A search for fast pulsars in globular clusters

A search for fast pulsars in globular clusters

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Millisecond pulsars (MSP) are old neutron stars that have been spun up to high spin frequencies (as fast as 716 Hz) through the accretion of matter from a companion star. The extreme steller densities in the core of globular clusters creates numerous accreting neutron star systems through exchange i...

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Main Author: Bégin, Steve
Language:English
Published: 2010
Online Access:http://hdl.handle.net/2429/17874
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spelling ndltd-UBC-oai-circle.library.ubc.ca-2429-178742018-01-05T17:39:07Z A search for fast pulsars in globular clusters Bégin, Steve Millisecond pulsars (MSP) are old neutron stars that have been spun up to high spin frequencies (as fast as 716 Hz) through the accretion of matter from a companion star. The extreme steller densities in the core of globular clusters creates numerous accreting neutron star systems through exchange interactions: this leads to the formation of MSPs in larger numbers than the galactic disk. Over the course of this project, we have collected over 17 TB of data on the 3 globular clusters M28 NGC6440 and NGC6441 plus 2 observations on NGC6522 and NGC6624 as part of the recently begun S-band survey using the Green Bank telescope. I have analyzed and conducted acceleration searches on 70% of the data and discovered 7 of the 23 new millisecond pulsars reported in this work. One year of timing observations of the pulsars in M28 and NGC6440 has led to the phase connected solution for 12 of the 15 new pulsars in those two clusters, 7 of which are in binaries. We have measured the rate of advance of periastron for two highly eccentric binaries and assuming this is purely due to general relativity, this leads to total system masses of (1.616 ± 0.014)M [circle with central dot] and 2.2 ± 0.8)M [circle with central dot] for M28C and NGC6440B respectively. The small mass function combined with this information imply that the most likely neutron star mass of NGC6440B is either very large or else there could be significant contribution to the advance of periastron from a nonzero quadrupole moment due to tidal interaction with the companion. Measurements of the period derivatives for many of the pulsars show that they are dominated by the dynamical effect of the gravitational field of the clusters. Finally, we have discovered the potential presence of a Mars-mass planet orbiting the pulsar NGC6440C with a period of ~21 days. A dedicated timing campaign will be necessary to confirm the presence of such an object. Science, Faculty of Physics and Astronomy, Department of Graduate 2010-01-08T19:43:31Z 2010-01-08T19:43:31Z 2006 2006-11 Text Thesis/Dissertation http://hdl.handle.net/2429/17874 eng For non-commercial purposes only, such as research, private study and education. Additional conditions apply, see Terms of Use https://open.library.ubc.ca/terms_of_use.
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language English
sources NDLTD
description Millisecond pulsars (MSP) are old neutron stars that have been spun up to high spin frequencies (as fast as 716 Hz) through the accretion of matter from a companion star. The extreme steller densities in the core of globular clusters creates numerous accreting neutron star systems through exchange interactions: this leads to the formation of MSPs in larger numbers than the galactic disk. Over the course of this project, we have collected over 17 TB of data on the 3 globular clusters M28 NGC6440 and NGC6441 plus 2 observations on NGC6522 and NGC6624 as part of the recently begun S-band survey using the Green Bank telescope. I have analyzed and conducted acceleration searches on 70% of the data and discovered 7 of the 23 new millisecond pulsars reported in this work. One year of timing observations of the pulsars in M28 and NGC6440 has led to the phase connected solution for 12 of the 15 new pulsars in those two clusters, 7 of which are in binaries. We have measured the rate of advance of periastron for two highly eccentric binaries and assuming this is purely due to general relativity, this leads to total system masses of (1.616 ± 0.014)M [circle with central dot] and 2.2 ± 0.8)M [circle with central dot] for M28C and NGC6440B respectively. The small mass function combined with this information imply that the most likely neutron star mass of NGC6440B is either very large or else there could be significant contribution to the advance of periastron from a nonzero quadrupole moment due to tidal interaction with the companion. Measurements of the period derivatives for many of the pulsars show that they are dominated by the dynamical effect of the gravitational field of the clusters. Finally, we have discovered the potential presence of a Mars-mass planet orbiting the pulsar NGC6440C with a period of ~21 days. A dedicated timing campaign will be necessary to confirm the presence of such an object. === Science, Faculty of === Physics and Astronomy, Department of === Graduate
author Bégin, Steve
spellingShingle Bégin, Steve
A search for fast pulsars in globular clusters
author_facet Bégin, Steve
author_sort Bégin, Steve
title A search for fast pulsars in globular clusters
title_short A search for fast pulsars in globular clusters
title_full A search for fast pulsars in globular clusters
title_fullStr A search for fast pulsars in globular clusters
title_full_unstemmed A search for fast pulsars in globular clusters
title_sort search for fast pulsars in globular clusters
publishDate 2010
url http://hdl.handle.net/2429/17874
work_keys_str_mv AT beginsteve asearchforfastpulsarsinglobularclusters
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