A Systematic Observational Study on Galactic Interstellar Ratio 18O/17O. I. C18O and C17O J = 1–0 Data Analysis

Zhang, J. S.; Liu, W.; Yan, Y. T.; Yu, H. Z.; Liu, J. T.; Zheng, Yao; Romano, D.; Zhang, Z.-Y.; Wang, J. Z.; Chen, J. L.; Wang, Y. X.; Zhang, W. J.; Lu, Huanlang; Chen, L. S.; Zou, Y. P.; Yang, Huan; Wen, Tao; Lu, Fangjun

doi:10.3847/1538-4365/ab9112

Cited by 13 publications

(3 citation statements)

References 48 publications

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“…Alternatively, from a statistical perspective, this finding may trace the overall evolution of our Galaxy and supports the inside-out formation scenario of our Galaxy (see Zhang et al 2020, and references therein), since the 12.2 GHz methanol masers usually appear later than the 6.7 GHz methanol masers from the evolutionary stages of interstellar masers during the massive star formation outlined by Breen et al (2010b). It can be further explored by combining the measurements of the Galactic gradient of isotopic ratios using particular molecules (e.g., C, N, O, and S; see Yan et al 2019;Yu et al 2020;Zhang et al 2020) for sources a certain arm.…”

Section: Galactic Structures Traced By the Observed Samplementioning

confidence: 99%

A 12.2 GHz Methanol Maser Survey toward the 6.7 GHz Counterparts Associated with/without UC H ii Regions

Song

Chen

Shen

et al. 2022

ApJS

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We report a new survey of the 12.2 GHz Class II methanol masers toward a sample of 367 sources with the 6.7 GHz methanol masers conducted with the Shanghai 65 m Tianma Radio Telescope. This sample has been previously made with observations of the radio continuum emission of UC H ii regions by the VLA. A total of 176 sources were detected with the 12.2 GHz methanol maser, with a detection rate of 48%, including 8 new detections. A lower detection rate (<10%) was determined toward the sources in the Galactic longitude ranges of 60°–180°, revealing that the physical environments from those sources in the Local arm or the tails of Galactic arms do not easily excite the 12.2 GHz masers. In addition, two detections of highly excited-state OH masers at the 13.4 GHz transition were made, one of which is a new detection. Compared to previous surveys, one-third of the detected 12.2 GHz masers show considerable flux variations, implying the possible changes of their physical environments associated with variable radiation fields from their host high-mass young stellar objects. A positive log–log correlation is found between the luminosities of the 6.7 and 12.2 GHz masers in our observed sample, suggesting that both the transition masers have similar excitation conditions. The statistical analysis for the relationships between the methanol maser luminosity and UC H ii region spatial size indicates that the maser luminosities of both the 6.7 and 12.2 GHz transitions have a decreasing trend with the spatial sizes of the associated UC H ii regions, indicating that the Class II methanol masers might fade away with the H ii region evolution.

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Section: Galactic Structures Traced By the Observed Samplementioning

confidence: 99%

A 12.2 GHz Methanol Maser Survey toward the 6.7 GHz Counterparts Associated with/without UC H ii Regions

Song

Chen

Shen

et al. 2022

ApJS

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“…Briefly, 18 O is primarily synthesized in massive stars, while 17 O is predominantly ejected by intermediate-mass stars through a longer production timescale. This can lead to a mildly positive gradient of 18 O/ 17 O throughout the disk, assuming an inside-out formation scenario for our Galaxy (see the detailed description in Zhang et al 2020). Recent theoretical results mainly based on numerical calculations suggest a complex interdependence of the yields on mass, metallicity, and rotation of the stars.…”

Section: Introductionmentioning

confidence: 82%

A Systematic Observational Study on Galactic Interstellar Ratio ¹⁸O/¹⁷O. II. C¹⁸O and C¹⁷O J = 2–1 Data Analysis

