Presentation is loading. Please wait.

Presentation is loading. Please wait.

Temporal variations of the circumstellar environment of the Mira star V Oph Keiichi Ohnaka Max-Planck-Institut für Radioastronomie ESO Santiago Seminar.

Published byMorris Peters Modified over 9 years ago

Similar presentations

Presentation on theme: "Temporal variations of the circumstellar environment of the Mira star V Oph Keiichi Ohnaka Max-Planck-Institut für Radioastronomie ESO Santiago Seminar."— Presentation transcript:

1 Temporal variations of the circumstellar environment of the Mira star V Oph Keiichi Ohnaka Max-Planck-Institut für Radioastronomie ESO Santiago Seminar 10 January 2008

2 Asymptotic Giant Branch (AGB) T eff ~ 3000K L ~ 10 3 -- 10 4 L  Late evolutionary stage of low- & intermediate mass stars (1-8 M  ) AGB To Planetary Nebulae Main sequence 1M1M 3M3M

3 C/O core He H Helium shell burning (3 4 He  12 C) Thermally unstable, run-away reaction “Thermal pulse” or “Helium shell flash” Hydrogen shell burning 4 H  He Photosphere Circumstellar shell Mass loss, Dust formation Convective mixing ~0.01--0.1 R  (~Earth’s radius) ~200--400 R  (~1AU = Earth’s Orbital Radius) ~2 R star = ~600--800 R  (3--4AU) Stellar surface To interstellar space Carbon mixed up to surface by convection O-rich photosphere  C-rich (“Carbon Star”)

4 Why AGB stars are important? 1. Majority of the stellar population 2. Nucleosynthesized material mixed to the stellar surface 3. Enrichment of ISM via mass loss Major “Dust Factory”, together with supernovae O-rich photosphere  C-rich photosphere  “Carbon stars” (C 2, CN, HCN, C 2 H 2 features in optical/IR spectra) s-process elements (Ba, La, Eu, Tc, etc)

5 Driving mechanism not well understood Mass-loss rates = 10 -8 —10 -5 M  /yr Dust & Molecule forming region close to the star Morphology change from AGB to planetary nebulae How and at what stage?  High Angular Resolution  IR interferometry AGB, CIT3 J 100mas AGB Post-AGB Red Rectangle 200mas PN, Cat’s Eye Nebula AGB, AFGL2290 50mas K H Carbon star, IRC+10216 100mas K Mass loss mechanism in AGB stars

6 2 Telescopes  Only visibility (Amplitude of Fourier transform of I(x,y) How an IR interferometer works B Spatial resolution  /B p N band (8—13  m) B p = 50 m  20 mas 200 m  5 mas K band (2  m) B p = 50 m  4 mas 200 m  1 mas Diffraction Limit (8m) N band  0.3” K band  60 mas BpBp Beam combiner Optical Path Difference Delay line to compensate OPD 3 Telescopes  Imaging OK, but not easy

7 Expanding dust shell IR interferometry of Mira stars Mid-IR (N band) Dust formation Mira variables: Large variability amplitude ~ 9 mag (in V) Photosphere Spectro-interferometry Spatial + Spectral resolution Near-IR (JHK) “Warm Molecular layers”, or “MOLsphere”, 1000—2000K, 2—5 Rstar MIDI AMBER

8 8.0  m 13.3  m MIDI observation Spectrally dispersed fringes extracted from raw data

9 MIDI + VINCI observations of O-rich Mira RR Sco H 2 O+SiO emission Dust emission Stellar continuum size (Photospheric size) Photosphere MOLsphere (H 2 O, SiO, CO) Dust shell

10 Multi-epoch MIDI observations of the C-rich Mira star V Oph O-rich Mira stars Warm molecular layers (H 2 O, SiO) 1000--1700K, 2--3 Rstar Optically thick (  line  ~1000) Spectroscopy + Interferometry C-rich Mira stars Circumstellar material close to the star  Dust or gas ? (or both?) Little mid-IR interferometry on optically bright (=not so dusty) C-rich Miras  V Oph C 2 H 2     band (< 9  m)  band (> 11  m) Dust Amorphous Carbon SiC (11.3  m) MIDI Spectro-interferometry

11 Multi-epoch MIDI observations of the C-rich Mira star V Oph UT1-UT4 UT2-UT4 UT2-UT3 Same Bp & P.A. N-band visibilities show temporal variations

12 Estimated photospheric size Temporal variation of 8—13  m angular size of V Oph N-band Uniform Disk Diameter N-band angular sizes are remarkably larger than the star itself. The object appears the smallest at minimum light (when faintest).

