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- Active Mercury(07/09)
- Hubble Status Report: Directly Observes a Planet Orbiting Another Star(01/09)
- A Non-trivial Answer to a Trivial Astronomical Question-The Origin Of Absolute Magnitude(07/08)
- Assault by a Black Hole(04/08)
- New Lakes Discovered on Titan(01/08)
- “Deviant Behaviour” in the Solar System(10/07)
- Cosmic Ripples - Cosmic Microwave Background - CMB(07/07)
- Interplanetary Superhighway(04/07)
- Is Pluto a Planet?(01/07)
- Breathing Moonrocks(10/06)
- My Thoughts on the Theory of Relativity, Quantum Mechanics, Superstring Theory and Dark Matter(07/06)
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- Neutrino Astronomy(10/05)
- The Active Earth(07/05)
- What is Dark Energy?(04/05)
- The Mysterious Black Holes(01/05)
- Intermediate-Mass Black Holes And Quasisoft X-Ray Sources(10/04)
- Time Travel: From a Scientific Approach(07/04)
- What is Astrobiology?(04/04)
- Black Hole: From Fantasy To Reality (II)(01/04)
- Black Hole: From Fantasy To Reality (I)(10/03)
- From The Oldest Light In The Universe To The Fate Of The Universe(7/03)
- The Cosmic HERO(4/03)
- Quaoar - the Tenth Member of the Solar System?(1/03)
- The First Chinese Telescope in Space(10/02)
- Diamonds and Other Stardust(7/02)
- Supermassive Black Hole in Andromeda Galaxy(4/02)
- Detection of Solar Neutrinos(1/02)
- Simultaneous Multiple Wavwlength Observation(10/01)
- Celestial Distance(7/01)
- Solar-Terrestrial Relations(7/00)
- Fundamental Particles in Astronomy(4/00)
- The Solar Maximum in 2000(1/00)
- Hubble Constant(10/99)
- New Findings on Cosmology(7/99)
- Strange Stars(4/99)
- How Strong Stellar Magnetic Field Can Be?(1/99)

Important notices

Frequent Space Museum visitors should know that neutron star is one of the possible final products of stellar evolution. These visitors may have also heard of a number of extreme conditions on a neutron star: its density is about the same as an atomic nucleus, and its diameter is not bigger than that of Hong Kong. Moreover, neutron stars have a huge magnetic field ranging from about 108 to 1012G. (As a comparison, the magnetic field on Earth is about 1G, and artificial magnetic fields created in laboratories seldom exceed 106G.) In fact, neutron star magnetic field is the strongest amongst all stars we know of to date. Moreover, most astronomers believed in the above magnetic field figures for neutron stars until recently.

In May 1998, Kouveliotou et al. reported the discovery of a very special neutron star SGR1806-20. This star emits X-ray pulses with a period of 7.47 s. From time to time, outbursts of low energy gamma-rays are also observed. Hence, observational astronomers sometimes call this type of stars "soft gamma ray repeaters". The periodic pulsation and low energy gamma-ray outbursts are two typical characteristics of a young energetic neutron stars. Most importantly, they observed that the rotational speed of this star slows down at a rate of 2.6 x10-3 s/yr. Since the stronger the magnetic field, the faster the slow down rate an object will be. Thus, they can use the slow rate rate data to infer the magnetic field strength of SGR1806-20. Quite surprisingly, the answer they found is 8 x 1014 G, some 80 times higher than all other known neutron stars! We now call this kind of super-strong magnetic field neutron stars magnetar, a term coined a few years ago by two theoretical astrophysicists Duncan and Thompson. (As expected, the work of Duncan and Thompson did not receive much attention in the astronomy community until Kouveliotou et al.'s discovery.)

With such a high magnetic field, magnetar slows down very rapidly. Therefore soon after their supernova birth, their rotational speed will become so low that they stop to emit electromagnetic pulses. In other words, astronomers can only detect those extremely young energetic magnetars before they stop emittng electromagnetic pulses. Consequently, it is extremely hard for us to find them in the sky. In this respect, we are very lucky to find one (and still the only one at this moment) - SGR1806-20 - in the sky.

Owing to its super-strong magnetic field, calculating various properties of magnetars are hard problems for astronomers. To give readers an example: the electron cloud of a hydrogen atom on Earth is essentially distributed spherically around the hydrogen nucleus. But interesting things occur when we place a hydrogen atom in a strong magnetic field of 8 x 1014 G. The magnetic field greatly distorts the electron cloud in such a way that the electron cloud looks like a cylinder instead of a sphere. The axis of this cylinder is parallel to the strong magnetic field. Consequently, heat conduction along the magnetic field lines on the surface of a magnetar is far more efficient than the heat conduction perpendicular to the magnetic field lines. This may lead to a profound effect on the thermal evolution as well as the shape of the X-ray pulse of a magnetar. Many of us are trying to predict their properties at this moment.

Related Links
'Magnetars', Soft Gamma Repeaters & Very Strong Magnetic Fields, Robert C. Duncan

Photo courtesy:NASA