Volume Density Structure of the Central Molecular Zone NGC 253 through ALCHEMI Excitation Analysis

Tanaka, Kunihiko; Mangum, Jeffrey G.; Viti, Serena; Martín, Sergio; Harada, Nanase; Sakamoto, Kazushi; Muller, Sebastien; Yoshimura, Yuki; Nakanishi, Kouichiro; Herrero-Illana, Rubén; Emig, Kimberly L.; Mühle, S.; Kaneko, Hiroyuki; Tosaki, Tomoka; Behrens, Erica; Rivilla, Víctor M.; Colzi, Laura; Nishimura, Yuri; Humire, P. K.; Bouvier, Mathilde; Huang, Ko-Yun; Butterworth, Joshua; Meier, David S.; van der Werf, Paul P.

doi:10.3847/1538-4357/ad0e64

Cited by 3 publications

(8 citation statements)

References 100 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Here, we examine whether each PC has any clear relationship with physical parameters such as column densities, kinetic temperatures, and volume densities. Figure 26 shows the relationship between the PC scores in our results and physical conditions derived by Tanaka et al (2024) from the ALCHEMI data. These physical parameters were obtained from the hierarchical Bayesian analysis method developed by Tanaka et al (2018).…”

Section: Relationship With Physical Parametersmentioning

confidence: 94%

“…For example, it takes ∼10 6 yr for a cloud to move 100 pc if it is moving with a velocity of 100 km s −1 , a few times the freefall time of a cloud with n = 10 4 cm −3 . Note, though, that the star formation threshold is likely higher in the CMZ of NGC 253 than that in the Galactic center and the Galactic disk (Tanaka et al 2024).…”

Section: Dense Gas Tracers and Star Formationmentioning

confidence: 96%

“…These physical parameters were obtained from the hierarchical Bayesian analysis method developed by Tanaka et al (2018). Tanaka et al (2024) present results from different sets of transitions. Among their results, we use their "high-HB" model derived from species with higher critical densities such as HCN, HCO + , and their isotopologues, HC 3 N, and SiO, instead of results derived from CO isotopologues.…”

Section: Relationship With Physical Parametersmentioning

confidence: 99%

“…These results suggest that PC1 primarily represents the overall molecular gas content. The volume densities tend to be higher in high-column-density regions in Tanaka et al (2024), and this is likely why PC1 and the volume densities have a positive correlation. The high-density regions are also the regions with high star formation rates, which explains the trend of increasing PC1 scores with increasing temperatures.…”

Section: Relationship With Physical Parametersmentioning

confidence: 99%

“…This survey also made the first extragalactic detection of a phosphorus-bearing molecule, phosphorus nitride (Haasler et al 2022). Tanaka et al (2024) make use of the multitransition and multimolecule data to accurately map the physical conditions (gas densities, temperatures, and molecular column densities) using hierarchical Bayesian analysis and found high densities compared to those in the center of our own Galaxy.…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

The ALCHEMI Atlas: Principal Component Analysis Reveals Starburst Evolution in NGC 253

Harada,

Meier,

Martín

et al. 2024

ApJS

Self Cite

View full text Add to dashboard Cite

Molecular lines are powerful diagnostics of the physical and chemical properties of the interstellar medium (ISM). These ISM properties, which affect future star formation, are expected to differ in starburst galaxies from those of more quiescent galaxies. We investigate the ISM properties in the central molecular zone of the nearby starburst galaxy NGC 253 using the ultrawide millimeter spectral scan survey from the Atacama Large Millimeter/submillimeter Array Large Program ALCHEMI. We present an atlas of velocity-integrated images at a 1.″6 resolution of 148 unblended transitions from 44 species, including the first extragalactic detection of HCNH+ and the first interferometric images of C3H+, NO, and HCS+. We conduct a principal component analysis (PCA) on these images to extract correlated chemical species and to identify key groups of diagnostic transitions. To the best of our knowledge, our data set is currently the largest astronomical set of molecular lines to which PCA has been applied. The PCA can categorize transitions coming from different physical components in NGC 253 such as (i) young starburst tracers characterized by high-excitation transitions of HC3N and complex organic molecules versus tracers of on-going star formation (radio recombination lines) and high-excitation transitions of CCH and CN tracing photodissociation regions, (ii) tracers of cloud-collision-induced shocks (low-excitation transitions of CH3OH, HNCO, HOCO+, and OCS) versus shocks from star formation-induced outflows (high-excitation transitions of SiO), as well as (iii) outflows showing emission from HOC+, CCH, H3O+, CO isotopologues, HCN, HCO+, CS, and CN. Our findings show these intensities vary with galactic dynamics, star formation activities, and stellar feedback.

show abstract

Section: Relationship With Physical Parametersmentioning

confidence: 94%

Section: Dense Gas Tracers and Star Formationmentioning

confidence: 96%

Section: Relationship With Physical Parametersmentioning

confidence: 99%

Section: Relationship With Physical Parametersmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

The ALCHEMI Atlas: Principal Component Analysis Reveals Starburst Evolution in NGC 253

