THE JET AND ARC MOLECULAR CLOUDS TOWARD WESTERLUND 2, RCW 49, AND HESS J1023–575;12CO AND13CO (J= 2-1 andJ= 1-0) OBSERVATIONS WITH NANTEN2 AND MOPRA TELESCOPE

Furukawa, N.; Ohama, Akio; Fukuda, Tatsuya; Torii, Kazufumi; Hayakawa, Takahiro; Sano, Hidetoshi; Okuda, Takeshi; Yamamoto, Hiroaki; Moribe, N.; Mizuno, Akira; Maezawa, Hiroyuki; Onishi, Toshikazu; Kawamura, Akiko; Mizuno, N.; Dawson, J. R.; Dame, T. M.; Yonekura, Yoshinori; Aharonian, F.; Oña-Wilhelmi, E.; Rowell, G.; Matsumoto, Ryoji; Asahina, Yuta; Fukui, Y.

doi:10.1088/0004-637x/781/2/70

Cited by 13 publications

(27 citation statements)

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“…The studies of the CO emission spectrum in combination with the 21 cm absorption spectrum by Dame (2007) suggest that Wd2 must be located in between two molecular clouds. Wd2 was studied in more detail by Furukawa et al (2009Furukawa et al ( , 2014 and Ohama et al (2010) using the NAN-TEN 2 4m submillimeter/millimeter telescope (from the NANTEN CO Galactic Plane Survey, Mizuno & Fukui 2004) in combination with Spitzer data. They detected three different CO clouds with 3 different velocities (16, 4, and −4 km s −1 , relative to the local standard of rest (LSR), see Fig.…”

Section: The 12 Co and 13 Co Transition Linesmentioning

confidence: 99%

“…Using the rotation curve of Brand & Blitz (1993), Furukawa et al (2009) obtained kinematic distances of 6.5, 5.2, and 4.0 kpc for the 16, 4, and −4 km s −1 clouds, respectively. Furukawa et al (2009Furukawa et al ( , 2014 and Ohama et al (2010) also suggested that the creation of the RCW 49 region, with the Wd2 cluster as its central ionizing cluster, was induced by a cloud-cloud collision of two of these observed molecular clouds. This collision may have caused the formation of the spatially uniformly distributed low-mass PMS stars that we see in our HST data.…”

Section: The 12 Co and 13 Co Transition Linesmentioning

confidence: 99%

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A High-resolution Multiband Survey of Westerlund 2 with the Hubble Space Telescope. III. The Present-day Stellar Mass Function

Zeidler

Nota

Grebel

et al. 2017

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We present a detailed analysis of the spatial distribution of the stellar population and the present-day mass function (PDMF) of the Westerlund 2 (Wd2) region using the data from our high resolution multi-band survey with the Hubble Space Telescope. We used state-of-the-art artificial star tests to determine spatially resolved completeness maps for each of the broad-band filters. We reach a level of completeness of 50% down to F 555W = 24.8 mag (0.7 M ⊙ ) and F 814W = 23.3 mag (0.2 M ⊙ ) in the optical and F 125W = 20.2 mag and F 160W = 19.4 mag (both 0.12 M ⊙ ) in the infrared throughout the field of view. We had previously reported that the core of Wd2 consists of two clumps: namely the main cluster (MC) and the northern clump (NC). From the spatial distribution of the completeness corrected population, we find that their stellar surface densities are 1114 stars pc −2 and 555 stars pc −2 , respectively, down to F 814W = 21.8 mag. We find that the present-day mass function (PDMF) of Wd2 has a slope of Γ = −1.46 ± 0.06, which translates to a total stellar cluster mass of (3.6 ± 0.3) · 10 4 M ⊙ . The spatial analysis of the PDMF reveals that the cluster population is mass-segregated, most likely primordial. In addition, we report the detection of a stellar population of spatially uniformly distributed low-mass (< 0.15 M ⊙ ) stars, extending into the gas ridges of the surrounding gas and dust cloud, as well as a confined region of reddened stars, likely caused by a foreground CO cloud. We find hints that a cloud-cloud collision might be the origin of the formation of Wd2.

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Section: The 12 Co and 13 Co Transition Linesmentioning

confidence: 99%

Section: The 12 Co and 13 Co Transition Linesmentioning

confidence: 99%

A High-resolution Multiband Survey of Westerlund 2 with the Hubble Space Telescope. III. The Present-day Stellar Mass Function

Zeidler

Nota

Grebel

et al. 2017

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“…Let us compare our results with CO observations (Furukawa et al 2014). The velocity dispersion of the molecular clouds formed by the jet-cloud interaction depends on the jet speed.…”

Section: Summary and Discussionmentioning

confidence: 70%

“…HESS J1023-575 is observed both at the high energy band (above 2.5 TeV) and the low energy band (0.7 − 2.5 TeV). The cooling by the pp-interaction and diffusion time scales of the relativistic particles are estimated to be about 5 × 10 6 yr and 2 × 10 4 yr, respectively, by Furukawa et al (2014). If the arc and the jet clouds and TeV γ-ray source are produced by a single object, a supernova remnant or a pulsar wind nebulae is not likely as the origin for TeV γ-ray source since the diffusion time scale of the relativistic particles is shorter than the age of the arc and jet clouds (∼ Myr).…”

Section: Summary and Discussionmentioning

confidence: 99%

Magnetohydrodynamic Simulations of the Formation of Molecular Clouds toward the Stellar Cluster Westerlund 2: Interaction of a Jet with a Clumpy Interstellar Medium

