Eccentric pulsar system challenges theories of binary formation

The discovery is reported today (May 15) in Science Express, the online site for the journal Science, by David Champion of the Australia Telescope.

The pair of objects is quirky in several ways, said Jim Cordes, professor of astronomy at Cornell and one of the paper's authors. The pulsar, JI903+0327, rotates once every 2.15 milliseconds, making it one of the faster-spinning among the known millisecond pulsars, or MSPs (pulsars that rotate once every 10 milliseconds or faster).

While about 50 MSPs have been identified in our galaxy, Cordes said, other MSPs in binary systems orbit in tight, precise circles. The JI903+0327 system's orbit, by contrast, is highly eccentric.

"These are [usually] the most perfect circles in the universe," said Cordes. "When we come across an object that has high eccentricity, it really stands out. We don't know of any other MSP like this."

The companion star itself is another anomaly: Apparently, it is a main sequence star (similar to our sun) rather than the more typical white dwarf or neutron star.

According to conventional scenarios for binary pulsar evolution, pulsars with slower spins are either isolated or, if in a binary, are likely to have been knocked into an eccentric orbit by the explosion of the supernova that created the pulsar. Faster spinning MSPs, on the other hand, have usually been "spun up" by momentum and matter accreted by their companion star's precursor -- and orbit in near-perfect circles.

Taken together, the newly discovered pulsar's fast spin, eccentric orbit and unusual companion require an alternate explanation -- possibly involving interaction with a third object or recent ejection from a globular cluster.

"In a globular cluster you've got all these other things happening -- collisions, other interactions … that provide numerous pathways for formation," Cordes said.

Meanwhile, the pulsar's high mass (1.74 solar masses) could help physicists better understand how matter behaves in extreme conditions.

Astronomers first detected the JI903+0327 in October 2005 as part of Arecibo's Pulsar ALFA (Arecibo L-band Feed Array) or PALFA Survey, an ongoing sky survey using ALFA -- a system of detectors with seven feeds that enables researchers to image large swaths of sky. Follow-up observations of the pulsar and its companion star used Arecibo, the Robert C. Byrd Green Bank Telescope in West Virginia, the Westerbork Synthesis Radio Telescope in the Netherlands and the Gemini North Observatory in Hilo, Hawaii.

All data for PALFA, which began in 2004 and is one of three ongoing sky surveys using the ALFA receiver, are archived and dispensed by the Cornell Center for Advanced Computing for the international PALFA Consortium, which is chaired by Cordes.

Source: Cornell University

Einstein was right: Unique stellar system provides 'laboratory' for testing relativity
Researchers at McGill University's Department of Physics – along with colleagues from several countries – have confirmed a long-held prediction of Albert Einstein's theory of general relativity, via observations of a binary-pulsar star system. Their results will be published July 3 in the journal Science.
Astronomers find first ever gamma ray clock
Astronomers using the H.E.S.S. telescopes have discovered the first ever modulated signal from space in Very High Energy Gamma Rays – the most energetic such signal ever observed.
'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.
Astronomers weigh 'recycled' millisecond pulsar
A team of U.S. and Australian astronomers is announcing today that they have, for the first time, precisely measured the mass of a millisecond pulsar -- a tiny, dead star spinning hundreds of times every second. This result is of special interest because it gives new insight into the production of millisecond pulsars and may shed light on the laws that govern nuclear matter.
Star eats companion
ESA's Integral space observatory, together with NASA's Rossi X-ray Timing Explorer spacecraft, has found a fast-spinning pulsar in the process of devouring its companion.
This finding supports the theory that the fastest-spinning isolated pulsars get that fast by cannibalising a nearby star. Gas ripped from the companion fuels the pulsar's acceleration. This is the sixth pulsar known in such an arrangement, and it represents a 'stepping stone' in the evolution of slower-spinning binary pulsars into faster-spinning isolated pulsars.
Gambling on Gravitational Waves
At the Institute of Physics conference Photon 04 today, Professor Jim Hough, one of the UK's leading scientists, revealed that he thinks high street bookmakers are crazy to be offering odds of 100-1 on whether Gravitational Waves (wrinkles in relativity) will be discovered before 2010. He has placed a personal bet of £25 – the maximum Ladbrokes allowed him to stake. The available odds were quickly cut from an initial offering of 500-1.
Strange star stumps astronomers
An obese oddball of a star has left astronomers wondering how it could have formed. Dr David Champion and his colleagues at CSIRO’s Australia Telescope National Facility publish their findings about the star today in the online journal, Science Express.
Neutron stars can be more massive, while black holes are more rare
Neutron stars and black holes aren’t all they’ve been thought to be. In fact, neutron stars can be considerably more massive than previously believed, and it is more difficult to form black holes, according to new research developed by using the Arecibo Observatory in Arecibo, Puerto Rico. Paulo Freire, an astronomer from the observatory, will present his research at the American Astronomical Society national meeting in Austin on Jan. 11.

Eccentric pulsar system challenges theories of binary formation

Related stories:

News discussion: