Presentation is loading. Please wait.

Presentation is loading. Please wait.

T Tauri Stars: An Overview Colette Salyk Ge132. What is a T Tauri star? 1st Answer: Observational –Hydrogen Balmer and Ca II H and K emission –Often emission.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "T Tauri Stars: An Overview Colette Salyk Ge132. What is a T Tauri star? 1st Answer: Observational –Hydrogen Balmer and Ca II H and K emission –Often emission."— Presentation transcript:

1 T Tauri Stars: An Overview Colette Salyk Ge132

2 What is a T Tauri star? 1st Answer: Observational –Hydrogen Balmer and Ca II H and K emission –Often emission of Fe I –Forbidden [O I] and [S II] emission –Strong Li absorption –IR -> sub-mm excess –UV excess –Found in dusty regions- proper motions correlated –Off main sequence –Sometimes associated with disks and/or outflows

3 What is a T Tauri star? 2nd Answer: Theoretical –Low-mass (0.2-2 M  ) young (PMS) star –Class II –Often accompanied by disk of gas and dust –Active (star/disk interactions, fast rotation) –Sometimes releasing mass via polar outflows

4 IR Excess Near-IR: hot inner disk: dust and gas mid-IR -> sub-mm: dusty disk emission Solar + accretional energy

5 H  emission n=3->n=2 transition = 6562.8 Å Requires high energy photons, close to star (also seen in solar chromosphere) Used to model accretion –Asymmetric shape –Doppler broadening >100 km/s (supersonic)

6 Strong Li I Absorption = 6707.76 Å ; 2 P 3/2 -> 2 S 1/2 = 6707.91 Å ; 2 P 1/2 -> 2 S 1/2 Li fragile, destroyed when in contact with high temperatures at base of convecting region of stars, so strong Li = young In TTSs, log[n Li ] = 3 ; similar to meteorites (in sun, log[n Li ] = 1; log[n H ]≡12)

7 Forbidden [O I] & [S II] emission Very low emission probabilities->low density environment Probe outer regions of polar jets Doppler broadened ->high speeds Blueshifted (red part partially hidden)

8 Ca II H & K, Fe I emission Ca II H – = 3968.5 Å – 2 S 1/2 <- 2 P 1/2 Ca II K – = 3933.7 Å – 2 S 1/2 <- 2 P 3/2 Fe I – = 4062.4 Å ; 3 P 1 <- 3 S 1 – = 4132.1 Å ; 3 F 2 <- 3 F 3 –Probably due to resonant fluorescence All similar to solar chromosphere, but actually due to extended atmosphere and star/disk interactions

9 Implications / The Future Initial Mass Function ( N(M) ) –Effect of environment on formation Mass of disk correlations? (environment, mass of parent star, age) Young Star/Disk Interactions –Magnetic fields –Accretion –Mass loss Evolution timescales –How long do outflows/disks last? –(How long do planets have to form?)

Download ppt "T Tauri Stars: An Overview Colette Salyk Ge132. What is a T Tauri star? 1st Answer: Observational –Hydrogen Balmer and Ca II H and K emission –Often emission."

Similar presentations

Accretion and Variability in T Tauri Disks James Muzerolle.

Accretion and Variability in T Tauri Disks James Muzerolle.
T Tauri Stars Kate Barnes A540. T Tauri Stars: Background Very young, solar-type stars ~10 7 yrs Low mass 0.5 M < M < 2 M Name: T Tauri, found in Taurus-Auriga.

T Tauri Stars Kate Barnes A540. T Tauri Stars: Background Very young, solar-type stars ~10 7 yrs Low mass 0.5 M < M < 2 M Name: T Tauri, found in Taurus-Auriga.
Stellar Evolution. Evolution on the Main Sequence Zero-Age Main Sequence (ZAMS) MS evolution Development of an isothermal core: dT/dr = (3/4ac) (  r/T.

Stellar Evolution. Evolution on the Main Sequence Zero-Age Main Sequence (ZAMS) MS evolution Development of an isothermal core: dT/dr = (3/4ac) (  r/T.
General Properties Absolute visual magnitude M V = 4.83 Central temperature = 15 million 0 K X = 0.73, Y = 0.25, Z = 0.02 Initial abundances: Age: ~ 4.52.

