Stellar yields and abundances: New directions from planetary nebulae

Maria Lugaro; Amanda I. Karakas; Marco Pignatari; Carolyn L. Doherty

doi:10.1017/S1743921317001247

Stellar yields and abundances: New directions from planetary nebulae

Maria Lugaro, Amanda I. Karakas, Marco Pignatari, Carolyn L. Doherty

Research output: Contribution to journal › Article › peer-review

Abstract

Planetary nebulae retain the signature of the nucleosynthesis and mixing events that occurred during the previous AGB phase. Observational signatures complement observations of AGB and post-AGB stars and their binary companions. The abundances of the elements heavier than iron such as Kr and Xe in planetary nebulae can be used to complement abundances of Sr/Y/Zr and Ba/La/Ce in AGB stars, respectively, to determine the operation of the slow neutron-capture process (the s process) in AGB stars. Additionally, observations of the Rb abundance in Type I planetary nebulae may allow us to infer the initial mass of the central star. Several noble gas components present in meteoritic stardust silicon carbide (SiC) grains are associated with implantation into the dust grains in the high-energy environment connected to the fast winds from the central stars during the planetary nebulae phase.

Original language	English
Pages (from-to)	86-94
Number of pages	9
Journal	Proceedings of the International Astronomical Union
Volume	12
Issue number	S323
DOIs	https://doi.org/10.1017/S1743921317001247
Publication status	Published - 1 Oct 2016

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title = "Stellar yields and abundances: New directions from planetary nebulae",

abstract = "Planetary nebulae retain the signature of the nucleosynthesis and mixing events that occurred during the previous AGB phase. Observational signatures complement observations of AGB and post-AGB stars and their binary companions. The abundances of the elements heavier than iron such as Kr and Xe in planetary nebulae can be used to complement abundances of Sr/Y/Zr and Ba/La/Ce in AGB stars, respectively, to determine the operation of the slow neutron-capture process (the s process) in AGB stars. Additionally, observations of the Rb abundance in Type I planetary nebulae may allow us to infer the initial mass of the central star. Several noble gas components present in meteoritic stardust silicon carbide (SiC) grains are associated with implantation into the dust grains in the high-energy environment connected to the fast winds from the central stars during the planetary nebulae phase.",

keywords = "Abundances, Nuclear reactions, Nucleosynthesis, Stars: Abundances, Stars: Agb and post-Agb, Stars: Chemically peculiar",

author = "Maria Lugaro and Karakas, {Amanda I.} and Marco Pignatari and Doherty, {Carolyn L.}",

note = "Publisher Copyright: Copyright {\textcopyright} International Astronomical Union 2017.",

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doi = "10.1017/S1743921317001247",

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T1 - Stellar yields and abundances

T2 - New directions from planetary nebulae

AU - Lugaro, Maria

AU - Karakas, Amanda I.

AU - Pignatari, Marco

AU - Doherty, Carolyn L.

PY - 2016/10/1

Y1 - 2016/10/1

N2 - Planetary nebulae retain the signature of the nucleosynthesis and mixing events that occurred during the previous AGB phase. Observational signatures complement observations of AGB and post-AGB stars and their binary companions. The abundances of the elements heavier than iron such as Kr and Xe in planetary nebulae can be used to complement abundances of Sr/Y/Zr and Ba/La/Ce in AGB stars, respectively, to determine the operation of the slow neutron-capture process (the s process) in AGB stars. Additionally, observations of the Rb abundance in Type I planetary nebulae may allow us to infer the initial mass of the central star. Several noble gas components present in meteoritic stardust silicon carbide (SiC) grains are associated with implantation into the dust grains in the high-energy environment connected to the fast winds from the central stars during the planetary nebulae phase.

AB - Planetary nebulae retain the signature of the nucleosynthesis and mixing events that occurred during the previous AGB phase. Observational signatures complement observations of AGB and post-AGB stars and their binary companions. The abundances of the elements heavier than iron such as Kr and Xe in planetary nebulae can be used to complement abundances of Sr/Y/Zr and Ba/La/Ce in AGB stars, respectively, to determine the operation of the slow neutron-capture process (the s process) in AGB stars. Additionally, observations of the Rb abundance in Type I planetary nebulae may allow us to infer the initial mass of the central star. Several noble gas components present in meteoritic stardust silicon carbide (SiC) grains are associated with implantation into the dust grains in the high-energy environment connected to the fast winds from the central stars during the planetary nebulae phase.

KW - Abundances

KW - Nuclear reactions

KW - Nucleosynthesis

KW - Stars: Abundances

KW - Stars: Agb and post-Agb

KW - Stars: Chemically peculiar

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U2 - 10.1017/S1743921317001247

DO - 10.1017/S1743921317001247

M3 - Article

AN - SCOPUS:85047005108

SN - 1743-9213

VL - 12

SP - 86

EP - 94

JO - Proceedings of the International Astronomical Union

JF - Proceedings of the International Astronomical Union

IS - S323

ER -

Stellar yields and abundances: New directions from planetary nebulae

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