3.5 Quasi-normal modes of a black hole
In 1970, Vishveshwara [381
] discussed a gedanken experiment, similar in philosophy to Rutherford’s
(real) experiment with the atom. In Vishveshwara’s experiment, he scattered gravitational radiation off a
black hole to explore its properties. With the aid of such a gedanken experiment, he demonstrated for the
first time that gravitational waves scattered off a black hole will have a characteristic waveform,
when the incident wave has frequencies beyond a certain value, depending on the size of the
black hole. It was soon realized that perturbed black holes have quasi-normal modes (QNMs)
of vibration and in the process emit gravitational radiation, whose amplitude, frequency and
damping time are characteristic of its mass and angular momentum [298
, 221]. We will discuss
in Section 6.4 how observations of QNMs could be used in testing strong field predictions of general
relativity.
We can easily estimate the amplitude of gravitational waves emitted when a black hole forms at a
distance
from Earth as a result of the coalescence of compact objects in a binary. The effective
amplitude is given by Equation (20), which involves the energy
put into gravitational waves and the
frequency
at which the waves come off. By dimensional arguments
is proportional to the total
mass
of the resulting black hole. The efficiency at which the energy is converted into
radiation depends on the symmetric mass ratio
of the merging objects. One does not know the
fraction of the total mass emitted nor the exact dependence on
. Flanagan and Hughes [164
]
argue that
. The frequency
is inversely proportional to
; indeed, for
Schwarzschild black holes
. Thus, the formula for the effective amplitude takes the form
where
is a number that depends on the (dimensionless) angular momentum
of the black hole and
has a value between 0.7 (for
, Schwarzschild black hole) and 0.4 (for
, maximally
spinning Kerr black hole). For stellar mass black holes at a distance of 200 Mpc the amplitude is:
For SMBHs, even at cosmological distances, the amplitude of quasinormal mode signals is pretty large:
In the first case we have a pair of
black holes inspiraling and merging to form a single black hole.
In this case the waves come off at a frequency of around 500 Hz [cf. Equation (13)]. The initial
ground-based network of detectors might be able to pick these waves up by matched filtering, especially
when an inspiral event precedes the ringdown signal. A
black hole plunging into a
black hole at a distance of 6.5 Gpc (
) gives out radiation at a frequency of
about 15 mHz. Note that in the latter case the radiation is redshifted from 30 mHz to 15 mHz.
Such an event produces an amplitude just large enough to be detected by LISA. At the same
distance, a pair of
SMBHs spiral in and merge to produce a fantastic amplitude of
, way above the LISA background noise. In this case, the signals would be given off
at about 7.5 mHz and will be loud and clear to LISA. It will not only be possible to detect
these events, but also to accurately measure the masses and spins of the objects before and
after merger and thereby test the black hole no-hair theorem and confirm whether the result of
the merger is indeed a black hole or some other exotic object (e.g., a boson star or a naked
singularity).