General Properties Absolute visual magnitude M V = 4.83 Central temperature = 15 million 0 K X = 0.73, Y = 0.25, Z = 0.02 Initial abundances: Age: ~ 4.52.
The Birth of Solar Systems A solar system The disk condenses and dissipates Collapse of and interstellar cloud Formation of a protostar and disk.

The Birth of Solar Systems A solar system The disk condenses and dissipates Collapse of and interstellar cloud Formation of a protostar and disk.
Ch. 9 The Lives of Stars from Birth through Middle Age The Cone Nebula.

Ch. 9 The Lives of Stars from Birth through Middle Age The Cone Nebula.
Ge/Ay133 SED studies of disk “lifetimes” & Long wavelength studies of disks.

Ge/Ay133 SED studies of disk “lifetimes” & Long wavelength studies of disks.
Post Main Sequence Evolution PHYS390 (Astrophysics) Professor Lee Carkner Lecture 15.

Post Main Sequence Evolution PHYS390 (Astrophysics) Professor Lee Carkner Lecture 15.
The Formation and Structure of Stars

The Formation and Structure of Stars
Pre-Main Sequence Stars PHYS390 (Astrophysics) Professor Lee Carkner Lecture 13.

Pre-Main Sequence Stars PHYS390 (Astrophysics) Professor Lee Carkner Lecture 13.
Chapter 7 The Sun. Solar Prominence – photo by SOHO spacecraft from the Astronomy Picture of the Day site link.

Chapter 7 The Sun. Solar Prominence – photo by SOHO spacecraft from the Astronomy Picture of the Day site link.
The Sun- Our Star. The Sun- Our Star Star Parts: core radiation zone convection zone photosphere chromosphere corona solar wind.

The Sun- Our Star. The Sun- Our Star Star Parts: core radiation zone convection zone photosphere chromosphere corona solar wind.
YSOs: Young Stellar Objects Provide evidence for planet-forming nebular disks around stars Dusty cocoon surrounding YSO.

YSOs: Young Stellar Objects Provide evidence for planet-forming nebular disks around stars Dusty cocoon surrounding YSO.
Star Formation Astronomy 315 Professor Lee Carkner Lecture 12.

Star Formation Astronomy 315 Professor Lee Carkner Lecture 12.
The Deaths of Stars Chapter 10. Evolution off the Main Sequence: Expansion into a Red Giant Hydrogen in the core completely converted into He: H burning.

The Deaths of Stars Chapter 10. Evolution off the Main Sequence: Expansion into a Red Giant Hydrogen in the core completely converted into He: H burning.
Physics 681: Solar Physics and Instrumentation – Lecture 24 Carsten Denker NJIT Physics Department Center for Solar–Terrestrial Research.

Physics 681: Solar Physics and Instrumentation – Lecture 24 Carsten Denker NJIT Physics Department Center for Solar–Terrestrial Research.
Most meteorites formed in the earliest moments of solar system history Early solar system consisted of a planetary nebula-- dust and gas surrounding protostar.

Most meteorites formed in the earliest moments of solar system history Early solar system consisted of a planetary nebula-- dust and gas surrounding protostar.
THE SUN 1 million km wide ball of H, He undergoing nuclear fusion. Contains 99% of the mass in the whole solar system! Would hold 1.3 million earths!

THE SUN 1 million km wide ball of H, He undergoing nuclear fusion. Contains 99% of the mass in the whole solar system! Would hold 1.3 million earths!
Susan CartwrightOur Evolving Universe1 Atoms and Starlight n Why do the stars shine? l l planets shine by reflected sunlight—but what generates the Sun’s.

Susan CartwrightOur Evolving Universe1 Atoms and Starlight n Why do the stars shine? l l planets shine by reflected sunlight—but what generates the Sun’s.
Star and Planet Formation Sommer term 2007 Henrik Beuther & Sebastian Wolf 16.4 Introduction (H.B. & S.W.) 23.4 Physical processes, heating and cooling.

Star and Planet Formation Sommer term 2007 Henrik Beuther & Sebastian Wolf 16.4 Introduction (H.B. & S.W.) 23.4 Physical processes, heating and cooling.

Similar presentations

Ads by Google