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New technique improves estimates of pulsar ages

To improve the accuracy of the standard technique, astronomers incorporated additional constraints that arise from the spin-up process and physical limits on the maximum spin period.
Provided by the American Astronomical Society, Washington, D.C.
Pulsar Illustration
Pulsars are spinning neutron stars. As the star's magnetic pole sweeps past Earth, it beams radio emission at terrestrial observers.
NRAO
June 9, 2009
Astronomers at the University of California, Santa Cruz (UCSC), have developed a new technique to determine the ages of millisecond pulsars, the fastest-spinning stars in the universe.

"The standard method for estimating pulsar ages yields unreliable results, especially for the fast-spinning millisecond pulsars," said Bulent Kiziltan, a graduate student in astronomy and astrophysics at UCSC.

"An accurate determination of pulsar ages is of fundamental importance, because it has ramifications for understanding the formation and evolution of pulsars, the physics of neutron stars, and other areas," he said.

Kiziltan has been working with Stephen Thorsett, professor of astronomy and astrophysics at UCSC, to study the evolution of millisecond pulsars.

A pulsar is a rapidly rotating neutron star - the collapsed core that remains after a massive star explodes as a supernova. The pulsar emits beams of radio waves (as well as x rays and gamma rays) from the magnetic poles of the neutron star. Because the magnetic poles are not aligned with the star's spin axis, the beams sweep around like a lighthouse beacon, sending pulses of radio waves toward observers on Earth. The period between each pulse of radio waves corresponds to the rotation rate of the neutron star.

"In most cases, the only information we have is the radio pulse we receive from these compact stars," Kiziltan said. "From these pulses we are trying to determine the ages, masses, and orbital parameters."

Ordinary pulsars tend to rotate a few times per second, and they gradually slow down with age, eventually becoming too faint to detect. Millisecond pulsars, however, rotate hundreds of times per second. They achieve these extraordinary spin rates by pulling in material from a binary companion star, a process that transfers angular momentum from the companion to the pulsar.

"This spin-up process is essentially like giving CPR to a dead or dying pulsar, giving it a second lease on life," Kiziltan said.

The standard approach to determine the "characteristic" or "spin-down" age of a pulsar is based on two parameters: the period between pulses and the rate at which they slow down. Kiziltan and Thorsett showed that this method may overestimate or underestimate the age of a pulsar by a factor of 10 when applied to millisecond pulsars.

To improve the accuracy of the standard technique, they incorporated additional constraints that arise from the spin-up process and physical limits on the maximum spin period. "We modified the age calculations to be consistent with these constraints and showed that this approach can achieve estimates closer to the true age of the pulsar," Kiziltan said.

They show that, in some cases, millisecond pulsars that appear to be young can be several billion years older. In other cases, young millisecond pulsars may mimic the characteristics of pulsars that are as old as the galaxy itself.
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