A Turbulent Origin for the Complex Envelope Kinematics in the Young Low-mass Core Per-bolo 58
We use CARMA 3 mm continuum and molecular lines (NH2D, N2H+, HCO+, HCN, and CS) at ∼1000 au resolution to characterize the structure and kinematics of the envelope surrounding the deeply embedded first core candidate Per-bolo 58. The line profile of the observed species shows two distinct peaks sepa...
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| Veröffentlicht in: | The Astrophysical journal 2017-11, Vol.849 (2), p.89 |
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| creator | José Maureira, María Arce, Héctor G. Offner, Stella S. R. Dunham, Michael M. Pineda, Jaime E. Fernández-López, Manuel Chen, Xuepeng Mardones, Diego |
| description | We use CARMA 3 mm continuum and molecular lines (NH2D, N2H+, HCO+, HCN, and CS) at ∼1000 au resolution to characterize the structure and kinematics of the envelope surrounding the deeply embedded first core candidate Per-bolo 58. The line profile of the observed species shows two distinct peaks separated by 0.4-0.6 km s−1, which most likely arise from two different optically thin velocity components rather than the product of self-absorption in an optically thick line. The two velocity components, each with a mass of ∼0.5-0.6 , overlap spatially at the position of the continuum emission and produce a general gradient along the outflow direction. We investigate whether these observations are consistent with infall in a turbulent and magnetized envelope. We compare the morphology and spectra of the N2H+ (1-0) with synthetic observations of an MHD simulation that considers the collapse of an isolated core that is initially perturbed with a turbulent field. The proposed model matches the data in the production of two velocity components, traced by the isolated hyperfine line of the N2H+ (1-0) spectra, and shows a general agreement in morphology and velocity field. We also use large maps of the region to compare the kinematics of the core with that of the surrounding large-scale filamentary structure and find that accretion from the large-scale filament could also explain the complex kinematics exhibited by this young dense core. |
| doi_str_mv | 10.3847/1538-4357/aa91ce |
| format | Article |
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R. ; Dunham, Michael M. ; Pineda, Jaime E. ; Fernández-López, Manuel ; Chen, Xuepeng ; Mardones, Diego</creator><creatorcontrib>José Maureira, María ; Arce, Héctor G. ; Offner, Stella S. R. ; Dunham, Michael M. ; Pineda, Jaime E. ; Fernández-López, Manuel ; Chen, Xuepeng ; Mardones, Diego</creatorcontrib><description>We use CARMA 3 mm continuum and molecular lines (NH2D, N2H+, HCO+, HCN, and CS) at ∼1000 au resolution to characterize the structure and kinematics of the envelope surrounding the deeply embedded first core candidate Per-bolo 58. The line profile of the observed species shows two distinct peaks separated by 0.4-0.6 km s−1, which most likely arise from two different optically thin velocity components rather than the product of self-absorption in an optically thick line. The two velocity components, each with a mass of ∼0.5-0.6 , overlap spatially at the position of the continuum emission and produce a general gradient along the outflow direction. We investigate whether these observations are consistent with infall in a turbulent and magnetized envelope. We compare the morphology and spectra of the N2H+ (1-0) with synthetic observations of an MHD simulation that considers the collapse of an isolated core that is initially perturbed with a turbulent field. The proposed model matches the data in the production of two velocity components, traced by the isolated hyperfine line of the N2H+ (1-0) spectra, and shows a general agreement in morphology and velocity field. We also use large maps of the region to compare the kinematics of the core with that of the surrounding large-scale filamentary structure and find that accretion from the large-scale filament could also explain the complex kinematics exhibited by this young dense core.</description><identifier>ISSN: 0004-637X</identifier><identifier>EISSN: 1538-4357</identifier><identifier>DOI: 10.3847/1538-4357/aa91ce</identifier><language>eng</language><publisher>Philadelphia: The American Astronomical Society</publisher><subject>Astrophysics ; Computer simulation ; Continuum radiation ; Deposition ; Emission analysis ; ISM: individual objects (Per-bolo 58) ; Kinematics ; Morphology ; stars: formation ; stars: kinematics and dynamics ; stars: low-mass ; stars: protostars ; Velocity ; Velocity distribution</subject><ispartof>The Astrophysical journal, 2017-11, Vol.849 (2), p.89</ispartof><rights>2017. The American Astronomical Society. 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The two velocity components, each with a mass of ∼0.5-0.6 , overlap spatially at the position of the continuum emission and produce a general gradient along the outflow direction. We investigate whether these observations are consistent with infall in a turbulent and magnetized envelope. We compare the morphology and spectra of the N2H+ (1-0) with synthetic observations of an MHD simulation that considers the collapse of an isolated core that is initially perturbed with a turbulent field. The proposed model matches the data in the production of two velocity components, traced by the isolated hyperfine line of the N2H+ (1-0) spectra, and shows a general agreement in morphology and velocity field. We also use large maps of the region to compare the kinematics of the core with that of the surrounding large-scale filamentary structure and find that accretion from the large-scale filament could also explain the complex kinematics exhibited by this young dense core.</description><subject>Astrophysics</subject><subject>Computer simulation</subject><subject>Continuum radiation</subject><subject>Deposition</subject><subject>Emission analysis</subject><subject>ISM: individual objects (Per-bolo 58)</subject><subject>Kinematics</subject><subject>Morphology</subject><subject>stars: formation</subject><subject>stars: kinematics and dynamics</subject><subject>stars: low-mass</subject><subject>stars: protostars</subject><subject>Velocity</subject><subject>Velocity distribution</subject><issn>0004-637X</issn><issn>1538-4357</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2017</creationdate><recordtype>article</recordtype><recordid>eNp9kEtLxDAURoMoOI7uXQZ0aZy0SZtkOQzjAwfGxQi6kJC2ydihbWLS-vj3tlR0I64u93K-78IB4DTCl4RTNosSwhElCZspJaJc74HJz2kfTDDGFKWEPR6CoxB2wxoLMQHPc7jpfNZVumnh2pfbsoHGeti-aLiwtav0B1w2b7qyTsO7stG1ass8wB4bkCfbNVu4su-oViH0Ca_hvfYos5WFCT8GB0ZVQZ98zyl4uFpuFjdotb6-XcxXKKc0aRHNGcmYiguRKppF1KQKG6wKg03BBOZJrDgWGJOMxIanjKUpMVnPR4RnShkyBWdjr_P2tdOhlTvb-aZ_KWOSJpzGieA9hUcq9zYEr410vqyV_5QRloNEORiTgzE5SuwjF2OktO638x_8_A9cuZ3kVMhYciFdYcgXFSd_FQ</recordid><startdate>20171110</startdate><enddate>20171110</enddate><creator>José Maureira, María</creator><creator>Arce, Héctor G.</creator><creator>Offner, Stella S. 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| subjects | Astrophysics Computer simulation Continuum radiation Deposition Emission analysis ISM: individual objects (Per-bolo 58) Kinematics Morphology stars: formation stars: kinematics and dynamics stars: low-mass stars: protostars Velocity Velocity distribution |
| title | A Turbulent Origin for the Complex Envelope Kinematics in the Young Low-mass Core Per-bolo 58 |
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