Stellar Winds and Mass Loss
Brian Baptista
Summary
Observations of mass loss Mass loss parameters for different
types of stars Winds colliding with the ISM Effects on stellar evolution
Some History
Nova like objects are discovered
Diagnostics of mass laws are generated for hot stars
Mass loss rated from cool giants were observed
Finally, time dependant mechanisms are studied.
How do we define mass loss?
Two basic Parameters The mass loss rate, , or the amount of mass loss per
unit of time. This is an important quantity for stellar evolution as stars
with different mass loss rated will evolve differently. The terminal velocity of the wind, , or the velocity the
ejecta have at large distances from the star. Different ejection theories predict different velocities, so it
can be used to determine the ejection mechanism.
The energy deposited into the ISM per unit time is,
M
v
2
2
1
vMKE
M-dot
General form for a spherically symmetric wind.
Use the mass continuity equation. The same amount of gas per unit time
flows through a sphere at any distance.
)()(4 2 rvrrM
Terminal Velocity
Gas that escapes from upper atmospheres of stars, starts at small radial velocity.
The gas is then accelerated to the terminal velocity, at large r.
Often the terminal velocity is approximated to,
r
vvRrv
r
Rvvvrv oooo
),,,(11)()( **
Hey wait what is beta?
Beta describes how steep the velocity profile is.
Hot stars have steep profiles with β=0.8
Cool stars have smaller accelerations β=2.0
Observations of Mass Loss
P Cygni Profiles Emission Lines
Ions Molecules
Infrared and radio excesses
P Cygni Profiles
P Cygni is the prototype, and was observed by Snow and Morton in 1976
Most are observed using UV resonance lines.
C IV, N V, and Si IV are use in O to early B
C II is used in late B to A Mg II is used in late B to M
P Cygni Profiles (cont.)
The star emits a continuum
The tube directly between the star and observer absorbs line absorbs everything between v=0-v∞
The region around the star contains velocities between -v∞ and v∞
“So what”
Profiles caused by a strongly saturated line will give us the velocity profile of the region Saturated lines are most sensitive to the velocity
profile, because the Doppler core will give a hard edge at v∞
Profiles due to unsaturated lines can give us the mass loss rate These profiles are fit using the above velocity
profile, with different numbers of absorbing ions, until the profile matches the observed unsaturated profile
The first group to make mass loss determinations was Lamers and Morton in 1976
Emission Lines
The biggest advantage is that this can be used to study mass loss from the ground. The star must have a high mass loss rate
on the order of 10-6M/yr Most notable is Hα Also, Paschen and Brackett lines of He II Wolf-Rayet stars are dominated by lines
that form in high density winds
Emission Lines (continued)
The lines typically have Doppler widths of a few hundred km/s This is not the terminal velocity of the winds These lines are formed near the star
The lines are typically formed by recombination The emissivity is proportional to ρ2
These lines must be formed in regions of high density
Mass loss determination
Since the gas is expanding radial from the star a photon that is created by recombination will be created at a Doppler shift that is greater than twice the thermal width of the line Any photon created by this process will escape
the region We can determine a total line luminosity
The mass loss will be determined by
lLvM
~
Emission lines for Molecules
The same approach can be used for molecules around cool stars The advantage is that they will from at large
distances from the star, 104R*. CO J=1→0 lines are typically used The velocities at this range are much lower than
the escape speed of the star, but they still indicate mass loss
Knapp and Morris derived an expression for the CO mass loss rate in 1985
85.02216105~
COB fDvTM
Infrared and Radio Excesses
Radio excess has only been measured for a few stars As a 10-6M/yr would correspond to a few mJy
Infrared excesses have men more heavily observed IR emission is due to free-free emission within
1.5 stellar radii from the surface of the star. These excess can be only a few tenths of
magnitudes The mass loss rate from IR excess requires an
accurate determination of the velocity law
Mass loss rates
O and B type stars These have been the most heavily studied The terminal velocity of the ejecta is comparable
to the star’s escape velocity, but can depend on the effective temperature of the star due to radiation pressure
Krudritzki et al. determined that for galactic stars, the loss rate is basically independent of the stellar mass
6*2/1
* 10log07.237.1log
LRvM
Mass loss rates (continued)
Central stars in planetary nebulae have very low mass loss rates Typical values are /yr and terminal
velocities of 3000 km/s Cool stars such as red super giants also
have low mass loss rates 6 G3 to M2 stars of class II and Ia that are in
binary systems have been measured These are between 10-9 and 10-6 M/yr The terminal velocities of 17 and 160 km/s
M~M -810
Mass loss rates (continued)
AGB stars have extremely high mass loss rates
The rate is linked to the period of pulsation of the stars
The rate seems to saturate at about 10-4M /yr
These however have low terminal velocities of 5-25 km/s
Interactions with the ISM
Winds deposit enriched materials back into the ISM, and massive stars can even create dust particulate
Fast winds can collide with previously ejected winds These can explain hot bubble around hot stars, ring
nebulae around WR stars, and ultra compact HII regions, as well as PNe
The time evolution of different models can be used to create a range of different out comes Rotation and clumping can cause different shock
structures in the ejecta Rotation can cause a higher density mass loss region in the
equatorial regions Clumping can cause mass loading, and slow the shocks
down
Effects on evolution
Mass loss can cause changes in surface composition When the outer layers of an atmospheres are blown off, it
exposes the convective cores of the stars These core will show an extreme over abundance of heavy
elements Formation of PNe Lack of luminous red super giants
The massive stars loose so much mass that their have insufficient mass to become convective
Formation of white dwarves Mass loss is responsible for stars that have masses less than 8M
not becoming SN, but instead becoming white dwarfs
The winds can remove up to 6.6 M worth of material
Effects on evolution (continued)
For stars with masses greater than 30M mass loss can change the amount of time that a star spends on the main sequence
Since the mass is so large for these stars throughout the main sequence lifetime The luminosity over the
lifetime of the star can change
The lower luminosity means that the star will have a longer MS lifetime
The final mass that the star will have is effected