Magellanic Cloud planetary nebulae as probes of stellar evolution and populations. Letizia Stanghellini

Similar documents

Faber-Jackson relation: Fundamental Plane: Faber-Jackson Relation

Ellipticals. Elliptical galaxies: Elliptical galaxies: Some ellipticals are not so simple M89 E0

Nuclear fusion in stars. Collapse of primordial density fluctuations into galaxies and stars, nucleosynthesis in stars

Evolution of Close Binary Systems

The Chemical Composition of a Molecular Cloud at the Outer Edge of the Galaxy

Science Standard 4 Earth in Space Grade Level Expectations

Chapter 15.3 Galaxy Evolution

Class #14/15 14/16 October 2008

Modeling Galaxy Formation

165 points. Name Date Period. Column B a. Cepheid variables b. luminosity c. RR Lyrae variables d. Sagittarius e. variable stars

A Universe of Galaxies

Elliptical Galaxies. Houjun Mo. April 19, Basic properties of elliptical galaxies. Formation of elliptical galaxies

Late Helium Flashes and Hydrogen-Poor Stars

Resultados Concurso Apex 2014-A

IV. Molecular Clouds. 1. Molecular Cloud Spectra

8.1 Radio Emission from Solar System objects

How Do Galeries Form?

Ay 20 - Lecture 9 Post-Main Sequence Stellar Evolution. This file has many figures missing, in order to keep it a reasonable size.

Lecture 6: distribution of stars in. elliptical galaxies

Using Photometric Data to Derive an HR Diagram for a Star Cluster

The Solar Journey: Modeling Features of the Local Bubble and Galactic Environment of the Sun

Star Formation in the Large Magellanic Cloud: Tracing an Evolution of Giant Molecular Clouds

Stellar Astrophysics: Stellar Evolution 1. Stellar Evolution

The Hidden Lives of Galaxies. Jim Lochner, USRA & NASA/GSFC

Adaptive Optics (AO) TMT Partner Institutions Collaborating Institution Acknowledgements

The Birth and Assembly of Galaxies: the Relationship Between Science Capabilities and Telescope Aperture

13 Space Photos To Remind You The Universe Is Incredible

Einstein Rings: Nature s Gravitational Lenses

Welcome to Class 4: Our Solar System (and a bit of cosmology at the start) Remember: sit only in the first 10 rows of the room

The Interstellar Medium Astronomy 216 Spring 2005

The Universe Inside of You: Where do the atoms in your body come from?

Stellar Evolution. The Basic Scheme

The Main Point. Lecture #34: Solar System Origin II. Chemical Condensation ( Lewis ) Model. How did the solar system form? Reading: Chapter 8.

AGN-driven winds and ionized clouds moving along the jet in PKS

DIRECT ORBITAL DYNAMICS: USING INDEPENDENT ORBITAL TERMS TO TREAT BODIES AS ORBITING EACH OTHER DIRECTLY WHILE IN MOTION

The Orbital Period Distribution of Wide Binary Millisecond Pulsars

Top 10 Discoveries by ESO Telescopes

Lecture 7 Formation of the Solar System. Nebular Theory. Origin of the Solar System. Origin of the Solar System. The Solar Nebula

Galaxy Classification and Evolution

7. In which part of the electromagnetic spectrum are molecules most easily detected? A. visible light B. radio waves C. X rays D.

Observing the Universe

An Introduction to Astronomy and Cosmology. 1) Astronomy - an Observational Science

Populations and Components of the Milky Way

Origins of the Cosmos Summer Pre-course assessment

L3: The formation of the Solar System

Solar Ast ro p h y s ics

Planck Early Results: New light on Anomalous Microwave Emission from Spinning Dust Grains

Data Provided: A formula sheet and table of physical constants is attached to this paper. DARK MATTER AND THE UNIVERSE

Constraints on the explosion mechanism and progenitors of Type Ia supernovae

Molecular line emission in asymmetric envelopes of evolved stars

This work was done in collaboration with the Centre de Données astronomiques de Strasbourg (CDS) and in particular with F. X. Pineau.

Spectral Line II. G ij (t) are calibrated as in chapter 5. To calibrated B ij (ν), observe a bright source that is known to be spectrally flat

Solar Nebula Theory. Basic properties of the Solar System that need to be explained:

Lecture 14. Introduction to the Sun

California Standards Grades 9 12 Boardworks 2009 Science Contents Standards Mapping

Solar System Formation

NGUYEN LUONG QUANG. Président du jury: J. Le Bourlot Rapporteurs: H. Beuther, T. Moore Examinateurs: I. Bonnell, F. Boulanger, F. Combes, F.

