Zhi Yun Li
University of Virginia
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Publication
Featured researches published by Zhi Yun Li.
The Astrophysical Journal | 2013
Nicholas L. Chapman; Jacqueline A. Davidson; Paul F. Goldsmith; Martin Houde; Woojin Kwon; Zhi Yun Li; Leslie W. Looney; Brenda C. Matthews; Tristan G. Matthews; Giles Novak; Ruisheng Peng; John E. Vaillancourt; Nikolaus H. Volgenau
We present 350 μm polarization observations of four low-mass cores containing Class 0 protostars: L483, L1157, L1448-IRS2, and Serp-FIR1. This is the second paper in a larger survey aimed at testing magnetically regulated models for core-collapse. One key prediction of these models is that the mean magnetic field in a core should be aligned with the symmetry axis (minor axis) of the flattened young stellar object inner envelope (aka pseudodisk). Furthermore, the field should exhibit a pinched or hourglass-shaped morphology as gravity drags the field inward toward the central protostar. We combine our results for the four cores with results for three similar cores that were published in the first paper from our survey. An analysis of the 350 μm polarization data for the seven cores yields evidence of a positive correlation between mean field direction and pseudodisk symmetry axis. Our rough estimate for the probability of obtaining by pure chance a correlation as strong as the one we found is about 5%. In addition, we combine together data for multiple cores to create a source-averaged magnetic field map having improved signal-to-noise ratio, and this map shows good agreement between mean field direction and pseudodisk axis (they are within 15°). We also see hints of a magnetic pinch in the source-averaged map. We conclude that core-scale magnetic fields appear to be strong enough to guide gas infall, as predicted by the magnetically regulated models. Finally, we find evidence of a positive correlation between core magnetic field direction and bipolar outflow axis.
Nature | 2014
Ian W. Stephens; Leslie W. Looney; Woojin Kwon; Manuel Fernández-López; A. Meredith Hughes; Lee G. Mundy; Richard M. Crutcher; Zhi Yun Li; Ramprasad Rao
Magnetic fields in accretion disks play a dominant part during the star formation process but have hitherto been observationally poorly constrained. Field strengths have been inferred on T Tauri stars and possibly in the innermost part of their accretion disks, but the strength and morphology of the field in the bulk of a disk have not been observed. Spatially unresolved measurements of polarized emission (arising from elongated dust grains aligned perpendicularly to the field) imply average fields aligned with the disks. Theoretically, the fields are expected to be largely toroidal, poloidal or a mixture of the two, which imply different mechanisms for transporting angular momentum in the disks of actively accreting young stars such as HL Tau (ref. 11). Here we report resolved measurements of the polarized 1.25-millimetre continuum emission from the disk of HL Tau. The magnetic field on a scale of 80xa0astronomical units is coincident with the major axis (about 210 astronomical units long) of the disk. From this we conclude that the magnetic field inside the disk at this scale cannot be dominated by a vertical component, though a purely toroidal field also does not fit the data well. The unexpected morphology suggests that the role of the magnetic field in the accretion of a T Tauri star is more complex than our current theoretical understanding.
The Astrophysical Journal | 2016
John J. Tobin; Leslie W. Looney; Zhi Yun Li; Claire J. Chandler; Michael M. Dunham; Dominique Segura-Cox; S. Sadavoy; Carl Melis; Robert J. Harris; Kaitlin M. Kratter; Laura M. Pérez
We present a multiplicity study of all known protostars (94) in the Perseus molecular cloud from a Karl G. Jansky Very Large Array (VLA) survey at Ka-band (8 mm and 1 cm) and C-band (4 cm and 6.6 cm). The observed sample has a bolometric luminosity range between 0.1 L
Nature | 2016
John J. Tobin; Kaitlin M. Kratter; M. V. Persson; Leslie W. Looney; Michael M. Dunham; Dominique Segura-Cox; Zhi Yun Li; Claire J. Chandler; S. Sadavoy; Robert J. Harris; Carl Melis; Laura M. Pérez
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Monthly Notices of the Royal Astronomical Society | 2016
Haifeng Yang; Zhi Yun Li; Leslie W. Looney; Ian W. Stephens
and
Publications of the Astronomical Society of Australia | 2008
Jürgen Ott; Tony Wong; Jorge L. Pineda; Annie Hughes; Erik Muller; Zhi Yun Li; Min Wang; Lister Staveley-Smith; Yasuo Fukui; A. Weiß; Christian Henkel; Ulrich Klein
sim
The Astrophysical Journal | 2014
Dominique Segura-Cox; Leslie W. Looney; Ian W. Stephens; Manuel Fernández-López; Woojin Kwon; John J. Tobin; Zhi Yun Li; Richard M. Crutcher
33 L
The Astrophysical Journal | 2014
John J. Tobin; Michael M. Dunham; Leslie W. Looney; Zhi Yun Li; Claire J. Chandler; Dominique Segura-Cox; S. Sadavoy; Carl Melis; Robert J. Harris; Laura M. Pérez; Kaitlin M. Kratter; Jes K. Jørgensen; Adele L. Plunkett; Charles L. H. Hull
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Monthly Notices of the Royal Astronomical Society | 2016
Haifeng Yang; Zhi Yun Li; Leslie W. Looney; Erin G. Cox; John J. Tobin; Ian W. Stephens; Dominque M. Segura-Cox; Robert J. Harris
, with a median of 0.7 L
The Astrophysical Journal | 2015
Erin G. Cox; Robert J. Harris; Leslie W. Looney; Dominique Segura-Cox; John J. Tobin; Zhi Yun Li; Łukasz Tychoniec; Claire J. Chandler; Michael M. Dunham; Kaitlin M. Kratter; Carl Melis; Laura M. Pérez; S. Sadavoy
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