Inastronomy,anintermediate polar(also called aDQ Herculis Star) is a type ofcataclysmic variable,binary starsystem with awhite dwarfand a coolmain-sequencesecondary star. In most cataclysmic variables, matter from the companion star is gravitationally stripped by the compact star and forms anaccretion diskaround it. In intermediate polar systems, the same general scenario applies except that the inner disk is disrupted by themagnetic fieldof the white dwarf.

Diagram of an intermediate polar. Matter flows from the companion star into anaccretion diskaround thewhite dwarf,but is disrupted by the white dwarf's magnetic field.

The name "intermediate polar" is derived from the strength of the white dwarf's magnetic field, which is between that of non-magnetic cataclysmic variable systems and strongly magnetic systems. Non-magnetic systems exhibit full accretion disks, while strongly magnetic systems (calledpolarsorAM Herculissystems) exhibit only accretion streams which directly impact the white dwarf's magnetosphere.

There were 26 confirmed intermediate polar systems as of 14 April 2006. This represents about 1% of the 1,830 total cataclysmic variable systems presented by Downes et al. (2006) in the Catalog of Cataclysmic Variables. Only two of them are brighter than 15thmagnitudeat minimum: the prototypeDQ Herculis,and the unusual slownova,GK Persei.[1]

System structure

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In intermediate polar systems, material stripped from ared dwarfsecondary star flows into an accretion disk around the white dwarf, but the inner disk is truncated by themagnetic fieldof the white dwarf. In extreme instances, the disk can be fully disrupted, although this is uncommon.[2]In the region where the disk is truncated, the gas in the disk begins to travel along the white dwarf's magnetic field lines, forming curved sheets of luminous material calledaccretion curtains.[3]Disk material passes through the curtains and then accretes onto the white dwarf near one of its magnetic poles.

Physical Properties

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Intermediate polar systems are strongx-rayemitters. The x-rays are generated by high velocity particles from the accretion stream forming ashockas they fall onto the surface of the white dwarf star. As particles decelerate and cool before hitting the white dwarf surface,bremsstrahlungx-rays are produced and may subsequently be absorbed by gas surrounding the shock region.

Themagnetic fieldstrength of white dwarfs in intermediate polar systems are typically 1 million to 10 million gauss (100–1000teslas). This is about a million times stronger than theEarth's magnetic fieldand towards the upper limit of magnetic field strengths that can be produced in a laboratory on Earth, but is much less than the magnetic field strength ofneutron stars.At the intersection of the accretion stream and the surface of the white dwarf, a hot spot is produced. Because the white dwarf has adipolemagnetic field, it will have one hot spot at each of its magnetic poles. As the white dwarf and its dipole magnetic field spin, the hot spots will spin also.

Other defining characteristics of intermediate polars include a strongHeliumIIemission lineat 468.6 nm andcircular polarization,in addition to the light curve periodicities described below.

Light curve periodicities

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Thelight curveof an intermediate polar may show several types of stable periodic changes in brightness. One periodicity is related to the orbital period of the binary star system. The orbital periods of confirmed intermediate polars range from 1.4 to 48 hours, with typical values between 3 and 6 hours.

A second periodic signal originates from the rotation of the white dwarf spinning on its axis. The observational characteristic that most clearly defines an intermediate polar is the existence of a spin period signal that is shorter than the orbital period. The known periods range from 33 to 4022 seconds. The physical cause of optical spin-period oscillations is usually attributed to the changing viewing aspect of the accretion curtain as it converges near the white dwarf.[4]

A third light curve periodicity, thesidebandperiod between the spin period and the orbital period, is also often present.

All three periodic signals may be measured by taking afourier transformof the light curve and producing apower spectrum.Intermediate polars produce spin and sideband periodicities in x-ray,ultraviolet,and optical wavelengths. Although the source of the periods in all three wavelengths is ultimately the white dwarf spin, the exact mechanisms for producing the high-energy periodicities and the optical periodicities are thought to be different.

In addition to the stable oscillations, unstable oscillations called "quasi-periodic oscillations" may appear and then die off after a few cycles.Quasi-periodic oscillationstypically have periods between 30 and 300 seconds.

References

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  1. ^"Catalog of Cataclysmic Variables".Retrieved2018-01-17.
  2. ^Buckley, D. A. H.; Sekiguchi, K.; Motch, C.; O'Donoghue, D.; Chen, A.-L.; Schwarzenberg-Czerny, A.; Pietsch, W.; Harrop-Allin, M. K. (1995-08-15)."RX J1712.6-2414: a polarized intermediate polar from the ROSAT Galactic Plane Survey".Monthly Notices of the Royal Astronomical Society.275(4): 1028–1048.Bibcode:1995MNRAS.275.1028B.doi:10.1093/mnras/275.4.1028.ISSN0035-8711.
  3. ^Patterson, Joseph (1994-03-01)."The DQ Herculis stars".Publications of the Astronomical Society of the Pacific.106(697): 209.Bibcode:1994PASP..106..209P.doi:10.1086/133375.ISSN1538-3873.
  4. ^Hellier, C.; Mason, K. O.; Rosen, S. R.; Cordova, F. A. (1987-09-01)."Time resolved optical spectroscopy of the eclipsing intermediate polar EX Hydrae".Monthly Notices of the Royal Astronomical Society.228(2): 463–481.Bibcode:1987MNRAS.228..463H.doi:10.1093/mnras/228.2.463.ISSN0035-8711.
  • Coel Hellier (2001).Cataclysmic Variable Stars: How and Why They Vary.Springer Praxis.ISBN978-1-85233-211-2.
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