The Messier Objects As A Tool in Teaching Astronomy

The Milky Way Galaxy is Heading for a Major Cosmic Collision

Summary: Four Major Features of our Solar System

Unit 8 Lesson 2 Gravity and the Solar System

Detailed Mass Map of CL from Strong Lensing

Be Stars. By Carla Morton

This paper is also taken for the relevant Examination for the Associateship. For Second Year Physics Students Wednesday, 4th June 2008: 14:00 to 16:00

Heating & Cooling in Molecular Clouds

The Formation of Dwarf Early-Type Galaxies. Reynier Peletier Kapteyn Astronomical Institute, Groningen

8. The evolution of stars a more detailed picture

Chapter 6 Formation of Planetary Systems Our Solar System and Beyond

Intermediate-Mass Black Holes (IMBHs) in Globular Clusters? HST Proper Motion Constraints. Roeland van der Marel

Malcolm S. Longair. Galaxy Formation. With 141 Figures and 12 Tables. Springer

Introduction to the Solar System

Transcription:

Magellanic Cloud planetary nebulae as probes of stellar evolution and populations Letizia Stanghellini Planetary nebulae beyond the Milky Way - May 19-21, 2004 1

Magellanic Cloud PNe The known distances, low field reddening, relative proximity, and metallicity range make them Absolute probes of post-agb evolution Benchmarks for extragalactic PN populations Planetary nebulae beyond the Milky Way - May 19-21, 2004 2

Probes of post-agb evolution Nebular analysis Morphology chemistry Links to central stars (CSs) Transition time Winds Planetary nebulae beyond the Milky Way - May 19-21, 2004 3

Benchmarks for extragalactic PN populations PNe and UCHII regions Luminosity distribution and metallicity PNe types in the PNLF Planetary nebulae beyond the Milky Way - May 19-21, 2004 4

PN morphology Depends on the formation and dynamic evolution of the PN, on the evolution of the central star and of the stellar progenitor, and on the environment. From Galactic PNe: Round, Elliptical, Bipolar [includes bipolar core and multipolar], and Point-symmetric Bipolar PNe are located in the Galactic plane, have high N, He, indication of massive CSs: remnant of 3-8 M stars? Planetary nebulae beyond the Milky Way - May 19-21, 2004 5

Symmetric Asymmetric Round PNe (R) are a minority (22 % of all Galactic PNe with studied morphology) 49% elliptical (E) 17% bipolar (or multi-polar) (B) 9% have an equatorial enhancement, or ring (lobe-less bipolar, or bipolar cores) (BC) 3% point-symmetric 6

HST and spatial resolution LMC SMP 10 HST STIS -----3 arcsec ------- ------------35 arcsec ---------------------- 7

8 Slitless Spectra of LMC SMP 16 G430M (4818 5104) and G750M (6295 6867) _5007 [O III] _4959 [O III] _4861 Hβ 6732 [S II] 6716 [S II] 6584 [N II] 6563 Hα 6548 [N II] _6300 [O I]

Galaxy LMC SMC Round Elliptical Bipolar Symmetric Asymmetric Point-symmetric 9

Morphological distribution Round R Elliptical E R+E (symm.) Bipolar B Bipolar core BC B+BC (asymm.) LMC 29 % 17 % 46 % 34 % 17 % 51 % SMC 35 % 29 % 64 % 6 % 24 % 30 % Point-symmetric 3 % 6 % 10

What is the physical origin of the equatorial disks? stellar rotation? Maybe associated with a strong magnetic field? Garcia-Segura 97 (single magnetic WD are more massive than nonmagnetic WDs! Wickramasinge & Ferrario 2000) Binary evolution of the progenitor (CE)? Morris 81; Soker 98 11

Chemistry PNe enrich the ISM He, C, N, O abundances are linked to the evolution of the progenitors C-rich for massive progenitors (M ZAMS < 3 Msun) He- and N-rich (and C-poor) if M ZAMS > 3 Msun Ar, S, Ne are invariant during the evolution of stars in this mass range they are signature of the protostellar ambient, thus test previous evolutionary history Planetary nebulae beyond the Milky Way - May 19-21, 2004 12

Primordial elements, LMC O Round * Elliptical Bipolar core Bipolar LMC HII regions (average) 13

Primordial elements, LMC O Round * Elliptical Bipolar core Bipolar LMC HII regions (average) 14

LMC PN morphology and the products of stellar evolution O Round * Elliptical Bipolar core Bipolar LMC HII regions (average) 15

