500–4000. We used small mosaics ranging from 1 × 1 to 3 × 3 MRS tiles to cover ∼4′′ to 20′′ fields of view, providing spectral imaging on spatial scales down to ∼30 au (low mass) and ∼600 au (high mass). For HH 211, the complete ∼1′ blue outflow lobe was mapped with the MRS. Atomic lines were interpreted with published shock models, whereas molecular lines were analyzed with simple rotation diagrams and local thermodynamic equilibrium slab models. We stress the importance of taking infrared pumping into account. Inferred abundance ratios were compared with detailed hot core chemical models including X-rays, whereas ice spectra were fit through comparison with laboratory spectra. Results. The JWST MIRI-MRS spectra show a wide variety of features, with their spatial distribution providing key insight into their physical origin. The atomic line maps differ among refractory (e.g., Fe), semi-refractory (e.g., S), and volatile elements (e.g., Ne) and are linked to their different levels of depletion and local (shock) conditions. Jets are prominently seen in lines of [Fe II] and other refractory elements, whereas the pure rotational H2 lines probe hot (∼1000 K) and warm (few ×102 K) gas inside the cavity, as well as gas associated with jets, entrained outflows, and cavity walls for both low- and high-mass sources. Wide-angle winds are found in low-J H2 lines. Nested stratified jet structures containing an inner ionized core with an outer molecular layer are commonly seen in the youngest sources. While [S I] follows the jet as seen in [Fe II] in the youngest protostars, it is different in more evolved sources, where it is concentrated on source. Noble gas lines such as [Ne II] 12.8 µm reveal a mix of jet shock and photoionized emission. The H I recombination lines serve as a measure of protostellar accretion rates but are also associated with more extended jets. Gaseous molecular emission (CO2, C2H2, HCN, H2O, CH4, SO2, SiO) is seen toward several sources, but it is cool compared with what is found in more evolved disks, with excitation temperatures of only 100–250 K, and likely associated with the warm inner envelopes (“hot cores”) . Along the outflow, CO2 is often extended, thus contrasting with C2H2, which is usually centered on source. Water emission is commonly detected on source, even if relatively weak. Off source, it is seen only in the highest density shocks, such as those associated with NGC 1333 IRAS4B. Some sources show gaseous molecular lines in absorption, including NH3 in one case. Deep ice features are seen toward the protostars, revealing not just the major ice components but also ions (as part of salts) and complex organic molecules, with comparable abundances from low- to high-mass sources. The relative abundances of some gas and ice species are similar, which is consistent with ice sublimation in hot cores. We present a second detection of HDO ice in a solar-mass source, with an HDO/H2O ice ratio of ∼0.4\%, thus providing a link with HDO/H2O in disks and comets. A deep search for solid O2 suggests that it is not a significant oxygen reservoir. Only a few embedded Class I disks show the same forest of water lines as Class II disks. This may be due to significant dust extinction of the upper layers in young disks caused by less settling of small dust as well as radial drift bringing in fresh dust. Conclusions. This paper illustrates the wide range of science questions that a single MIRI-MRS IFU data set can address. Our data suggest many similarities between low- and high-mass sources. Large source samples across evolutionary stages and luminosities are needed to further develop these diagnostics of the physics and chemistry of protostellar systems.",

keywords = "ISM: atoms, ISM: jets and outflows, ISM: molecules, methods: laboratory: solid state, stars: formation",

author = "\{van Dishoeck\}, \{E. F.\} and Tychoniec and Rocha, \{W. R.M.\} and K. Slavicinska and L. Francis and \{van Gelder\}, \{M. L.\} and Ray, \{T. P.\} and H. Beuther and \{Caratti o Garatti\}, A. and Brunken, \{N. G.C.\} and Y. Chen and R. Devaraj and Geers, \{V. C.\} and C. Gieser and Greene, \{T. P.\} and K. Justtanont and \{Le Gouellec\}, \{V. J.M.\} and Kavanagh, \{P. J.\} and Klaassen, \{P. D.\} and Janssen, \{A. G.M.\} and Navarro, \{M. G.\} and P. Nazari and S. Notsu and G. Perotti and Ressler, \{M. E.\} and Reyes, \{S. D.\} and Sellek, \{A. D.\} and B. Tabone and C. Tap and Theijssen, \{N. C.M.A.\} and L. Colina and M. G{\"u}del and Th Henning and Lagage, \{P. O.\} and G. {\"O}stlin and B. Vandenbussche and Wright, \{G. S.\}",

