By ANDY FLEMING
Imagine a sphere more than 2 million miles
across -- eight times the distance from Earth to the Moon -- spinning so fast
that its surface is traveling at nearly the speed of light. Such an object
exists: the supermassive black hole at the centre of the spiral galaxy NGC
1365.
Astronomers measured its jaw-dropping spin rate
using new data from the Nuclear Spectroscopic Telescope Array, or NuSTAR, and
the European Space Agency's XMM-Newton X-ray satellites.
"This is the first time anyone has
accurately measured the spin of a supermassive black hole," said lead
author Guido Risaliti of the Harvard-Smithsonian Centre for Astrophysics (CfA)
and INAF -- Arcetri Observatory.
This research is being published in the Feb. 28
issue of the journal Nature, and featured in a NASA media teleconference on
Feb. 27th.
A black hole's gravity is so strong that, as the
black hole spins, it drags the surrounding space along. The edge of this
spinning hole is called the event horizon. Any material crossing the event
horizon is pulled into the black hole. In spiraling matter collects into an
accretion disk, where friction heats it and causes it to emit X-rays.
Risaliti and his colleagues measured X-rays from
the centre of NGC 1365 to determine where the inner edge of the accretion disk
was located. This Innermost Stable Circular Orbit -- the disk's point of no
return -- depends on the black hole's spin. Since a spinning black hole
distorts space, the disk material can get closer to the black hole before being
sucked in.
Astronomers want to know the black hole's spin
for several reasons. The first is physical -- only two numbers define a black
hole: mass and spin. By learning those two numbers, you learn everything there
is to know about the black hole.
Most importantly, the black hole's spin gives
clues to its past and by extension the evolution of its host galaxy.
"The black hole's spin is a memory, a
record, of the past history of the galaxy as a whole," explained Risaliti.
Although the black hole in NGC 1365 is currently
as massive as several million Suns, it wasn't born that big. It grew over
billions of years by accreting stars and gas, and by merging with other black
holes.
Spin results from a transfer of angular
momentum, like playing on a children's swing. If you kick at random times while
you swing, you'll never get very high. But if you kick at the beginning of each
downswing, you go higher and higher as you add angular momentum.
Similarly, if the black hole grew randomly by
pulling in matter from all directions, its spin would be low. Since its spin is
so close to the maximum possible, the black hole in NGC 1365 must have grown
through "ordered accretion" rather than multiple random events.
Studying a supermassive black hole also allows
theorists to test Einstein's general theory of relativity in extreme
conditions. Relativity describes how gravity affects the structure of
space-time, and nowhere is space-time more distorted than in the immediate
vicinity of a black hole.
The team also has additional observations of NGC
1365 that they will study to determine how conditions other than black hole
spin change over time. Those data are currently being analysed. At the same
time, other teams are observing several other supermassive black holes with
NuSTAR and XMM-Newton.
Original Source: Harvard-Smithsonian Centre for
Astrophysics
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