SMP16 SMP 95 SMP 34 Decreasing excitation class ---> 16 Si IV N IV C IV] He II

[Ne IV] SMP16 SMP 95 SMP 34 C III ] C II] 17

Optical AND UV morphology Broad band [O III] 5007 [N II] Hα [N II] C III]1908 C II] 2327 [Ne IV] 2426 nebular continuum LMC SMP 95 18

UV spectra fitting Planetary nebulae beyond the Milky Way - May 19-21, 2004 19

P-Cygni profiles Planetary nebulae beyond the Milky Way - May 19-21, 2004 20

See poster by A. Arrieta 21 Wind momentum vs. luminosity

Transition time Transition time (t tr ) is measured from the envelope ejection quenching (EEQ) and the PN illumination; it is regulated by wind and/or nuclear evolution M er (residual envelope mass at EEQ) determines t tr τ dyn =D PN /v exp represent the dynamic PN age. If D PN is measured on main shell, τ dyn tracks time from EEQ τ dyn =t tr + t (t ev ev = time after PN illumination, corresponding to evolutionary time if tracks have zero point at illumination) 22

Dealing with unsynchronized clocks t tr is an essential parameter in post-agb population synthesis (e.g., PNLF high luminosity cutoff, and UV contribution from post-agb stars in galaxies) Mass-loss at TP-AGB and beyond not completely understood, and M er now known Only way to constraint t tr is observationally > Magellanic PNe offer the first direct estimates of transition time Planetary nebulae beyond the Milky Way - May 19-21, 2004 23

τ dyn and t ev LMC SMC Round: symm. PNe (R,E) Square: asymm. PNe (B,BC,P) H-burning central stars 24

Distribution of t tr in MC PNe 25

M er =1e-3 M er =2e-3 Data LMC PNe SMC Pne M er =5e-3 M er =1e-2 Models t wind t nucl t tr 26

Total mass loss (IMFMR) Data: optically thin LMC and SMC PNe Hydro models: solid line =PN shells broken line=outer halos --> To constrain IMFMR we need to measure mass in PN halos (and in CSs) 27

Importance of spatiallyresolved PN populations We sampled ~50 (+30) LMC and ~30 SMC PNe, chosen among the brightest known (based on on Hβ and [O III] 5007 fluxes ) All LMC PN candidates are indeed PNe ~10% of the SMC PN candidates are H II regions Planetary nebulae beyond the Milky Way - May 19-21, 2004 28

MA 1796 MA 1797 MG 2 Log Fβ 13.85... 14.3 C 1.53... 1.4 Size [arcsec] 3 11 3.5 Size [pc] 0.85 3.1 0.98 Planetary nebulae beyond the Milky Way - May 19-21, 2004 29

Observed distributions of I(5007)/I(Hb) LMC SMC 30

Cloudy models Galaxy LMC SMC Nuclear reactions end PN + CS trans. Super-wind TP-AGB AGB Cooling WD T eff L 31

Cloudy models, varying density SMC LMC Galaxy 32

PN cooling in different galaxies Our HST data: LMC <I(5007)/I(Hβ)>=9.4 (3.1) <I(1909)/I(Hβ)>=5 (5) SMC <I(5007)/I(Hβ)>=5.7 (2.5) UV: Cycle 13 SMC LMC Galaxy 33

PNe in the PNLF O round; * elliptical; bipolar core; bipolar LMC SMC Open circles: R Asterisks: E Triangles: BC Squares: B Filled circles: P Faint----------> bright 34

LMC SMC CSs in PNLF SMC HLCO LMC HLCO 35 Faint-----------> bright

Summary, and the future HST fundamental for shapes/ radii, but also for identification (misclassified H II regions in SMC but not in LMC metallicity effect?) Same morphology types in Galaxy, LMC, SMC, but more asymmetric PNe in LMC than SMC different stellar generations? Asymmetric LMC PNe have high Ne, S, Ar--> signature of younger progenitors Similar UV and optical morphology Planetary nebulae beyond the Milky Way - May 19-21, 2004 36

Summary, cont. Carbon higher for symmetric PNe, STIS UV spectra of LMC PNe to be analyzed; SMC PNe in Cycle 13 P-Cygni profiles as signature of CS winds, distance indicator for galactic PNe Transition time constrained from observation enlarge sample, hydro+stellar modeling IMFM relation constraints [O III]/Hβ flux ratio of a PN population variant with host galaxy Planetary nebulae beyond the Milky Way - May 19-21, 2004 37

Summary, cont. Symmetric PNe populate the high luminosity parts of the PNLF High mass CSs populate the faint end of the LF, sample to be extended Planetary nebulae beyond the Milky Way - May 19-21, 2004 38