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Biggest black hole in the cosmos discovered

The most massive known black hole in the universe has been discovered, weighing

in with the mass of 18 billion Suns. Observing the orbit of a smaller black

hole around this monster has allowed astronomers to test Einstein's theory of

general relativity with stronger gravitational fields than ever before.

The black hole is about six times as massive as the previous record holder and

in fact weighs as much as a small galaxy. It lurks 3.5 billion light years

away, and forms the heart of a quasar called OJ287. A quasar is an extremely

bright object in which matter spiralling into a giant black hole emits copious

amounts of radiation.

But rather than hosting just a single colossal black hole, the quasar appears

to harbour two - a setup that has allowed astronomers to accurately 'weigh' the

larger one.

The smaller black hole, which weighs about 100 million Suns, orbits the larger

one on an oval-shaped path every 12 years. It comes close enough to punch

through the disc of matter surrounding the larger black hole twice each orbit,

causing a pair of outbursts that make OJ287 suddenly brighten.

General relativity predicts that the smaller hole's orbit itself should rotate,

or precess, over time, so that the point at which it comes nearest its

neighbour moves around in space - an effect seen in Mercury's orbit around the

Sun, albeit on a smaller scale.

Bright outbursts

In the case of OJ287, the tremendous gravitational field of the larger black

hole causes the smaller black hole's orbit to precess at an incredible 39 each

orbit. The precession changes where and when the smaller hole crashes through

the disc surrounding its larger sibling.

About a dozen of the resulting bright outbursts have been observed to date, and

astronomers led by Mauri Valtonen of Tuorla Observatory in Finland have

analysed them to measure the precession rate of the smaller hole's orbit. That,

along with the period of the orbit, suggests the larger black hole weighs a

record 18 billion Suns.

A couple of other black holes have been estimated to be as massive, but their

masses are less certain, says Valtonen. That's because the estimates were based

on the speed of gas clouds around the black holes, and it is not clear whether

the clouds are simply passing by the black holes or actually orbiting them.

But Tod Strohmayer of NASA's Goddard Space Flight Center in Maryland, US, says

he is not convinced that Valtonen's team has really measured the mass of the

large black hole in OJ287 accurately.

That's because only a handful of the outbursts have been measured with high

precision, making it difficult to determine if the precession scenario is

responsible for the outbursts. "Obviously, if subsequent timings continue to

agree with the model, then that would provide further support," he told New

Scientist.

No limit

Just how big can black holes get? Craig Wheeler of the University of Texas in

Austin, US, says it depends only on how long a black hole has been around and

how fast it has swallowed matter in order to grow. "There is no theoretical

upper limit," he says.

The new research also tested another prediction of general relativity - that

the black holes should spiral towards each other as they radiate energy away in

the form of gravitational waves, or ripples in space. This radiation affects

the timing of the disc crossings and their accompanying outbursts.

The most recent outburst occurred on 13 September 2007, as predicted by general

relativity. "If there was no orbital decay, the outburst would have been 20

days later than when it actually happened," Valtonen told New Scientist, adding

that the black holes are on track to merge within 10,000 years.

Wheeler says the observations of the outbursts fit closely with the

expectations from general relativity. "The fact that you can fit Einstein's

theory [so well] ... is telling you that that's working," he says.