- Management Update (October 12, 2020) by Director Eng. Francisco Cordova13 Oct, 2020
- Summer Student Assists in Development of Newest AO Facility01 Oct, 2020
- STAR Academy: Training the Next Generation of STEM Professionals 29 Sep, 2020
- Management Update (August 11, 2020) by Director Eng. Francisco Cordova29 Sep, 2020
- Management Update (August 28, 2020) by Director Eng. Francisco Cordova29 Sep, 2020
- Arecibo STAR Teachers29 Sep, 2020
- Hunting for the Mysterious Origins of Fast Radio Bursts28 Sep, 2020
- Girls Educating Girls 28 Sep, 2020
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- A Holistic Approach to Understanding Asteroids11 Sep, 2020
- Sharing the Connection: Arecibo’s Planetary Radar & NASA’s OSIRIS-REx Mission to Bennu10 Sep, 2020
- Analyzing Gravitational Fields Around Small Bodies in Support of Future Spacecraft Missions09 Sep, 2020
- Broken Cable Damages Arecibo Observatory11 Aug, 2020
- Open Position: Research Intern06 Aug, 2020
- Recorded Session: Arecibo Observatory Virtual Town Hall30 Jul, 2020
Byadmin13 July 2018 Astronomy
n international team of researchers today published findings from its six-year study in Nature.
The Arecibo Observatory helped scientists demonstrate that Einstein’s theory of relativity applies even to objects with extreme gravity, such as neutron stars.
“The high-quality data we have from Arecibo allowed us to divide the data up into subsections and compare them with each other, allowing us to resolve an apparent conflict with Einstein’s gravity.” - Dr. Anne Archibald
“Thanks to the power of Arecibo and in conjunction with the Westerbork Synthesis Radio Telescope here in the Netherlands and the Green Bank Telescope in West Virginia we were able to show that Einstein’s theory of relativity holds water even when it comes to neutron stars and dwarf stars,” said lead scientist Anne Archibald, a postdoctoral researcher of the University of Amsterdam and ASTRON at the Netherlands Institute for Radio Astronomy. A UCF-led team manages the Arecibo Observatory in Puerto Rico, home to one of the most powerful radio-radar telescopes in the world.
A key part of Einstein’s theory is that objects, regardless of their composition or mass, fall the same way. Just think of dropping a feather and a bowling ball from the same point. They both hit the ground at the same time. But some theories predict that when it comes to objects with extreme gravity, they will in fact fall differently. Archibald’s research indicates otherwise.
Archibald and her team observed a system of stars that had just the right extreme combination — the triple star system called PSR J0337+1715, located 4,200 light years from the Earth. In this unique system, a neutron star is in a 1.6-day orbit with a white dwarf, and this pair is in a 327-day orbit with another white dwarf farther away. If alternative theories of gravity were correct, then the neutron star and the inner white dwarf would fall differently towards the outer white dwarf.
“We were able to measure this by looking at the neutron star alone,” Archibald said. “The neutron star, a millisecond pulsar, behaves like a clock: it rotates 366 times per second, and beams of radio waves rotate along. They sweep over the earth at regular intervals, like a cosmic lighthouse. We have used these radio pulses to track the position of the neutron star.”
Arecibo played a central role, providing data that the team analyzed to reach its conclusion that Einstein’s theory holds, Archibald said. “The high-quality data we have from Arecibo allowed us to divide the data up into subsections and compare them with each other, allowing us to resolve an apparent conflict with Einstein’s gravity.” This powerful test of gravity is possible because PSR J0337+1715 is a natural laboratory. But there may be more remarkable millisecond pulsar systems waiting to be discovered, said co-author Jason Hessels, an associate professor at ASTRON and the University of Amsterdam.
“Among these yet undiscovered systems may lurk even more powerful tools for understanding the universe: unusual binaries, other triple star systems or a pulsar orbiting a black hole. Perhaps one of these may provide our first peek at a theory beyond Einstein’s,” Hessels said.
For now, Einstein’s theory stands. For more information about the study, check out today’s Nature online publication .
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Keywords: UCF, UMET, AO, Yang, Arecibo, Observatory, dwarf, Archibald, Einstein, PSR J0337+1715, Westerbork, Synthesis