Correlated emission and spin-down variability in radio pulsars

Benjamin Shaw; Benjamin W. Stappers; Paul R. Brook; Aris Karastergiou; Andrew G. Lyne; P. Weltevrede

doi:10.1017/S1743921317008742

Correlated emission and spin-down variability in radio pulsars

Benjamin Shaw, Benjamin W. Stappers, Paul R. Brook, Aris Karastergiou, Andrew G. Lyne, P. Weltevrede

Research output: Contribution to journal › Article › peer-review

Abstract

The recent revelation that there are correlated period derivative and pulse shape changes in pulsars has dramatically changed our understanding of timing noise as well as the relationship between the radio emission and the properties of the magnetosphere as a whole. Using Gaussian processes we are able to model timing and emission variability using a regression technique that imposes no functional form on the data. We revisit the pulsars first studied by Lyne et al. (2010). We not only confirm the emission and rotational transitions revealed therein, but reveal further transitions and periodicities in 8 years of extended monitoring. We also show that in many of these objects the pulse profile transitions between two well-defined shapes, coincident with changes to the period derivative. With a view to the SKA and other telescopes capable of higher cadence we also study the detection limitations of period derivative changes.

Original language	English
Pages (from-to)	58-61
Journal	Proceedings of the International Astronomical Union
Volume	13
Issue number	S337
Early online date	4 Jun 2018
DOIs	https://doi.org/10.1017/S1743921317008742
Publication status	Published - 2018

Access to Document

10.1017/S1743921317008742

Cite this

@article{ab6e79a94dca4c38951f8e4cbed5ca88,

title = "Correlated emission and spin-down variability in radio pulsars",

abstract = "The recent revelation that there are correlated period derivative and pulse shape changes in pulsars has dramatically changed our understanding of timing noise as well as the relationship between the radio emission and the properties of the magnetosphere as a whole. Using Gaussian processes we are able to model timing and emission variability using a regression technique that imposes no functional form on the data. We revisit the pulsars first studied by Lyne et al. (2010). We not only confirm the emission and rotational transitions revealed therein, but reveal further transitions and periodicities in 8 years of extended monitoring. We also show that in many of these objects the pulse profile transitions between two well-defined shapes, coincident with changes to the period derivative. With a view to the SKA and other telescopes capable of higher cadence we also study the detection limitations of period derivative changes.",

author = "Benjamin Shaw and Stappers, {Benjamin W.} and Brook, {Paul R.} and Aris Karastergiou and Lyne, {Andrew G.} and P. Weltevrede",

year = "2018",

doi = "10.1017/S1743921317008742",

language = "English",

volume = "13",

pages = "58--61",

journal = "Proceedings of the International Astronomical Union",

issn = "1743-9213",

publisher = "Cambridge University Press",

number = "S337",

}

TY - JOUR

T1 - Correlated emission and spin-down variability in radio pulsars

AU - Shaw, Benjamin

AU - Stappers, Benjamin W.

AU - Brook, Paul R.

AU - Karastergiou, Aris

AU - Lyne, Andrew G.

AU - Weltevrede, P.

PY - 2018

Y1 - 2018

N2 - The recent revelation that there are correlated period derivative and pulse shape changes in pulsars has dramatically changed our understanding of timing noise as well as the relationship between the radio emission and the properties of the magnetosphere as a whole. Using Gaussian processes we are able to model timing and emission variability using a regression technique that imposes no functional form on the data. We revisit the pulsars first studied by Lyne et al. (2010). We not only confirm the emission and rotational transitions revealed therein, but reveal further transitions and periodicities in 8 years of extended monitoring. We also show that in many of these objects the pulse profile transitions between two well-defined shapes, coincident with changes to the period derivative. With a view to the SKA and other telescopes capable of higher cadence we also study the detection limitations of period derivative changes.

AB - The recent revelation that there are correlated period derivative and pulse shape changes in pulsars has dramatically changed our understanding of timing noise as well as the relationship between the radio emission and the properties of the magnetosphere as a whole. Using Gaussian processes we are able to model timing and emission variability using a regression technique that imposes no functional form on the data. We revisit the pulsars first studied by Lyne et al. (2010). We not only confirm the emission and rotational transitions revealed therein, but reveal further transitions and periodicities in 8 years of extended monitoring. We also show that in many of these objects the pulse profile transitions between two well-defined shapes, coincident with changes to the period derivative. With a view to the SKA and other telescopes capable of higher cadence we also study the detection limitations of period derivative changes.

U2 - 10.1017/S1743921317008742

DO - 10.1017/S1743921317008742

M3 - Article

SN - 1743-9213

VL - 13

SP - 58

EP - 61

JO - Proceedings of the International Astronomical Union

JF - Proceedings of the International Astronomical Union

IS - S337

ER -

Correlated emission and spin-down variability in radio pulsars

Abstract

Access to Document

Fingerprint

Cite this