圖片來源: Hyosun Kim, I-Ta Hsieh, Sheng-Yuan Liu, & Ronald E. Taam
Velocity channel images of an HC3N molecular line emission of CIT 6 observed with the VLA (red, Claussen et al. 2011), and modeled by an hydrodynamic radiative transfer simulation using the FLASH and SPARX codes (green). The position angles of the knots found in the model are indicated by arrows. A simple geometric model with an inclined Archimedes spiral-shell is drawn by a gray solid line in each channel.
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With the advent of high-resolution high-sensitivity observations, spiral patterns have been revealed around several asymptotic giant branch (AGB) stars. Such patterns can provide possible evidence for the existence of central binary stars embedded in outflowing circumstellar envelopes. In Kim et al. (2013, ApJ, 776, 86), we suggest the viability of explaining the previously observed incomplete ring-like patterns with the spiral-shell structure due to the motion of (unknown) binary components viewed at an inclination with respect to the
orbital plane. We describe a method of extracting such spiral-shells from
an incomplete ring-like pattern to place constraints on the characteristics
of the central binary stars. The use of gas kinematics is essential in
facilitating a detailed modeling for the three-dimensional structure of the
circumstellar pattern. We show that a hydrodynamic radiative transfer model
can reproduce the structure of the HC3N molecular line emission of the
extreme carbon star, CIT 6. This method can be applied to other sources
in the AGB phase and to the outer ring-like patterns of pre-planetary
nebulae for probing the existence of embedded binary stars, which are
highly anticipated with future observations using the Atacama Large
Millimeter/submillimeter Array. |