TY - JOUR
T1 - JWST observations of 13CO2ice
T2 - Tracing the chemical environment and thermal history of ices in protostellar envelopes
AU - Brunken, Nashanty G.C.
AU - Rocha, Will R.M.
AU - Van Dishoeck, Ewine F.
AU - Gutermuth, Robert
AU - Tyagi, Himanshu
AU - Slavicinska, Katerina
AU - Nazari, Pooneh
AU - Megeath, S. Thomas
AU - Evans, Neal J.
AU - Narang, Mayank
AU - Manoj, P.
AU - Rubinstein, Adam E.
AU - Watson, Dan M.
AU - Looney, Leslie W.
AU - Linnartz, Harold
AU - Caratti O Garatti, Alessio
AU - Beuther, Henrik
AU - Linz, Hendrik
AU - Klaassen, Pamela
AU - Poteet, Charles A.
AU - Federman, Samuel
AU - Anglada, Guillem
AU - Atnagulov, Prabhani
AU - Bourke, Tyler L.
AU - Fischer, William J.
AU - Furlan, Elise
AU - Green, Joel
AU - Habel, Nolan
AU - Hartmann, Lee
AU - Karnath, Nicole
AU - Osorio, Mayra
AU - Muzerolle Page, James
AU - Pokhrel, Riwaj
AU - Rahatgaonkar, Rohan
AU - Sheehan, Patrick
AU - Stanke, Thomas
AU - Stutz, Amelia M.
AU - Tobin, John J.
AU - Tychoniec, Lukasz
AU - Wolk, Scott
AU - Yang, Yao Lun
N1 - Publisher Copyright:
© 2024 EDP Sciences. All rights reserved.
PY - 2024/5/1
Y1 - 2024/5/1
N2 - The structure and composition of simple ices can be severely modified during stellar evolution by protostellar heating. Key to understanding the involved processes are thermal and chemical tracers that can be used to diagnose the history and environment of the ice. The 15.2 μm bending mode of 12CO2 in particular has proven to be a valuable tracer of ice heating events but suffers from grain shape and size effects. A viable alternative tracer is the weaker 13CO2 isotopologue band at 4.39 μm, which has now become accessible at high S/N with the James Webb Space Telescope (JWST). In this study, we present JWST NIRSpec observations of 13CO2 ice in five deeply embedded Class 0 sources that span a wide range in masses and luminosities (0.2a "104 LaŠA ) taken as part of the Investigating Protostellar Accretion Across the Mass Spectrum (IPA) program. The band profiles vary significantly depending on the source, with the most luminous sources showing a distinct narrow peak at 4.38 μm. We first applied a phenomenological approach with which we demonstrate that a minimum of three to four Gaussian profiles are needed to fit the absorption feature of 13CO2. We then combined these findings with laboratory data and show that a 15.2 μm 12CO2 bending-mode-inspired five-component decomposition can be applied to the isotopologue band, with each component representative of CO2 ice in a specific molecular environment. The final solution consists of cold mixtures of CO2 with CH3OH, H2O, and CO as well as segregated heated pure CO2 ice at 80 K. Our results are in agreement with previous studies of the 12CO2 ice band, further confirming that 13CO2 is a useful alternative tracer of protostellar heating and ice composition. We also propose an alternative solution consisting only of heated mixtures of CO2:CH3OH and CO2:H2O ices and warm pure CO2 ice at 80 K (i.e., no cold CO2 ices) for decomposing the ice profiles of HOPS 370 and IRAS 20126, the two most luminous sources in our sample that show strong evidence of ice heating resulting in ice segregation.
AB - The structure and composition of simple ices can be severely modified during stellar evolution by protostellar heating. Key to understanding the involved processes are thermal and chemical tracers that can be used to diagnose the history and environment of the ice. The 15.2 μm bending mode of 12CO2 in particular has proven to be a valuable tracer of ice heating events but suffers from grain shape and size effects. A viable alternative tracer is the weaker 13CO2 isotopologue band at 4.39 μm, which has now become accessible at high S/N with the James Webb Space Telescope (JWST). In this study, we present JWST NIRSpec observations of 13CO2 ice in five deeply embedded Class 0 sources that span a wide range in masses and luminosities (0.2a "104 LaŠA ) taken as part of the Investigating Protostellar Accretion Across the Mass Spectrum (IPA) program. The band profiles vary significantly depending on the source, with the most luminous sources showing a distinct narrow peak at 4.38 μm. We first applied a phenomenological approach with which we demonstrate that a minimum of three to four Gaussian profiles are needed to fit the absorption feature of 13CO2. We then combined these findings with laboratory data and show that a 15.2 μm 12CO2 bending-mode-inspired five-component decomposition can be applied to the isotopologue band, with each component representative of CO2 ice in a specific molecular environment. The final solution consists of cold mixtures of CO2 with CH3OH, H2O, and CO as well as segregated heated pure CO2 ice at 80 K. Our results are in agreement with previous studies of the 12CO2 ice band, further confirming that 13CO2 is a useful alternative tracer of protostellar heating and ice composition. We also propose an alternative solution consisting only of heated mixtures of CO2:CH3OH and CO2:H2O ices and warm pure CO2 ice at 80 K (i.e., no cold CO2 ices) for decomposing the ice profiles of HOPS 370 and IRAS 20126, the two most luminous sources in our sample that show strong evidence of ice heating resulting in ice segregation.
KW - Astrochemistry
KW - ISM: molecules
KW - Stars: protostars
KW - Techniques: spectroscopic
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U2 - 10.1051/0004-6361/202348718
DO - 10.1051/0004-6361/202348718
M3 - Article
AN - SCOPUS:85192322909
SN - 0004-6361
VL - 685
JO - Astronomy and Astrophysics
JF - Astronomy and Astrophysics
M1 - A27
ER -