Washington, February 11
In a landmark discovery for physics and astronomy, international scientists said today they have glimpsed the first direct evidence of gravitational waves, or ripples in space-time, which Albert Einstein predicted a century ago.
When two black holes collided 1.3 billion years ago, the joining of those two great masses sent forth a wobble that hurtled through space and arrived at Earth on September 14, 2015, when it was picked up by sophisticated instruments, researchers announced.
“Up until now we have been deaf to gravitational waves, but today, we are able to hear them,” said David Reitze, executive director of the LIGO Laboratory, at a press conference.
Reitze and colleagues compared the magnitude of the discovery to Galileo’s use of the telescope four centuries ago to open the era of modern astronomy. “I think we are doing something equally important here today. I think we are opening a window on the universe,” Reitze said.
The phenomenon was observed by two US-based underground detectors, designed to pick up tiny vibrations from passing gravitational waves, a project known as the Laser Interferometer Gravitational-wave Observatory (LIGO).
It took scientists months to verify their data and put it through a process of peer-review before announcing it today, marking the culmination of decades of efforts by teams around the world, including some 1,000 scientists from 16 countries, according to the National Science Foundation, which funded the research.
Gravitational waves are a measure of strain in space, an effect of the motion of large masses that stretches the fabric of space-time - a way of viewing space and time as a single, interweaved continuum.
They travel at the speed of light and cannot be stopped or blocked by anything.
As part of his theory of general relativity, Einstein said space-time could be compared to a net, bowing under the weight of an object. Gravitational waves would be like ripples that emanate from a pebble thrown in a pond.
While scientists have previously been able to calculate gravitational waves, they had never before seen one directly. According to the Massachusetts Institute of Technology's David Shoemaker, the leader of the Advanced LIGO team, it looked just like physicists thought it would.
“The waveform that we can calculate based on Einstein's theory of 1916 matches exactly what we observed in 2015,” he said. — AFP