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The final 105 years of stellar AGB evolution in the presence of a pulsating, dust-induced “superwind”

Published online by Cambridge University Press:  25 May 2016

K.-P. Schröder ,
J.M. Winters  and
E. Sedlmayr
K.-P. Schröder
Affiliation:
Technische Universität Berlin, Inst. f. Astronomie u. Astrophysik, Sekr. PN 8-1, Hardenbergstr. 36, D-10623 Berlin, Germany
J.M. Winters
Affiliation:
Technische Universität Berlin, Inst. f. Astronomie u. Astrophysik, Sekr. PN 8-1, Hardenbergstr. 36, D-10623 Berlin, Germany
E. Sedlmayr
Affiliation:
Technische Universität Berlin, Inst. f. Astronomie u. Astrophysik, Sekr. PN 8-1, Hardenbergstr. 36, D-10623 Berlin, Germany

Abstract

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We have computed mass-loss histories and tip-AGB stellar evolution models in the presence of a dust-induced, carbon-rich “superwind”, in the initial mass-range of 1.1 to about 2.5 solar masses and for nearly solar composition (X=0.28, Y=0.70, Z=0.02). Consistent, actual mass-loss rates are used in each time-step, based on pulsating and “dust-driven” stellar wind models for carbon-rich stars (Fleischer et al. 1992) which include a detailed treatment of dust-formation, radiative transfer and wind acceleration. Our tip-AGB mass-loss rates reach about 4 · 10−5Myr−1 and become an influencial factor of stellar evolution.

Heavy outflows of 0.3 to 0.6 M within only 2 to 3·104 yrs, exactly as required for PN-formation, occur with tip-AGB models of an initial stellar mass Mi ≳ 1.3M. The mass-loss of our “superwind” varies strongly with effective temperature (T−8eff, see Arndt et al. 1997), reflecting the temperature-sensitive micro-physics and chemistry of dust-formation and radiative transfer on a macroscopic scale. Furthermore, a thermal pulse leads to a very short (100 to 200 yrs) interruption of the “superwind” of these models.

For Mi ≲ 1.1M, our evolution models fail to reach the (Eddington-like) critical luminosity Lc required by the radiatively driven wind models, while for the (initial) mass-range in-between, with the tip-AGB luminosity LtAGB near Lc, thermal pulses drive bursts of “superwind”, which could explain the outer shells found with some PN's. In particular, a burst with a duration of only 800 yrs and a mass-loss of about 0.03 M, occurs right after the last AGB thermal pulse of a model with Mi ≈ 1.1M. There is excellent agreement with the thin CO shells found by Olofsson et al. (e.g., 1990, 1998) around some Mira stars.

Type
Part 4. Circumstellar Envelopes
Information
Symposium - International Astronomical Union , Volume 191: Asymptotic Giant Branch Stars , 1999 , pp. 389 - 394
Copyright
Copyright © Astronomical Society of the Pacific 1999 

References

Alksnis, A., Balklavs, A., Dzervitis, U., Eglitis, I., 1998, A&A 338, 209 Google Scholar
Arndt, T.U., Fleischer, A.J., Sedlmayr, E., 1997, A&A 327, 614 Google Scholar
Blöcker, T., 1995, A&A 297, 727 Google Scholar
Bowen, G.H., 1988, ApJ 329, 299 Google Scholar
Eggleton, P.P., 1971, MNRAS 151, 351 Google Scholar
Eggleton, P.P., 1972, MNRAS 156, 361 Google Scholar
Fleischer, A.J., Gauger, A., Sedlmayr, E., 1992, A&A 266, 321 Google Scholar
Hashimoto, O., Izumiura, H., Kester, D.J.M., Bontekoe, Tj.R., 1998, A&A 329, 213 Google Scholar
Kwok, S., 1981, in Physical Processes in Red Giants, Iben, I. Jr. and Renzini, A. (eds.), D. Reidel Publ. Co., Dordrecht, p. 421 Google Scholar
Olofsson, H., Carlström, U., Eriksson, K., Gustafsson, B., Willson, L.A., 1990, A&A 230, L13 Google Scholar
Olofsson, H., Bergman, P., Lucas, R., Eriksson, K., Gustafsson, B., Bieging, J.H., 1998, A&A 330, L1 Google Scholar
Pols, O.R., Schröder, K.-P., Tout, C.A., Hurley, J.R., Eggleton, P.P., 1998, MNRAS 298, 525 Google Scholar
Reimers, D., 1975, in Problems in Stellar Atmospheres and Envelopes , Baschek, B. and Kegel, W.H. (eds.), Springer, Berlin, p. 229 Google Scholar
Renzini, A., 1981, in Physical Processes in Red Giants, Iben, I. Jr. and Renzini, A. (eds.), D. Reidel Publ. Co., Dordrecht, p. 431 Google Scholar
Schröder, K.-P., 1998, A&A 334, 901 Google Scholar
Schröder, K.-P., Winters, J.M., Arndt, T.U., Sedlmayr, E., 1998, A&A 335, L9 Google Scholar
Sedlmayr, E., 1994, in Molecules in the Stellar Environment , IAU Colloquium 146, J⊘rgensen, U.G. (ed.), Springer, Berlin, p. 163 Google Scholar
Vassiliadis, E., Wood, P.R., 1993, ApJ 413, 641 Google Scholar