50 picoarcsec astrometry of pulsar emission

Ue Li Pen; Jean Pierre Macquart; Adam T. Deller; Walter Brisken

doi:10.1093/mnrasl/slu010

50 picoarcsec astrometry of pulsar emission

Ue Li Pen, Jean Pierre Macquart, Adam T. Deller, Walter Brisken

Physics and Astronomy (Twin Cities)

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Abstract

We use very long baseline interferometry (VLBI) imaging of the interstellar scattering speckle pattern associated with the pulsar PSR 0834+06 to measure the astrometric motion of its emission. The D ~ 5 au interstellar baselines, provided by interference between speckles spanning the scattering disc, enable us to detect motions with subnanoarcsecond accuracy. We measure a small pulse deflection of̃18±2 km(not including geometric uncertainties), which is 100 times smaller than the characteristic resolution (λ/D) of this interstellar interferometer. This implies that the emission region is small, and at an altitude of a few hundred km, with the exact value depending on field geometry. This is substantially closer to the star than to the light cylinder. Future VLBI measurements can improve on this finding. This new regime of ultraprecise astrometry may enable precision parallax distance determination of pulsar binary displacements.

Original language	English (US)
Pages (from-to)	L36-L40
Journal	Monthly Notices of the Royal Astronomical Society: Letters
Volume	440
Issue number	1
DOIs	https://doi.org/10.1093/mnrasl/slu010
State	Published - Feb 2014

Keywords

ISM: structure astrometry
Techniques: high angular resolution

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title = "50 picoarcsec astrometry of pulsar emission",

abstract = "We use very long baseline interferometry (VLBI) imaging of the interstellar scattering speckle pattern associated with the pulsar PSR 0834+06 to measure the astrometric motion of its emission. The D ~ 5 au interstellar baselines, provided by interference between speckles spanning the scattering disc, enable us to detect motions with subnanoarcsecond accuracy. We measure a small pulse deflection o{\~f}18±2 km(not including geometric uncertainties), which is 100 times smaller than the characteristic resolution (λ/D) of this interstellar interferometer. This implies that the emission region is small, and at an altitude of a few hundred km, with the exact value depending on field geometry. This is substantially closer to the star than to the light cylinder. Future VLBI measurements can improve on this finding. This new regime of ultraprecise astrometry may enable precision parallax distance determination of pulsar binary displacements.",

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AU - Macquart, Jean Pierre

AU - Deller, Adam T.

AU - Brisken, Walter

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AB - We use very long baseline interferometry (VLBI) imaging of the interstellar scattering speckle pattern associated with the pulsar PSR 0834+06 to measure the astrometric motion of its emission. The D ~ 5 au interstellar baselines, provided by interference between speckles spanning the scattering disc, enable us to detect motions with subnanoarcsecond accuracy. We measure a small pulse deflection of̃18±2 km(not including geometric uncertainties), which is 100 times smaller than the characteristic resolution (λ/D) of this interstellar interferometer. This implies that the emission region is small, and at an altitude of a few hundred km, with the exact value depending on field geometry. This is substantially closer to the star than to the light cylinder. Future VLBI measurements can improve on this finding. This new regime of ultraprecise astrometry may enable precision parallax distance determination of pulsar binary displacements.

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KW - Techniques: high angular resolution

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50 picoarcsec astrometry of pulsar emission

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Keywords

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