1. Centre for Astrophysics Research, Science and Technology Research Institute, University of Hertfordshire, Hatfield, Herts. AL10 9AB, UK

Correspondence to: Antonio Chrysostomou¹Philip W. Lucas¹ Correspondence and requests for materials should be addressed to A.C. (Email: a.chrysostomou@herts.ac.uk) or P.W.L. (Email: p.w.lucas@herts.ac.uk).

Abstract

Magnetic fields are believed to have a vital role in regulating and shaping the flow of material onto and away from protostars during their initial mass accretion phase. It is becoming increasingly accepted¹ that bipolar outflows are generated and collimated as material is driven along magnetic field lines and centrifugally accelerated off a rotating accretion disk. However, the precise role of the magnetic field is poorly understood and evidence for its shape and structure has not been forthcoming. Here we report imaging circular polarimetry in the near-infrared and Monte Carlo modelling showing that the magnetic field along the bipolar outflow of the HH 135–136 young stellar object is helical. The field retains this shape for large distances along the outflow, so the field structure can also provide the necessary magnetic pressure for collimation of the outflow. This result lends further weight to the hypothesis—central to any theory of star formation—that the outflow is an important instrument for the removal of high-angular-momentum material from the accretion disk, thereby allowing the central protostar to increase its mass.

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