In a remarkable breakthrough, astronomers have, for the first time, detected the faint whispers of low-frequency gravitational waves.
This cosmic hum, an echo of events occurring shortly after the Big Bang, reverberates across the universe, now perceived by humanity for the first time. The discovery is a result of almost a decade's worth of research in the quest for the elusive gravitational wave background.
Scientists globally revealed on June 28 that the Milky Way’s galaxy-sized antenna, composed of millisecond pulsars, has picked up a unique "low pitch hum".
This detection supports the compelling evidence of gravitational waves that theoretical physics predicted. The signal corresponds with the expected emanations from colossal black hole pairs, each as massive as billions of suns.
These gravitational waves may originate from the fusion of supermassive black holes, entwined in a slow cosmic waltz. As these colossal entities circle each other, they release energy in the form of gravitational waves.
These waves, now perceivable to us, resonate throughout the universe. Their detection provides persuasive evidence that numerous supermassive black holes could be on the verge of merging in the future.
In their quest to uncover the gravitational wave background, astronomers turned to millisecond pulsars, the rapidly spinning remnants of dead stars.
These 'cosmic lighthouses' rotate up to 700 times per second, casting out beams of light. The pulsating light offers vital clues to detect gravitational waves from colossal black holes, millions to billions of times the size of our sun.
Gravitational waves alter the space-time fabric between us and the pulsars, causing distortions in their otherwise meticulously regular pulses. The result is the pulses' arrival on Earth earlier or later than expected.
This unique pattern, detected from nearly 70 millisecond pulsars in the Milky Way, was the key evidence for the existence of gravitational waves.
Scientists extracted these patterns by observing beams from pairs of pulsars using a variety of radio telescopes. They documented the timing of these pulses for 15 years, resulting in the groundbreaking discovery of gravitational wave signals, etched into the inconsistencies of the pulsar light pulses.
This marked the first compelling evidence for such a phenomenon, which was predicted by Einstein's theory of general relativity back in 1916.
The "final parsec problem", the question of how black holes shrink their orbit and merge, has been a long-standing puzzle in the world of astrophysics.
This discovery, however, hints that these binary black holes may have found a way to overcome this barrier. If proven correct, this signals a significant milestone in our understanding of the universe, unveiling the secrets hidden in the cosmic hum of low-frequency gravitational waves.
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