note = "Publisher Copyright: {\textcopyright} The Authors 2025.",

year = "2025",

month = jul,

day = "22",

doi = "10.1051/0004-6361/202554444",

language = "English",

volume = "699",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

publisher = "EDP SCIENCES S A",

}

van Dishoeck, EF, Tychoniec, Rocha, WRM, Slavicinska, K, Francis, L, van Gelder, ML, Ray, TP, Beuther, H, Caratti o Garatti, A, Brunken, NGC, Chen, Y, Devaraj, R, Geers, VC, Gieser, C, Greene, TP, Justtanont, K, Le Gouellec, VJM, Kavanagh, PJ, Klaassen, PD, Janssen, AGM, Navarro, MG, Nazari, P, Notsu, S, Perotti, G, Ressler, ME, Reyes, SD, Sellek, AD, Tabone, B, Tap, C, Theijssen, NCMA, Colina, L, Güdel, M, Henning, T, Lagage, PO, Östlin, G, Vandenbussche, B & Wright, GS 2025, 'JWST Observations of Young protoStars (JOYS) Overview of program and early results', Astronomy and Astrophysics, vol. 699, A361. https://doi.org/10.1051/0004-6361/202554444

TY - JOUR

T1 - JWST Observations of Young protoStars (JOYS) Overview of program and early results

AU - van Dishoeck, E. F.

AU - Tychoniec,

AU - Rocha, W. R.M.

AU - Slavicinska, K.

AU - Francis, L.

AU - van Gelder, M. L.

AU - Ray, T. P.

AU - Beuther, H.

AU - Caratti o Garatti, A.

AU - Brunken, N. G.C.

AU - Chen, Y.

AU - Devaraj, R.

AU - Geers, V. C.

AU - Gieser, C.

AU - Greene, T. P.

AU - Justtanont, K.

AU - Le Gouellec, V. J.M.

AU - Kavanagh, P. J.

AU - Klaassen, P. D.

AU - Janssen, A. G.M.

AU - Navarro, M. G.

AU - Nazari, P.

AU - Notsu, S.

AU - Perotti, G.

AU - Ressler, M. E.

AU - Reyes, S. D.

AU - Sellek, A. D.

AU - Tabone, B.

AU - Tap, C.

AU - Theijssen, N. C.M.A.

AU - Colina, L.

AU - Güdel, M.

AU - Henning, Th

AU - Lagage, P. O.

AU - Östlin, G.

AU - Vandenbussche, B.

AU - Wright, G. S.