Zou 邹,

Zhang 张,

Henkel

et al. 2023

ApJS

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To investigate the relative amount of ejecta from high-mass versus intermediate-mass stars and to trace the chemical evolution of the Galaxy, we have performed a systematic study of Galactic interstellar 18O/17O ratios toward a sample of 421 molecular clouds with IRAM 30 m and the 10 m Submillimeter Telescope, covering a galactocentric distance range of ∼1–22 kpc. The results presented in this paper are based on the J = 2–1 transition and encompass 364 sources showing both C18O and C17O detections. The previously suggested 18O/17O gradient is confirmed. For the 41 sources detected with both facilities, good agreement is obtained. A correlation of the 18O/17O ratios with heliocentric distance is not found, indicating that beam dilution and linear beam sizes are not relevant. For the subsample of IRAM 30 m high-mass star-forming regions with accurate parallax distances, an unweighted fit gives 18O/17O = (0.12 ± 0.02)R GC + (2.38 ± 0.13) with a correlation coefficient of R = 0.67. While the slope is consistent with our J = 1–0 measurement, the ratios are systematically lower. This should be caused by larger optical depths of C18O 2–1 lines with respect to the corresponding 1–0 transitions, which is supported by RADEX calculations and the fact that C18O/C17O is positively correlated with 13CO/C18O. When we consider that optical depth effects with C18O J = 2–1 typically reach an optical depth of ∼0.5, the corrected 18O/17O ratios from the J = 1–0 and J = 2–1 lines are consistent. A good numerical fit to the data is provided by the MWG-12 model, which includes both rotating stars and novae.

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“…Nowadays, the increased sensitivity and high spectral resolution of millimeter telescopes allow to reach far outer Galactic disc regions and probe their low-metallicity ISM. This provides unique information on the synthesis of the minor CNO isotopes in metalpoor environments (see Romano et al 2017Romano et al , 2019bZhang et al 2020;Fontani et al 2022). Spectroscopy of unevolved stars, in fact, provides only fragments of the local enrichment histories of 12 C= 13 C and 16 O= 18 O (see Fig.…”

Section: The Milky Way Galaxymentioning

confidence: 99%

The evolution of CNO elements in galaxies

Romano

2022

Astron Astrophys Rev

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After hydrogen and helium, oxygen, carbon, and nitrogen—hereinafter, the CNO elements—are the most abundant species in the universe. They are observed in all kinds of astrophysical environments, from the smallest to the largest scales, and are at the basis of all known forms of life, hence, the constituents of any biomarker. As such, their study proves crucial in several areas of contemporary astrophysics, extending to astrobiology. In this review, I will summarize current knowledge about CNO element evolution in galaxies, starting from our home, the Milky Way. After a brief recap of CNO synthesis in stars, I will present the comparison between chemical evolution model predictions and observations of CNO isotopic abundances and abundance ratios in stars and in the gaseous matter. Such a comparison permits to constrain the modes and time scales of the assembly of galaxies and their stellar populations, as well as stellar evolution and nucleosynthesis theories. I will stress that chemical evolution models must be carefully calibrated against the wealth of abundance data available for the Milky Way before they can be applied to the interpretation of observational datasets for other systems. In this vein, I will also discuss the usefulness of some key CNO isotopic ratios as probes of the prevailing, galaxy-wide stellar initial mass function in galaxies where more direct estimates from the starlight are unfeasible.

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A Systematic Observational Study on Galactic Interstellar Ratio ¹⁸O/¹⁷O. I. C¹⁸O and C¹⁷O J = 1–0 Data Analysis

Cited by 13 publications

References 48 publications

A 12.2 GHz Methanol Maser Survey toward the 6.7 GHz Counterparts Associated with/without UC H ii Regions

A 12.2 GHz Methanol Maser Survey toward the 6.7 GHz Counterparts Associated with/without UC H ii Regions

A Systematic Observational Study on Galactic Interstellar Ratio ¹⁸O/¹⁷O. II. C¹⁸O and C¹⁷O J = 2–1 Data Analysis

The evolution of CNO elements in galaxies

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A Systematic Observational Study on Galactic Interstellar Ratio 18O/17O. I. C18O and C17O J = 1–0 Data Analysis

Cited by 13 publications

References 48 publications

A 12.2 GHz Methanol Maser Survey toward the 6.7 GHz Counterparts Associated with/without UC H ii Regions

A 12.2 GHz Methanol Maser Survey toward the 6.7 GHz Counterparts Associated with/without UC H ii Regions

A Systematic Observational Study on Galactic Interstellar Ratio 18O/17O. II. C18O and C17O J = 2–1 Data Analysis

The evolution of CNO elements in galaxies

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A Systematic Observational Study on Galactic Interstellar Ratio ¹⁸O/¹⁷O. I. C¹⁸O and C¹⁷O J = 1–0 Data Analysis

A Systematic Observational Study on Galactic Interstellar Ratio ¹⁸O/¹⁷O. II. C¹⁸O and C¹⁷O J = 2–1 Data Analysis