November 2, 2024

Brighton Journal

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Radio signal from deep space reaches Earth after 8 billion years

Radio signal from deep space reaches Earth after 8 billion years

Recently, astronomers made an amazing discovery – a mysterious and powerful radio wave has reached Earth after traveling through space for 8 billion years. Named FRB 20220610A, it is one of the most distant and energetic radio signals ever detected.

Fast radio bursts, including this one in particular, are extremely intense flashes of radio waves that last only a few milliseconds, yet their origins remain a source of great curiosity and mystery. We still don’t know what or who is sending these bursts of energy.

The nature of these signals challenges our understanding of the universe, because they may originate from regions far beyond the Milky Way, indicating processes and events that we are only beginning to understand.

Dr. Stuart Ryder, a distinguished astronomer at Macquarie University In Australia, he is part of a dedicated team of scientists working hard to unravel the mysteries surrounding this cosmic mystery.

Through advanced techniques and collaborative efforts, researchers aim to decipher the origins and effects of these fast radio bursts, which could open up new insights into the fundamental processes of our universe and the forces that shape it.

Understanding Fast Radio Bursts (FRBs)

Fast radio bursts, or FRBs, are intense flashes of radio waves that last only milliseconds. They were first discovered in 2007, and have since captured the curiosity and interest of the scientific community around the world.

For example, these recent fast radio bursts released as much energy as our Sun produces over 30 years—all in less than the blink of an eye.

Researchers believe these cosmic events may be linked to magnetars, high-energy remnants left behind by exploding stars.

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Astronomers have deployed the Australian Square Kilometre Pathfinder (SKP) array.Escape) to detect the explosion and trace its source.

“We used ASKAP radio dishes to pinpoint the source of the explosion,” says Dr. Ryder.

The discovery did not end there, as the team also identified the source galaxy using the European Southern Observatory. very large telescopeThey discovered that it is older and more distant than any other FRB source found so far.

Weighing the Universe Using FRBs

Believe it or not, these fleeting cosmic fireworks could help us “weigh” the universe. There’s a discrepancy between the amount of ordinary matter we can detect and what cosmologists assume exists. Could the answer lie beyond our visual range?

“More than half of the normal matter that should exist today is missing,” says Professor Ryan Shannon. He suggests that this “missing” matter may be hiding in the vast spaces between galaxies, where it is too hot and diffuse to be seen by conventional methods.

This is where fast radio bursts come in. Their unique ability to “sense” ionized matter in the nearly empty space of space allows scientists to measure the matter between galaxies.

This method, founded by the late Australian astronomer Jean-Pierre Macquart in 2020, is now known as the Macquart relation.

“This discovery confirms the Macquart relation, even for explosions that occurred half the distance of the known universe,” Ryder adds.

Nearly 50 FRBs have been traced back to their origins, and about half were discovered using the ASKAP telescope.

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Despite the unknown causes of these massive explosions, one thing is certain: these fast radio bursts are common events in the universe and have enormous potential to advance our understanding of the cosmos.

Professor Shannon believes that future radio telescopes, currently under construction, will detect thousands more FRBs.

“Fast radio bursts are common and hold great promise,” he says. “We can use them to create a new map of the structure of the universe and answer big questions about cosmology.”

The mystery of the missing matter

The universe is enormous, and much of it still puzzles us, especially the disparity between visible matter and theoretical matter.

This “missing matter” refers to a large amount of matter that is supposed to be present according to our current models of cosmic evolution but has not been seen.

Visible matter—such as stars, planets, and galaxies—turns out to make up only about 5 percent of the universe’s total mass and energy. The other 95 percent is thought to be dark matter and dark energy, which we can’t detect directly. This gap raises some big questions about the structure and behavior of the universe.

Researchers believe this missing matter may exist in forms that are difficult to detect, such as hydrogen gas floating in the intergalactic medium.

Recent studies using advanced telescopes have begun to find these mysterious hydrogen clouds, suggesting that a large portion of the universe’s matter may be hiding in this diffuse state.

Knowing what this missing matter is and where it is located is essential to getting a complete picture of cosmic evolution and adjusting our models of how the universe works.

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Fortunately, the discovery of these fast radio waves and their ability to track hidden matter could revolutionize our understanding of the universe. As Professor Shannon points out, even in nearly empty space, fast radio waves can “see” electrons and measure the matter present.

An exciting future for FRB research

With the advent of more advanced radio telescopes, the future of FRB research looks bright. Each new discovery brings us closer to unlocking the secrets of these powerful cosmic events.

Besides mapping the structure of the universe, fast radio bursts may guide us to fundamental questions about the inner workings of the cosmos — bringing us closer to the cosmic forces and events that shape our universe.

Despite our growing knowledge base, fast radio bursts remain one of the greatest mysteries of the universe. As researchers delve deeper into these cosmic flashes, one thing is becoming clear: we still know very little about the universe we live in.

The full study was published in the journal sciences.

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