Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-15T01:26:15.719Z Has data issue: false hasContentIssue false

High-Dispersion Spectroscopy of IC 351 and NGC 3242, Planetaries by High Internal Motion

Published online by Cambridge University Press:  07 August 2017

Y. Yadoumaru
Affiliation:
Astronomical Institute, Tohoku University, Aoba-ku Sendat 980, Japan
S. Tamura
Affiliation:
Astronomical Institute, Tohoku University, Aoba-ku Sendat 980, Japan

Extract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

We made high-dispersion spectroscopic observations of IC 351 = PK 159 − 15°1, a compact high-excitation planetary nebula. We found the expansion velocity from Hα, [OIII] and HeII line, of 45.1kms −1, 38.7kms −1, and 33.3kms −1, respectively. Moreover, for the Hα line we detected an additional faint blue-shifted component escaping from the center of expansion with high velocity of 120kms −1. This value is larger than the usual expansion velocity (< 50kms −1) but considerably smaller than that of stellar wind. This faint blue-shifted component of Hα is also coincidently identified as the helium line, HeIIλ6560 (Pickering 6). Using the emission coefficients of recombination lines (Case B, T= 10,000K; Osterbrock 1989), and the intensity ratio, I(HeIIλ4686)/I(Hβ)=0.56±0.05 (Aller&Czyzak 1979), we can estimate the expected line intensity ratio, I(HeIIλ6560)/I(Hα)=0.026±0.002. On the other hand, the intensity ratio of faint component to Hα in the present observations is estimated as Ifaintcomp ./I(Hα)=0.064±0.013, based up the Hα profile in 1988. Comparing these two estimated intensity ratios it is clearly unable to emit the all intensity of the observed faint component by HeIIλ6560 line only. Therefore, even if this component is partly polluted by HeIIλ6560 line, we can consider the rest part as an emission from high velocity component of Hα. We can also recognize the bumped feature of [OIII]λ5007 line around the same velocity to the blue-shifted component of Hα. This fact supports the idea that these components can be attributed to the high velocity flow. We discuss the three ideas for the interpretation of such component; (a) colliding winds, (b) unresolved bipolar flow, and (c) secondary formation of an expanding shell. We have investigated whether the colliding winds model gives such high velocity or not. As the results of the calculation, if we use the usual mass-loss rate, the model can not give such high velocity. Therefore, it is doubtful that we can take this model as an explanation of the high velocity components. The high velocity component of IC 351 is not uncommon; such large internal motions are reported for other planetaries by Weinberger(1989) and compiled by Grewing(1989). The article on the results of IC 351 is submitted to PASP (Yadoumaru & Tamura 1992). We also report the other analysis on NGC 3242.

Type
IV. Planetary Nebulae Connection: Evolution from the AGB
Copyright
Copyright © Kluwer 1993 

References

Aller, L.H. and Czyzak, S.J.,1979,Ap&SS,62,397.Google Scholar
Grewing, M.,1989, in “IAU Symposium No.131, Planetary Nebulae “, ed. Torres-Peimbert, S., (Reidel, Dordrecht, Holland), p. 241.Google Scholar
Osterbrock, D.E., 1989, Astrophysics of Gaseous Nebulae and Active Galactic Nuclei , p.80 and p.85.Google Scholar
Weinberger, R., 1989, in “IAU Symposium No.131, Planetary Nebulae, ed. Torres-Peimbert, S., (Reidel, Dordrecht, Holland), p.93.Google Scholar
Yadoumaru, Y. and Tamura, S.,1992, submitted to PASP.Google Scholar