ALMA observations of starless core substructure in ophiuchus

H. Kirk; M. M. Dunham; J. Di Francesco; D. Johnstone; S. S.R. Offner; S. I. Sadavoy; J. J. Tobin; H. G. Arce; T. L. Bourke; S. Mairs; P. C. Myers; J. E. Pineda; S. Schnee; Y. L. Shirley

ALMA observations of starless core substructure in ophiuchus

H. Kirk, M. M. Dunham, J. Di Francesco, D. Johnstone, S. S.R. Offner, S. I. Sadavoy, J. J. Tobin, H. G. Arce, T. L. Bourke, S. Mairs, P. C. Myers, J. E. Pineda, S. Schnee, Y. L. Shirley

Astronomy

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Abstract

Compact substructure is expected to arise in a starless core as mass becomes concentrated in the central region likely to form a protostar. Additionally, multiple peaks may form if fragmentation occurs. We present ALMA Cycle 2 observations of 60 starless and protostellar cores in the Ophiuchus molecular cloud. We detect eight compact substructures which are > 15^′′ from the nearest Spitzer YSO. Only one of these has strong evidence for being truly starless after considering ancillary data, e.g., from Herschel and X-ray telescopes. An additional extended emission structure has tentative evidence for starlessness. The number of our detections is consistent with estimates from a combination of synthetic observations of numerical simulations and analytical arguments. This result suggests that a similar ALMA study in the Chamaeleon I cloud, which detected no compact substructure in starless cores, may be due to the peculiar evolutionary state of cores in that cloud.

Original language	English (US)
Journal	Unknown Journal
State	Published - Mar 1 2017

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@article{aa7af2537d42422899abd1cfe6f6b676,

title = "ALMA observations of starless core substructure in ophiuchus",

abstract = "Compact substructure is expected to arise in a starless core as mass becomes concentrated in the central region likely to form a protostar. Additionally, multiple peaks may form if fragmentation occurs. We present ALMA Cycle 2 observations of 60 starless and protostellar cores in the Ophiuchus molecular cloud. We detect eight compact substructures which are > 15′′ from the nearest Spitzer YSO. Only one of these has strong evidence for being truly starless after considering ancillary data, e.g., from Herschel and X-ray telescopes. An additional extended emission structure has tentative evidence for starlessness. The number of our detections is consistent with estimates from a combination of synthetic observations of numerical simulations and analytical arguments. This result suggests that a similar ALMA study in the Chamaeleon I cloud, which detected no compact substructure in starless cores, may be due to the peculiar evolutionary state of cores in that cloud.",

author = "H. Kirk and Dunham, {M. M.} and {Di Francesco}, J. and D. Johnstone and Offner, {S. S.R.} and Sadavoy, {S. I.} and Tobin, {J. J.} and Arce, {H. G.} and Bourke, {T. L.} and S. Mairs and Myers, {P. C.} and Pineda, {J. E.} and S. Schnee and Shirley, {Y. L.}",

year = "2017",

month = mar,

day = "1",

language = "English (US)",

journal = "Nuclear Physics A",

issn = "0375-9474",

publisher = "Elsevier",

}

TY - JOUR

T1 - ALMA observations of starless core substructure in ophiuchus

AU - Kirk, H.

AU - Dunham, M. M.

AU - Di Francesco, J.

AU - Johnstone, D.

AU - Offner, S. S.R.

AU - Sadavoy, S. I.

AU - Tobin, J. J.

AU - Arce, H. G.

AU - Bourke, T. L.

AU - Mairs, S.

AU - Myers, P. C.

AU - Pineda, J. E.

AU - Schnee, S.

AU - Shirley, Y. L.

PY - 2017/3/1

Y1 - 2017/3/1

N2 - Compact substructure is expected to arise in a starless core as mass becomes concentrated in the central region likely to form a protostar. Additionally, multiple peaks may form if fragmentation occurs. We present ALMA Cycle 2 observations of 60 starless and protostellar cores in the Ophiuchus molecular cloud. We detect eight compact substructures which are > 15′′ from the nearest Spitzer YSO. Only one of these has strong evidence for being truly starless after considering ancillary data, e.g., from Herschel and X-ray telescopes. An additional extended emission structure has tentative evidence for starlessness. The number of our detections is consistent with estimates from a combination of synthetic observations of numerical simulations and analytical arguments. This result suggests that a similar ALMA study in the Chamaeleon I cloud, which detected no compact substructure in starless cores, may be due to the peculiar evolutionary state of cores in that cloud.

AB - Compact substructure is expected to arise in a starless core as mass becomes concentrated in the central region likely to form a protostar. Additionally, multiple peaks may form if fragmentation occurs. We present ALMA Cycle 2 observations of 60 starless and protostellar cores in the Ophiuchus molecular cloud. We detect eight compact substructures which are > 15′′ from the nearest Spitzer YSO. Only one of these has strong evidence for being truly starless after considering ancillary data, e.g., from Herschel and X-ray telescopes. An additional extended emission structure has tentative evidence for starlessness. The number of our detections is consistent with estimates from a combination of synthetic observations of numerical simulations and analytical arguments. This result suggests that a similar ALMA study in the Chamaeleon I cloud, which detected no compact substructure in starless cores, may be due to the peculiar evolutionary state of cores in that cloud.

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M3 - Article

AN - SCOPUS:85095270489

JO - Nuclear Physics A

JF - Nuclear Physics A

SN - 0375-9474

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