13 Dust Shell Modeling Optically thin dust shell (Amorphous carbon + SiC)  Monte Carlo code (Ohnaka et al. 2006) SED + N-band Visibility fitting Interpretation of MIDI data on V Oph (1) Dust shell model Dust shell Amorphous carbon (featureless) + SiC (11.3  m) Inner boundary = 2.5 Rstar  Tdust = 1600K  Condensation Temperature Expanding dust shell

14 Estimated photospheric size Dust shell model compared to MIDI observations N-band Uniform Disk Diameter N-band spectra Phase 0.18 Phase 0.49 Phase 0.65 C 2 H 2    band C 2 H 2  band SiC Estimated photospheric size

15 Optically thick emission from C 2 H 2     band (< 9  m)  band (> 11  m) (ad hoc) Modeling Hot and cool C 2 H 2 layers (constant temperatures, densities)  Line opacity calculated analytically (Band model, Tsuji 1984) Optically thin dust shell (Amorphous carbon + SiC)  Monte Carlo code (Ohnaka et al. 2006) Interpretation of MIDI data on V Oph (2): C 2 H 2 layers + dust shell (Ohnaka et al. 2007, A&A, 466, 1099) C 2 H 2 gas Dust shell Amorphous carbon (featureless) + SiC (11.3  m) Inner boundary = 2.5 Rstar  Tdust = 1600K  Condensation Temperature Expanding dust shell

16 Modeling for 3 epochs Optically thick emission from C 2 H 2  Angular size larger ( 12  m) Extended, dense C 2 H 2 layers in C-rich Mira stars H 2 O layers in O-rich Mira stars

17 Model for post-maximum (phase = 0.18) Photospheric size

18 Phase dependence of the C 2 H 2 layers and the dust shell C 2 H 2 Radius C 2 H 2 Column Density Dust Optical Depth

19 How to explain the phase dependence Shock front C 2 H 2 formation Series of “snapshots” of a dynamical atmosphere (shock wave passage), Nowotny et al. (2005) Dust formation Diluted New dust formation C 2 H 2 formation C 2 H 2 layers: dense, extended Dust opacity: high C 2 H 2 layers: less dense, small Dust opacity: low C 2 H 2 layers: dense, extended Dust opacity: high dM/dt = 10 -6 M  /yr dM/dt = 10 -8 M  /yr (V Oph) Post-Maximum Minimum Post-Minimum

20 Conclusion & Outlook C-rich version of the warm molecular layers (C 2 H 2 ) Phase dependence of the mid-IR angular size: The object appears the smallest at minimum light. Observed N-band visibilities and spectra can be explained by the C 2 H 2 layers + dust shell model. Dust formation zone not well constrained (baselines were too long).  Better (u,v) coverage with ATs. O-rich Miras: MIDI/AT program on 3 Miras C-rich Miras: MIDI+VISIR+AMBER program on 1 Mira Non-Mira AGB stars (majority of AGB stars) Very small variability amplitudes, but substantial mass loss

21 Estimated photospheric size Temporal variation of N-band angular size of V Oph N-band Uniform Disk Diameter N-band spectra Phase 0.18 Phase 0.49 Phase 0.65 C 2 H 2    band C 2 H 2  band SiC UT1-UT4 UT2-UT4 UT2-UT3 Estimated photospheric size

22 MIDI + VINCI observations of O-rich Mira RR Sco Warm molecular layer makes the star appear larger in MIR than in NIR Dust shell emission is responsible for the size increase beyond 10  m H 2 O+SiO emission Dust emission Stellar continuum size silicate 20%, corundum 80% ~1400K, 2.3 R *, column densities = 10 20 --10 21 cm -2 Inner radius = 7--8 R *, Tin = 700--800 K, (Large-amplitude pulsation may explain the formation of warm H 2 O layers)

Download ppt "Temporal variations of the circumstellar environment of the Mira star V Oph Keiichi Ohnaka Max-Planck-Institut für Radioastronomie ESO Santiago Seminar."

Similar presentations

Stellar Evolution. The Mass-Luminosity Relation Our goals for learning: How does a star’s mass affect nuclear fusion?

Stellar Evolution. The Mass-Luminosity Relation Our goals for learning: How does a star’s mass affect nuclear fusion?
Nebula to Protostar Giant molecular clouds within a nebula contract under the gravitational pressure, increasing its thermal energy. CO, NO, OH- Giant.

Nebula to Protostar Giant molecular clouds within a nebula contract under the gravitational pressure, increasing its thermal energy. CO, NO, OH- Giant.
Star Formation and the Interstellar Medium

Star Formation and the Interstellar Medium
Sakurai’s Object Dr H F Chau Department of Physics HKU Dr H F Chau Department of Physics HKU A Case Of Superfast Stellar Evolution.

