Revealing H2D+ depletion and compact structure in starless and protostellar cores with ALMA

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Revealing H2D+ depletion and compact structure in starless and protostellar cores with ALMA. / Friesen, R. K.; Di Francesco, J.; Bourke, T. L.; Caselli, P.; Jørgensen, Jes Kristian; Pineda, J. E.; Wong, M.

In: Astrophysical Journal, Vol. 797, No. 1, 27, 2014.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Friesen, RK, Di Francesco, J, Bourke, TL, Caselli, P, Jørgensen, JK, Pineda, JE & Wong, M 2014, 'Revealing H2D+ depletion and compact structure in starless and protostellar cores with ALMA', Astrophysical Journal, vol. 797, no. 1, 27. https://doi.org/10.1088/0004-637X/797/1/27

APA

Friesen, R. K., Di Francesco, J., Bourke, T. L., Caselli, P., Jørgensen, J. K., Pineda, J. E., & Wong, M. (2014). Revealing H2D+ depletion and compact structure in starless and protostellar cores with ALMA. Astrophysical Journal, 797(1), [27]. https://doi.org/10.1088/0004-637X/797/1/27

Vancouver

Friesen RK, Di Francesco J, Bourke TL, Caselli P, Jørgensen JK, Pineda JE et al. Revealing H2D+ depletion and compact structure in starless and protostellar cores with ALMA. Astrophysical Journal. 2014;797(1). 27. https://doi.org/10.1088/0004-637X/797/1/27

Author

Friesen, R. K. ; Di Francesco, J. ; Bourke, T. L. ; Caselli, P. ; Jørgensen, Jes Kristian ; Pineda, J. E. ; Wong, M. / Revealing H2D+ depletion and compact structure in starless and protostellar cores with ALMA. In: Astrophysical Journal. 2014 ; Vol. 797, No. 1.

Bibtex

@article{115478638151453192bfeccb37979090,
title = "Revealing H2D+ depletion and compact structure in starless and protostellar cores with ALMA",
abstract = "We present Atacama Large Millimeter/submillimeter Array (ALMA) observations of the submillimeter dust continuum and H2D+ 110-111 emission toward two evolved, potentially protostellar cores within the Ophiuchus molecular cloud, Oph A SM1 and SM1N. The data reveal small-scale condensations within both cores, with mass upper limits of M 0.02 M ☉ (~20 M Jup). The SM1 condensation is consistent with a nearly symmetric Gaussian source with a width of only 37 AU. The SM1N condensation is elongated and extends 500 AU along its major axis. No evidence for substructure is seen in either source. A Jeans analysis indicates that these sources are unlikely to fragment, suggesting that both will form single stars. H2D+ is only detected toward SM1N, offset from the continuum peak by ~150-200 AU. This offset may be due to either heating from an undetected, young, low-luminosity protostellar source or first hydrostatic core, or HD (and consequently H2D+) depletion in the cold center of the condensation. We propose that SM1 is protostellar and that the condensation detected by ALMA is a warm (T ~ 30-50 K) accretion disk. The less concentrated emission of the SM1N condensation suggests that it is still starless, but we cannot rule out the presence of a low-luminosity source, perhaps surrounded by a pseudodisk. These data observationally reveal the earliest stages of the formation of circumstellar accretion regions and agree with theoretical predictions that disk formation can occur very early in the star formation process, coeval with or just after the formation of a first hydrostatic core or protostar.",
author = "Friesen, {R. K.} and {Di Francesco}, J. and Bourke, {T. L.} and P. Caselli and J{\o}rgensen, {Jes Kristian} and Pineda, {J. E.} and M. Wong",
year = "2014",
doi = "10.1088/0004-637X/797/1/27",
language = "English",
volume = "797",
journal = "Astrophysical Journal",
issn = "0004-637X",
publisher = "Institute of Physics Publishing, Inc",
number = "1",

}

RIS

TY - JOUR

T1 - Revealing H2D+ depletion and compact structure in starless and protostellar cores with ALMA

AU - Friesen, R. K.

AU - Di Francesco, J.

AU - Bourke, T. L.

AU - Caselli, P.

AU - Jørgensen, Jes Kristian

AU - Pineda, J. E.

AU - Wong, M.

PY - 2014

Y1 - 2014

N2 - We present Atacama Large Millimeter/submillimeter Array (ALMA) observations of the submillimeter dust continuum and H2D+ 110-111 emission toward two evolved, potentially protostellar cores within the Ophiuchus molecular cloud, Oph A SM1 and SM1N. The data reveal small-scale condensations within both cores, with mass upper limits of M 0.02 M ☉ (~20 M Jup). The SM1 condensation is consistent with a nearly symmetric Gaussian source with a width of only 37 AU. The SM1N condensation is elongated and extends 500 AU along its major axis. No evidence for substructure is seen in either source. A Jeans analysis indicates that these sources are unlikely to fragment, suggesting that both will form single stars. H2D+ is only detected toward SM1N, offset from the continuum peak by ~150-200 AU. This offset may be due to either heating from an undetected, young, low-luminosity protostellar source or first hydrostatic core, or HD (and consequently H2D+) depletion in the cold center of the condensation. We propose that SM1 is protostellar and that the condensation detected by ALMA is a warm (T ~ 30-50 K) accretion disk. The less concentrated emission of the SM1N condensation suggests that it is still starless, but we cannot rule out the presence of a low-luminosity source, perhaps surrounded by a pseudodisk. These data observationally reveal the earliest stages of the formation of circumstellar accretion regions and agree with theoretical predictions that disk formation can occur very early in the star formation process, coeval with or just after the formation of a first hydrostatic core or protostar.

AB - We present Atacama Large Millimeter/submillimeter Array (ALMA) observations of the submillimeter dust continuum and H2D+ 110-111 emission toward two evolved, potentially protostellar cores within the Ophiuchus molecular cloud, Oph A SM1 and SM1N. The data reveal small-scale condensations within both cores, with mass upper limits of M 0.02 M ☉ (~20 M Jup). The SM1 condensation is consistent with a nearly symmetric Gaussian source with a width of only 37 AU. The SM1N condensation is elongated and extends 500 AU along its major axis. No evidence for substructure is seen in either source. A Jeans analysis indicates that these sources are unlikely to fragment, suggesting that both will form single stars. H2D+ is only detected toward SM1N, offset from the continuum peak by ~150-200 AU. This offset may be due to either heating from an undetected, young, low-luminosity protostellar source or first hydrostatic core, or HD (and consequently H2D+) depletion in the cold center of the condensation. We propose that SM1 is protostellar and that the condensation detected by ALMA is a warm (T ~ 30-50 K) accretion disk. The less concentrated emission of the SM1N condensation suggests that it is still starless, but we cannot rule out the presence of a low-luminosity source, perhaps surrounded by a pseudodisk. These data observationally reveal the earliest stages of the formation of circumstellar accretion regions and agree with theoretical predictions that disk formation can occur very early in the star formation process, coeval with or just after the formation of a first hydrostatic core or protostar.

U2 - 10.1088/0004-637X/797/1/27

DO - 10.1088/0004-637X/797/1/27

M3 - Journal article

VL - 797

JO - Astrophysical Journal

JF - Astrophysical Journal

SN - 0004-637X

IS - 1

M1 - 27

ER -

ID: 138805996