PY - 2025/7/22

Y1 - 2025/7/22

N2 - Context. The embedded phase of star formation is a crucial period in the development of a young star when the system still accretes matter, emerges from its natal cloud with assistance from powerful jets and outflows, and forms a disk, thus setting the stage for the birth of a planetary system. The mid-infrared spectral line observations now possible with unprecedented sensitivity, spectral resolution, and sharpness from the James Webb Space Telescope (JWST) are key for probing many of the physical and chemical processes on subarcsecond scales that occur in highly extincted regions. They provide unique diagnostics and complement millimeter observations. Aims. The aim of the JWST Observations of Young protoStars (JOYS) program is to address a wide variety of topics ranging from protostellar accretion and the nature of primeval jets, winds, and outflows to the chemistry of gas and ice in hot cores and cold dense protostellar environments to the characteristics of the embedded disks. We introduce the JOYS program and show representative results. Methods. The JWST Mid-InfraRed Instrument (MIRI) Medium Resolution Spectrometer (MRS) Integral Field Unit (IFU) 5–28 µm maps of 17 low-mass targets (23 if binary components are counted individually) and six high-mass protostellar sources were taken with resolving powers R = λ/∆λ = 1500–4000. We used small mosaics ranging from 1 × 1 to 3 × 3 MRS tiles to cover ∼4′′ to 20′′ fields of view, providing spectral imaging on spatial scales down to ∼30 au (low mass) and ∼600 au (high mass). For HH 211, the complete ∼1′ blue outflow lobe was mapped with the MRS. Atomic lines were interpreted with published shock models, whereas molecular lines were analyzed with simple rotation diagrams and local thermodynamic equilibrium slab models. We stress the importance of taking infrared pumping into account. Inferred abundance ratios were compared with detailed hot core chemical models including X-rays, whereas ice spectra were fit through comparison with laboratory spectra. Results. The JWST MIRI-MRS spectra show a wide variety of features, with their spatial distribution providing key insight into their physical origin. The atomic line maps differ among refractory (e.g., Fe), semi-refractory (e.g., S), and volatile elements (e.g., Ne) and are linked to their different levels of depletion and local (shock) conditions. Jets are prominently seen in lines of [Fe II] and other refractory elements, whereas the pure rotational H2 lines probe hot (∼1000 K) and warm (few ×102 K) gas inside the cavity, as well as gas associated with jets, entrained outflows, and cavity walls for both low- and high-mass sources. Wide-angle winds are found in low-J H2 lines. Nested stratified jet structures containing an inner ionized core with an outer molecular layer are commonly seen in the youngest sources. While [S I] follows the jet as seen in [Fe II] in the youngest protostars, it is different in more evolved sources, where it is concentrated on source. Noble gas lines such as [Ne II] 12.8 µm reveal a mix of jet shock and photoionized emission. The H I recombination lines serve as a measure of protostellar accretion rates but are also associated with more extended jets. Gaseous molecular emission (CO2, C2H2, HCN, H2O, CH4, SO2, SiO) is seen toward several sources, but it is cool compared with what is found in more evolved disks, with excitation temperatures of only 100–250 K, and likely associated with the warm inner envelopes (“hot cores”) . Along the outflow, CO2 is often extended, thus contrasting with C2H2, which is usually centered on source. Water emission is commonly detected on source, even if relatively weak. Off source, it is seen only in the highest density shocks, such as those associated with NGC 1333 IRAS4B. Some sources show gaseous molecular lines in absorption, including NH3 in one case. Deep ice features are seen toward the protostars, revealing not just the major ice components but also ions (as part of salts) and complex organic molecules, with comparable abundances from low- to high-mass sources. The relative abundances of some gas and ice species are similar, which is consistent with ice sublimation in hot cores. We present a second detection of HDO ice in a solar-mass source, with an HDO/H2O ice ratio of ∼0.4%, thus providing a link with HDO/H2O in disks and comets. A deep search for solid O2 suggests that it is not a significant oxygen reservoir. Only a few embedded Class I disks show the same forest of water lines as Class II disks. This may be due to significant dust extinction of the upper layers in young disks caused by less settling of small dust as well as radial drift bringing in fresh dust. Conclusions. This paper illustrates the wide range of science questions that a single MIRI-MRS IFU data set can address. Our data suggest many similarities between low- and high-mass sources. Large source samples across evolutionary stages and luminosities are needed to further develop these diagnostics of the physics and chemistry of protostellar systems.