Harada,

Meier,

Martín

et al. 2024

ApJS

Self Cite

View full text Add to dashboard Cite

show abstract

Physical properties of the southwest outflow streamer in the starburst galaxy NGC 253 with ALCHEMI

Bao,

Harada,

Kohno

et al. 2024

A&A

View full text Add to dashboard Cite

The physical properties of galactic molecular outflows are important as they could constrain outflow formation mechanisms. In this work, we study the properties of the southwest (SW) outflow streamer including gas kinematics, optical depth, dense gas fraction, and shock strength through molecular emission in the central molecular zone of the starburst galaxy NGC 253. We imaged the molecular emission in NGC 253 at a spatial resolution of 1.6$^ prime $(sim 27\,pc at Dsim 3.5\,Mpc) based on data from the ALMA Comprehensive High-resolution Extragalactic Molecular Inventory (ALCHEMI) large program. We traced the velocity and velocity dispersion of molecular gas with the CO(1-0) line and studied the molecular spectra in the region of the SW streamer, the brightest CO streamer in NGC 253. We constrained the optical depth of the CO emission with the CO/13CO(1-0) ratio, the dense gas fraction with the HCN/CO(1-0), H13CN/13CO(1-0) and $H$^ $/13CO(1-0) ratios, as well as the shock strength with the SiO(2-1)/13CO(1-0) and CH$_ $OH(2$_ k k $)/13CO(1-0) ratios. The CO/13CO(1-0) integrated intensity ratio is sim 21 in the SW streamer region, which approximates the C/13C isotopic abundance ratio. The higher integrated intensity ratio compared to the disk can be attributed to the optically thinner environment of CO(1-0) emission inside the SW streamer. The HCN/CO(1-0) and SiO(2-1)/13CO(1-0) integrated intensity ratios both approach sim 0.2 in three giant molecular clouds (GMCs) at the base of the outflow streamers, which implies a higher dense gas fraction and strength of fast shocks in those GMCs than in the disk, while the HCN/CO(1-0) integrated intensity ratio is moderate in the SW streamer region. The contours of those two integrated intensity ratios are extended in the directions of outflow streamers, which connect the enhanced dense gas fraction and shock strength with molecular outflow. Moreover, the molecular gas with an enhanced dense gas fraction and shock strength located at the base of the SW streamer shares the same velocity as the outflow. The enhanced dense gas fraction and shock strength at the base of the outflow streamers suggest that star formation inside the GMCs can trigger shocks and further drive the molecular outflow. The increased CO/13CO(1-0) integrated intensity ratio coupled with the moderate HCN/CO(1-0) integrated intensity ratio in the SW streamer region are consistent with the picture that the gas velocity gradient inside the streamer may decrease the optical depth of CO(1-0) emission, as well as the dense gas fraction in the extended streamer region.

show abstract

A Temperature or Far-ultraviolet Tracer? The HNC/HCN Ratio in M83 on the Scale of Giant Molecular Clouds

Harada,

Saito,

Nishimura

et al. 2024

ApJ

Self Cite

View full text Add to dashboard Cite

The HNC/HCN ratio is observationally known as a thermometer in Galactic interstellar molecular clouds. A recent study has alternatively suggested that the HNC/HCN ratio is affected by the ultraviolet (UV) field, not by the temperature. We aim to study this ratio on the scale of giant molecular clouds in the barred spiral galaxy M83 towards the southwestern bar end and the central region from Atacama Large Millimeter/submillimeter Array observations, and if possible, distinguish the above scenarios. We compare the high-resolution (40–50 pc) HNC/HCN ratios with the star formation rate from the 3 mm continuum intensity and the molecular mass inferred from the HCN intensities. Our results show that the HNC/HCN ratios do not vary with the star formation rates, star formation efficiencies, or column densities in the bar-end region. In the central region, the HNC/HCN ratios become higher with higher star formation rates, which tend to cause higher temperatures. This result is not consistent with the previously proposed scenario in which the HNC/HCN ratio decreases with increasing temperature. Spectral shapes suggest that this trend may be due to optically thick HCN and optically thin HNC. In addition, we compare the large-scale (∼200 pc) correlation between the dust temperature from the far-IR ratio and the HNC/HCN ratio for the southwestern bar-end region. The HNC/HCN ratio is lower when the dust temperatures are higher. We suggest from the above results that the HNC/HCN ratio depends on the UV radiation field that affects the interstellar medium on the ∼100 pc scale where the column densities are low.

show abstract

Volume Density Structure of the Central Molecular Zone NGC 253 through ALCHEMI Excitation Analysis

Cited by 3 publications

References 100 publications

The ALCHEMI Atlas: Principal Component Analysis Reveals Starburst Evolution in NGC 253

The ALCHEMI Atlas: Principal Component Analysis Reveals Starburst Evolution in NGC 253

Physical properties of the southwest outflow streamer in the starburst galaxy NGC 253 with ALCHEMI

A Temperature or Far-ultraviolet Tracer? The HNC/HCN Ratio in M83 on the Scale of Giant Molecular Clouds

Contact Info

Product

Resources

About