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Transcript
Stellar Disruptions of
Super Massive Black
Holes
Ron Caplan
March 7, 2003
Outline
Overview of Black Holes
The Stellar Disruption Event
The Flare
The Stellar Wind
Core Remnants
Observations
When a star gets too close to a super massive black hole, it
becomes disrupted causing a flare. Detecting these flares is a
way to find such holes, as well as learn about them. The study
of super massive black holes is important for galaxy evolution
studies.
Outline Structure Accretion Disruption Flare Wind Remnants Observation End
Ron
Caplan
Black Hole Structure
Space-Time Geometry
How to Make a BH
Event Horizon
Singularity
Tidal Forces
Stellar vs. Super Massive
Outline Structure Accretion Disruption
Flare Wind Remnants Observation End
Ron
Caplan
Black Hole Accretion Disks
Outline
Friction and Heat
Active Galactic Nuclei
Thermal Radiation
Gamma-Ray Bursts
Structure Accretion Disruption Flare Wind Remnants Observation End
Ron
Caplan
The Stellar Disruption Event
Velocity Dispersion – Capture of Star Inevitable
Once Every 10,000 Years in an Average Galaxy
~Half of Star is Ejected, ~Half of Star is Accreted
Outline Structure Accretion Disruption
Flare Wind Remnants Observation End
Ron
Caplan
The Flare
Material Left from Star
Forms Accretion Disk
Disk Radiates Large Energies
Mostly in UV – X-Ray
Disk Can Last Up to a Few
Years Before Being Consumed
by the Hole
Outline Structure Accretion
Disruption Flare Wind Remnants Observation End
Ron
Caplan
The Wind
The material that gets blown off, does so at a very high
velocity
Energy of this stellar wind is equal to the that from a
supernovae
It can cause shockwaves in the surrounding ISM, as well as
create shells
Outline Structure Accretion Disruption
Flare Wind Remnants Observation End
Ron
Caplan
Stellar Remnants
When a large red giant star is disrupted, there is a possibility its
core survives, and is ejected very fast away from the galactic
center
This core star would be a Helium star much like a White Dwarf
Outline Structure Accretion Disruption Flare
Wind Remnants Observation End
Ron
Caplan
Observations
Flare
Light Frequency Problem?
Wind and Atmosphere to the Rescue
How many??
UCSB Lubin Group
Core Remnants
Live Longer than Flare
Harder to See – HST, Keck
Very Similar to Standard White
Dwarfs
Circular Patterns
Outline Structure Accretion Disruption Flare Wind Remnants Observation End
Ron
Caplan
The End
Any Questions?