AB - Context. The embedded phase of star formation is a crucial period in the development of a young star when the system still accretes matter, emerges from its natal cloud with assistance from powerful jets and outflows, and forms a disk, thus setting the stage for the birth of a planetary system. The mid-infrared spectral line observations now possible with unprecedented sensitivity, spectral resolution, and sharpness from the James Webb Space Telescope (JWST) are key for probing many of the physical and chemical processes on subarcsecond scales that occur in highly extincted regions. They provide unique diagnostics and complement millimeter observations. Aims. The aim of the JWST Observations of Young protoStars (JOYS) program is to address a wide variety of topics ranging from protostellar accretion and the nature of primeval jets, winds, and outflows to the chemistry of gas and ice in hot cores and cold dense protostellar environments to the characteristics of the embedded disks. We introduce the JOYS program and show representative results. Methods. The JWST Mid-InfraRed Instrument (MIRI) Medium Resolution Spectrometer (MRS) Integral Field Unit (IFU) 5–28 µm maps of 17 low-mass targets (23 if binary components are counted individually) and six high-mass protostellar sources were taken with resolving powers R = λ/∆λ = 1500–4000. We used small mosaics ranging from 1 × 1 to 3 × 3 MRS tiles to cover ∼4′′ to 20′′ fields of view, providing spectral imaging on spatial scales down to ∼30 au (low mass) and ∼600 au (high mass). For HH 211, the complete ∼1′ blue outflow lobe was mapped with the MRS. Atomic lines were interpreted with published shock models, whereas molecular lines were analyzed with simple rotation diagrams and local thermodynamic equilibrium slab models. We stress the importance of taking infrared pumping into account. Inferred abundance ratios were compared with detailed hot core chemical models including X-rays, whereas ice spectra were fit through comparison with laboratory spectra. Results. The JWST MIRI-MRS spectra show a wide variety of features, with their spatial distribution providing key insight into their physical origin. The atomic line maps differ among refractory (e.g., Fe), semi-refractory (e.g., S), and volatile elements (e.g., Ne) and are linked to their different levels of depletion and local (shock) conditions. Jets are prominently seen in lines of [Fe II] and other refractory elements, whereas the pure rotational H2 lines probe hot (∼1000 K) and warm (few ×102 K) gas inside the cavity, as well as gas associated with jets, entrained outflows, and cavity walls for both low- and high-mass sources. Wide-angle winds are found in low-J H2 lines. Nested stratified jet structures containing an inner ionized core with an outer molecular layer are commonly seen in the youngest sources. While [S I] follows the jet as seen in [Fe II] in the youngest protostars, it is different in more evolved sources, where it is concentrated on source. Noble gas lines such as [Ne II] 12.8 µm reveal a mix of jet shock and photoionized emission. The H I recombination lines serve as a measure of protostellar accretion rates but are also associated with more extended jets. Gaseous molecular emission (CO2, C2H2, HCN, H2O, CH4, SO2, SiO) is seen toward several sources, but it is cool compared with what is found in more evolved disks, with excitation temperatures of only 100–250 K, and likely associated with the warm inner envelopes (“hot cores”) . Along the outflow, CO2 is often extended, thus contrasting with C2H2, which is usually centered on source. Water emission is commonly detected on source, even if relatively weak. Off source, it is seen only in the highest density shocks, such as those associated with NGC 1333 IRAS4B. Some sources show gaseous molecular lines in absorption, including NH3 in one case. Deep ice features are seen toward the protostars, revealing not just the major ice components but also ions (as part of salts) and complex organic molecules, with comparable abundances from low- to high-mass sources. The relative abundances of some gas and ice species are similar, which is consistent with ice sublimation in hot cores. We present a second detection of HDO ice in a solar-mass source, with an HDO/H2O ice ratio of ∼0.4%, thus providing a link with HDO/H2O in disks and comets. A deep search for solid O2 suggests that it is not a significant oxygen reservoir. Only a few embedded Class I disks show the same forest of water lines as Class II disks. This may be due to significant dust extinction of the upper layers in young disks caused by less settling of small dust as well as radial drift bringing in fresh dust. Conclusions. This paper illustrates the wide range of science questions that a single MIRI-MRS IFU data set can address. Our data suggest many similarities between low- and high-mass sources. Large source samples across evolutionary stages and luminosities are needed to further develop these diagnostics of the physics and chemistry of protostellar systems.

KW - ISM: atoms

KW - ISM: jets and outflows

KW - ISM: molecules

KW - methods: laboratory: solid state

KW - stars: formation

UR - https://www.scopus.com/pages/publications/105011725617

UR - https://ui.adsabs.harvard.edu/abs/2025A%26A...699A.361V/abstract

U2 - 10.1051/0004-6361/202554444

DO - 10.1051/0004-6361/202554444

M3 - Article

AN - SCOPUS:105011725617

SN - 0004-6361

VL - 699

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

M1 - A361

ER -

JWST Observations of Young protoStars (JOYS) Overview of program and early results

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Austrian Fields of Science 2012

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