Researchers discover never-before-seen pulsar blasts in Crab Nebula

"We never see the strange frequency structure in the main pulse and we never see the really short blasts in the interpulse," said Tim Hankins, acting director of the Arecibo Observatory and a co-investigator on this research. "We fully expected the main pulse and interpulse to be spectrally identical, but what we found is that they are very different. This is the first time seeing this in a pulsar."

Hankins, who also is an emeritus professor of physics at New Mexico Tech in Socorro, N.M., will present a poster, "Radio Emission Signatures in the High Frequency Interpulse of the Crab Pulsar," which he made with Jean Eilek, New Mexico Tech professor of physics, on Jan. 8, 2007, at the American Astronomical Society (AAS) convention in Seattle.

"This is a cool result," said Eilek. "The fact that the 'left hand' and the 'right hand' of the pulsar – or the north and south magnetic poles – don't know what each other is doing, is very striking. It knocks just about every existing theory of pulsar radio emission for a loop."

Because pulses from north and south poles should be identical, Eilek thinks this strange radio emission might be coming from another part of the pulsar. She speculates: "Maybe we've discovered an unknown, unexpected 'third magnetic pole' somewhere else in the star."

Pulsars are important to understand as they allow physicists to confirm Albert Einstein's Theory of Relativity. The magnetic and electrical fields of pulsars are far stronger than any laboratory can generate, and Hankins admits this is a difficult physics problem to understand.

In the case of the Crab Nebula pulsar, located in the constellation Taurus, some 6,300 light years from Earth, the numbers boggle the mind: Plasma clouds in the pulsar's atmosphere send out the radio emission blasts in times as short as four-tenths of a nanosecond. This plasma cloud is smaller than a soccer ball. During their short lifetimes, their blasts of radio emission can be as powerful as 10 percent of the power of our sun

"These strange emission features are not showing up in other pulsars," says Eilek. The researchers have been using Arecibo on several observation occasions, between 2004 and the present. They last conducted observations in December 2006. "Maybe the magnetic field is not as simple as we think. Right now, we're totally perplexed," she said.

Source: Cornell University

Heart of the Crab Pulsar probed -- first direct look into the core of a neutron star
New information about the heart of one of the most famous objects in the sky -- the Crab Pulsar in the Crab Nebula -- has been revealed by an international team of scientists searching for gravitational waves. The team's achievement also is the first direct look into the interior of a neutron star.
Mysterious energy burst stuns astronomers
Astronomers studying archival data from an Australian radio telescope have discovered a powerful, short-lived burst of radio waves that they say indicates an entirely new type of astronomical phenomenon.
Brown Dwarfs Beaming Like Pulsars
Brown dwarfs, thought just a few years ago to be incapable of emitting any significant amounts of radio waves, have been discovered putting out extremely bright "lighthouse beams" of radio waves, much like pulsars. A team of astronomers made the discovery using the National Science Foundation's Very Large Array (VLA) radio telescope.
Astronomers find unexpected 'heartbeats' in star
Astronomers using CSIRO's Parkes telescope in eastern Australia have detected radio "heartbeats" from a star that was not expected to have them. A US-Australian research team found that a "magnetar" -- a kind of star with the strongest magnetic fields known in the Universe -- is giving off extraordinary radio pulses, which links this rare type of star with the much more common "radio pulsars."
Dizzy Little Green Man - XMM-Newton Reveals a Tumbling Pulsar
When the first pulsar was discovered, it was nicknamed LGM-1 or 'Little Green Man 1' because it was beaming such a regular signal into space. Now an international team of astronomers have discovered a pulsar that is tumbling through space in a fashion that would surely dizzy any Little Green Men unfortunate enough to be in the vicinity. Reporting their results in Astronomy & Astrophysics, the scientists explain how this unique object, called RX J0720.4-3125 can shed light on the mysteries of pulsars.
Did 'Dark Matter' Create the First Stars?
Dark matter may have played a major role in creating stars at the very beginnings of the universe. If that is the case, however, the dark matter must consist of particles called "sterile neutrinos". Peter Biermann of the Max Planck Institute for Radio Astronomy in Bonn, and Alexander Kusenko, of the University of California, Los Angeles, have shown that when sterile neutrinos decay, it speeds up the creation of molecular hydrogen. This process could have helped light up the first stars only some 20 to 100 million years after the Big Bang.
Part-time pulsar yields new insight into inner workings of cosmic clocks
Astronomers using the 76-m Lovell radio telescope at the University of Manchester's Jodrell Bank Observatory have discovered a very strange pulsar that helps explain how pulsars act as 'cosmic clocks' and confirms theories put forward 37 years ago to explain the way in which pulsars emit their regular beams of radio waves - considered to be one of the hardest problems in astrophysics.
'Deep impact' of pulsar around companion star
Astronomers have witnessed a never-seen-before event in observations by ESA's XMM-Newton spacecraft - a collision between a pulsar and a ring of gas around a neighbouring star.

Researchers discover never-before-seen pulsar blasts in Crab Nebula

Related stories:

News discussion: