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Star Formation and Bipolar Flows

Published online by Cambridge University Press:  04 August 2017

Ralph E. Pudritz
Ralph E. Pudritz*
Affiliation:
Deparment of Physics and Astronomy, The Johns Hopkins University

Extract

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Observations of molecular outflows from regions of star formation show that they cannot be radiatively driven ((Ṁv)mol ≥ 102 – 103 (L./c)). The thrust observed to be associated with the smaller scale ionized outflows is also incapable of driving the molecular gas ((Ṁv)ion ≃ (L./c), Persson et al 1984). The results may be explained if bipolar flows are hydromagnetic winds from molecular disks around protostars. These winds carry off disk rotational energy (observed as the mechanical energy of the outflows) and angular momentum (observed when rotation of the outflowing gas is found), which drives an accretion flow through it and onto the protostellar core (Pudritz 1985, Pudritz and Norman 1983, 1986). Therefore star formation and bipolar outflows occur simultaneously when magnetized, rotating disks are the source of activity.

Type
I. Star Forming Processes in the Solar Neighborhood
Information
Symposium - International Astronomical Union , Volume 115: Star Forming Regions , 1987 , pp. 336 - 340
Copyright
Copyright © Reidel 1987 

References

Bally, J. and Lada, C.J. 1983, Ap. J., 265, 824.CrossRefGoogle Scholar
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Pudritz, R.E. 1985, Ap. J., 293, 216.CrossRefGoogle Scholar
Pudritz, R.E., and Norman, C.A. 1983, Ap. J., 274, 677.CrossRefGoogle Scholar
Pudritz, R.E., and Norman, C.A. 1986, Ap. J., 301, Feb. 15 issue.CrossRefGoogle Scholar