Asahina

Kawashima

Furukawa

et al. 2017

ApJ

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The formation mechanism of CO clouds observed with NANTEN2 and Mopra telescope toward the stellar cluster Westerlund 2 is studied by three-dimensional magnetohydrodynamic (MHD) simulations taking into account the interstellar cooling. These molecular clouds show a peculiar shape composing of an arcshaped cloud in one side of a TeV γ-ray source HESS J1023-575 and a linear distribution of clouds (jet clouds) in another side. We propose that these clouds are formed by the interaction of a jet with interstellar neutral hydrogen (HI) clumps. By studying the dependence of the shape of dense cold clouds formed by shock compression and cooling on the filling factor of HI clumps, we found that the density distribution of HI clumps determines the shape of molecular clouds formed by the jet-cloud interaction; arc-clouds are formed when the filling factor is large. On the other hand, when the filling factor is small, molecular clouds align with the jet. The jet propagates faster in models with small filling factors.

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“…The reduced maps (FITS files) are only available at the CDS via anonymous ftp to cdsarc.u-strasbg.fr (130.79.128.5) or via http://cdsarc.u-strasbg.fr/viz-bin/qcat?J/A+A/617/A77 in many environments, for instance, in photodissociation regions (PDRs), protoplanetary disks, young stellar objects (YSOs; Martín et al 2009;Sturm et al 2010;Furukawa et al 2014), and different extragalactic environments, such as low surface brightness galaxies, high-redshift galaxies, and ultra-luminous infrared galaxies (ULIRGs;O'Neil et al 2000;Schleicher et al 2010;Papadopoulos et al 2010).…”

Section: Introductionmentioning

confidence: 99%

High-J CO emission spatial distribution and excitation in the Orion Bar

Parikka

Habart

Bernard─Salas

et al. 2018

A&A

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Context. With Herschel, we can for the first time observe a wealth of high-J CO lines in the interstellar medium with a high angular resolution. These lines are specifically useful for tracing the warm and dense gas and are therefore very appropriate for a study of strongly irradiated dense photodissocation regions (PDRs). Aims. We characterize the morphology of CO J = 19-18 emission and study the high-J CO excitation in a highly UV-irradiated prototypical PDR, the Orion Bar. Methods. We used fully sampled maps of CO J = 19-18 emission with the Photoconductor Array Camera and Spectrometer (PACS) on board the Herschel Space Observatory over an area of ∼110 × 110 with an angular resolution of 9 . We studied the morphology of this high-J CO line in the Orion Bar and in the region in front and behind the Bar, and compared it with lower-J lines of CO from J = 5-4 to J = 13-12 and 13 CO from J = 5-4 to J = 11-10 emission observed with the Herschel Spectral and Photometric Imaging Receiver (SPIRE). In addition, we compared the high-J CO to polycyclic aromatic hydrocarbon (PAH) emission and vibrationally excited H 2 . We used the CO and 13 CO observations and the RADEX model to derive the physical conditions in the warm molecular gas layers. Results. The CO J = 19-18 line is detected unambiguously everywhere in the observed region, in the Bar, and in front and behind of it. In the Bar, the most striking features are several knots of enhanced emission that probably result from column and/or volume density enhancements. The corresponding structures are most likely even smaller than what PACS is able to resolve. The high-J CO line mostly arises from the warm edge of the Orion Bar PDR, while the lower-J lines arise from a colder region farther inside the molecular cloud. Even if it is slightly shifted farther into the PDR, the high-J CO emission peaks are very close to the H/H 2 dissociation front, as traced by the peaks of H 2 vibrational emission. Our results also suggest that the high-J CO emitting gas is mainly excited by photoelectric heating. The CO J = 19-18/J = 12-11 line intensity ratio peaks in front of the CO J = 19-18 emission between the dissociation and ionization fronts, where the PAH emission also peak. A warm or hot molecular gas could thus be present in the atomic region where the intense UV radiation is mostly unshielded. In agreement with recent ALMA detections, low column densities of hot molecular gas seem to exist between the ionization and dissociation fronts. As found in other studies, the best fit with RADEX modeling for beam-averaged physical conditions is for a density of 10 6 cm −3 and a high thermal pressure (P/k = n H × T ) of ∼1-2 × 10 8 K cm −3 . Conclusions. The high-J CO emission is concentrated close to the dissociation front in the Orion Bar. Hot CO may also lie in the atomic PDR between the ionization and dissociation fronts, which is consistent with the dynamical and photoevaporation effects.

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THE JET AND ARC MOLECULAR CLOUDS TOWARD WESTERLUND 2, RCW 49, AND HESS J1023–575;¹²CO AND¹³CO (J= 2-1 andJ= 1-0) OBSERVATIONS WITH NANTEN2 AND MOPRA TELESCOPE

Cited by 13 publications

References 83 publications

A High-resolution Multiband Survey of Westerlund 2 with the Hubble Space Telescope. III. The Present-day Stellar Mass Function

A High-resolution Multiband Survey of Westerlund 2 with the Hubble Space Telescope. III. The Present-day Stellar Mass Function

Magnetohydrodynamic Simulations of the Formation of Molecular Clouds toward the Stellar Cluster Westerlund 2: Interaction of a Jet with a Clumpy Interstellar Medium

High-J CO emission spatial distribution and excitation in the Orion Bar

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