1. Reissner-Nordström Metric �and�Charged Black Holes Jordan Gallagher and Jenn LeNestour
2. Reissner-Nordström Metric Generalized Schwarzschild metric for a black hole that has
An electric charge
No angular momentum
3. Reissner-Nordström�Metric - Derivation Derivation process is similar to that of the Schwarzschild metric
We assume spherical symmetry
By Birkhoff’s Theorem, the metric will have the familiar form of:
4. Reissner-Nordström�Metric - Derivation However, we cannot set the Stress-Energy tensor to zero as in the Schwarzschild derivation
There is electric charge present, and hence a non-zero Maxwell Tensor
By equating the Ricci Tensor with the non-zero Maxwell Tensor, and after working through a lot of math, one arrives at the Reissner-Nordström Metric
5. What is a Black Hole? Object with a very large gravitational field
To escape you must be traveling faster than the speed of light
Since no light escapes, black holes will always appear dark
6. Static Black Hole Structure Photon Sphere at 1.5 RS
Singularity in the centre
Event Horizon at RS
7. Static Black Hole Structure Photon Sphere
Lowest possible orbit around a black hole
Speed of c required to maintain orbit
Light will orbit temporarily
Orbits usually disturbed by other photons or particles and the photons will fall to the event horizon
8. Static Black Hole Structure Singularity
Black hole’s mass is compressed into a region with zero volume
Density, gravitational pull, and curvature of space-time are then infinite
Can be thought of as a “place in time” since space and time change roles at the event horizon
9. Static Black Hole Structure Event Horizon
Physically
“Point of no return”�Nothing that passes this sphere can return
Required escape velocity greater than c
Time and space effectively switch roles
10. Static Black Hole Structure Event Horizon
Mathematically
Coordinate singularity of the metric�Can choose alternate coordinates (Eddington-Finkelstein) to show it isn’t a physical singularity
Point after which the coefficients of dr and dt change signs
11. Event Horizons The “Horizon Function” H(r) is given by,
H(r) = (1 - 2M/r + Q2/r2)
and is quadratic with 2 distinct roots
These two roots are given by;
r+ = M + (M2 + Q2)1/2
r- = M + (M2 + Q2)1/2
These two roots correspond to two different event horizons, one at r+ and the other at r-
12. Event Horizons Schwarzschild black hole
r+ = 2M
r- = 0
13. Event Horizons The outer horizon at r+ is much like the event horizon of 2M for a Schwarzschild black hole
Space and time change roles upon crossing the outer horizon as “normal”
At the inner horizon, also known as the Cauchy horizon, something remarkable happens, the space and time co-ordinates change roles again.
Inside the Cauchy horizon, time and space behave as “normal”, and the singularity is space-like
14. Spacetime Diagram for an R-N Black Hole Yellow = Radially inward light rays
Orange = Radially outward light rays
Purple (-) = Constant Time
Purple (|) = Constant Radius
Red = Event Horizons
15. Entering a Black Hole Static
Once past the event horizon, you would be stretched due to tidal forces
Due to time-space changing roles, the singularity is a point in time, and cannot be avoided
As you approached the singularity the gravitational force will increase and you will be torn apart
You become part of the black hole
16. Entering a Black Hole Penrose Diagram
Space-time diagram
Shows movement in a black hole
17. Entering a Black Hole Reissner-Nordstrom
You would still be broken apart by the tidal forces
Within the Outer Horizon the singularity would appear as a place in time
Within the Inner Horizon time and space change roles again and so the singularity appears as a place in space, which is avoidable
18. Entering a Black Hole Reissner-Nordstrom
Possible to pass “through” the singularity
Find yourself in another black hole
Would cross both event horizons and end up with the same velocity leaving as you did entering
mirror-image of your worldline
19. Entering a Black Hole Penrose Diagram
Space-time diagram
Shows movement in a black hole
Possible to transfer into other Universes
20. Do Black Holes Exist�Without Angular Momentum? Black Hole Formation
Gravitational collapse of a star
Collisions between neutron stars
Pressure from the Big Bang (small Primordial Black Holes)
Black holes can then absorb mass from interstellar gas and dust, as well as other stars and planets to become larger
21. Do Black Holes Exist�Without Angular Momentum? All of these methods will result in a black hole with some angular momentum
Black holes with no angular momentum are only theoretical
22. Existence of Charged Black Holes Electric charge, over large scales, is pretty effective at “neutralizing” itself
That is, macroscopic objects, especially astrophysical ones, tend to be electrically neutral
The size of the Cauchy horizon depends directly on the magnitude of the charge of the black hole
For a 3 solar mass black hole, a charge of�~ 1019 C is required to create a Cauchy horizon of radius 0.001M
Such a charge would require ~1038 electrons, and the resultant electric field would rip apart atoms with the greatest of ease
23. Do Reissner-Nordström Black Holes Exist? No, they are just theoretical!
