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Scientists Find Black Hole's Point of No Return

Media Contact:
Elizabeth Thompson
thomson@mit.edu
617-258-5402

issued by Massachusetts Institute of Technology

January 9, 2006 CAMBRIDGE, Mass. -- By a score of 135 to zero, scientists at MIT and Harvard have found that a certain type of X-ray explosion common on neutron stars is never seen around black holes, as if the gas that fuels these explosions has vanished into a void.

This is strong evidence, the team said, for the existence of a theoretical border around a black hole called an event horizon, a point from beyond which nothing, not even light, can escape.

Dr. Ron Remillard of the MIT Kavli Institute in Cambridge, Mass., led the analysis and discusses his team's result today at a press conference at the 207th meeting of the American Astronomical Society in Washington. His colleagues are Dacheng Lin of MIT, and Randall Cooper and Prof. Ramesh Narayan of the Harvard-Smithsonian Center for Astrophysics in Cambridge.

The scientists studied a complete sample of transient X-ray sources detected with NASA's Rossi X-ray Timing Explorer during the last nine years. They detected 135 X-ray bursts from the 13 sources believed to be neutron stars, but none came from the 18 suspected black holes.

Gas accreted from a nearby star can accumulate on the hard surface of a neutron star, and it will eventually erupt in a thermonuclear explosion. The more massive compact objects in this study suspected of being black holes appeared to have no surface. Gas falling toward the black hole seems to disappear.

"Event horizons are invisible by definition, so it seems impossible to prove their existence," said Remillard. "Yet by looking at dense objects that pull in gas, we can infer whether that gas crashes and accumulates onto a hard surface or just quietly vanishes. For the group of suspected black holes we studied, there is a complete absence of surface explosions called X-ray bursts."

A black hole forms when a very massive star runs out of fuel. Without energy to support its mass, the star implodes. If the star is over 25 times more massive than our sun, the core will collapse to a point of infinite density with no surface. Within a boundary of about 50 miles from the black hole center, gravity is so strong that not even light can escape its pull. This boundary is the theoretical event horizon.

Stars about 10 to 25 solar masses will collapse into compact spheres about 10 miles across, called neutron stars. These objects have a hard surface and no event horizon.

Black holes and their neutron star cousins are sometimes located in binary systems, orbiting a relatively normal star companion. Gas from these stars, lured by strong gravity, can flow toward the compact object periodically. This process, called accretion, releases large amounts of energy, predominantly in the form of X-rays.

Gas can accumulate on a neutron star surface. When conditions are ripe, the gas will ignite in a thermonuclear explosion that is visible as a one-minute event called a type I X-ray burst. The suspected black holes --- that is, the more massive types of compact objects in this study --- behave as if they have no surface and are located behind event horizons.

The idea of using the absence of X-ray bursts to confirm the presence of event horizons in black holes was proposed in 2002 by Harvard's Narayan and Dr. Jeremy Heyl of the University of British Columbia in Vancouver.

"It was a very simple but powerful idea," said Narayan. "Type I bursts are easy to identify. We can compare burst statistics with the quantitative predictions of our burst model for a variety of compact objects with a hard surface. Two important aspects of this new study are the ability to model the conditions that produce X-ray bursts and to count the neutron star bursts as a function of the amount of gas raining down on the surface."

Extensive computer modeling separates this analysis from similar comparisons in recent years. The model predictions computed for neutron stars roughly matched the measured burst rate function for the neutron star group. This increased the scientists' confidence that they have a reasonably good model for X-ray bursts, while decreasing the chance that more massive compact objects with a hypothetical hard surface can hide their bursts.

The Rossi Explorer, launched on December 30, 1995, is operated by NASA Goddard Space Flight Center in Greenbelt, Md.


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