Sakurai’s Object Dr H F Chau Department of Physics HKU Dr H F Chau Department of Physics HKU A Case Of Superfast Stellar Evolution.
Asymptotic Giant Branch. Learning outcomes Evolution and internal structure of low mass stars from the core He burning phase to the tip of the AGB Nucleosynthesis.

Asymptotic Giant Branch. Learning outcomes Evolution and internal structure of low mass stars from the core He burning phase to the tip of the AGB Nucleosynthesis.
Science with the Very Large Telescope Interferometer (VLT-I) Jean-Baptiste Le Bouquin (ESO, Chile) for VLTI Team, AMBER team, MIDI team, PRIMA team… The.

Science with the Very Large Telescope Interferometer (VLT-I) Jean-Baptiste Le Bouquin (ESO, Chile) for VLTI Team, AMBER team, MIDI team, PRIMA team… The.
The Nature and Origin of Molecular Knots in Planetary Nebulae Sarah Eyermann – U. of Missouri Angela Speck – U. of Missouri Margaret Meixner – STScI Peter.

The Nature and Origin of Molecular Knots in Planetary Nebulae Sarah Eyermann – U. of Missouri Angela Speck – U. of Missouri Margaret Meixner – STScI Peter.
Objectives Determine the effect of mass on a star’s evolution.

Objectives Determine the effect of mass on a star’s evolution.
VLBI observations of two 43-GHz SiO masers in R Cas Jiyune Yi KVN Korea VLBI Network ( KVN ) group Korea Astronomy and Space Science Institute In collaboration.

VLBI observations of two 43-GHz SiO masers in R Cas Jiyune Yi KVN Korea VLBI Network ( KVN ) group Korea Astronomy and Space Science Institute In collaboration.
Studying circumstellar envelopes with ALMA

Studying circumstellar envelopes with ALMA
Astromineralogy Astromineralogy July 12 2013 --- Lecture 13--- Summer 2013 H.-P. Gail & A. Tamanai Lecture 13, SS 2013Astronimeralogy1.

Astromineralogy Astromineralogy July Lecture Summer 2013 H.-P. Gail & A. Tamanai Lecture 13, SS 2013Astronimeralogy1.
Armando DOMICIANO de SOUZA Main collaborators: O. Chesneau (OCA, F), T. Driebe (MPIfR, D), K-.H. Hofmann (MPIfR, D), S. Kraus (MPIfR, D), A. Miroshnichenko.

Armando DOMICIANO de SOUZA Main collaborators: O. Chesneau (OCA, F), T. Driebe (MPIfR, D), K-.H. Hofmann (MPIfR, D), S. Kraus (MPIfR, D), A. Miroshnichenko.
The origin of the (lighter) elements The Late Stages of Stellar Evolution Supernova of 1604 (Kepler’s)

The origin of the (lighter) elements The Late Stages of Stellar Evolution Supernova of 1604 (Kepler’s)
The Deaths of Stars. What Do You Think? Will the Sun someday cease to shine brightly? If so, how will this occur? What is a nova? How does it differ from.

The Deaths of Stars. What Do You Think? Will the Sun someday cease to shine brightly? If so, how will this occur? What is a nova? How does it differ from.
Towards abundance determination from dynamic atmospheres Michael T. Lederer, Thomas Lebzelter, Bernhard Aringer, Walter Nowotny, Josef Hron Department.

Towards abundance determination from dynamic atmospheres Michael T. Lederer, Thomas Lebzelter, Bernhard Aringer, Walter Nowotny, Josef Hron Department.
Stellar Birth and Stellar Structure Dense “cold” clouds in the Interstellar Medium, or the ISM 75% hydrogen 25% helium and trace amounts of : carbon, oxygen,

Stellar Birth and Stellar Structure Dense “cold” clouds in the Interstellar Medium, or the ISM 75% hydrogen 25% helium and trace amounts of : carbon, oxygen,
The Interstellar Medium Astronomy 315 Professor Lee Carkner Lecture 19.

The Interstellar Medium Astronomy 315 Professor Lee Carkner Lecture 19.
Stars science questions Origin of the Elements Mass Loss, Enrichment High Mass Stars Binary Stars.

Stars science questions Origin of the Elements Mass Loss, Enrichment High Mass Stars Binary Stars.
Post Main Sequence Evolution PHYS390 (Astrophysics) Professor Lee Carkner Lecture 15.

Post Main Sequence Evolution PHYS390 (Astrophysics) Professor Lee Carkner Lecture 15.
Post-AGB evolution. Learning outcome evolution from the tip of the AGB to the WD stage object types along the post-AGB evolution basics about planetary.

Post-AGB evolution. Learning outcome evolution from the tip of the AGB to the WD stage object types along the post-AGB evolution basics about planetary.

Similar presentations

Ads by Google