Frequency evolution of pulsar emission: further evidence for the fan beam model
Frequency evolution of pulsar emission: further evidence for the fan beam model
Aims: we explore frequency-dependent changes in pulsar radio emission by analyzing their profile widths and emission heights, assessing whether the simple radius-to-frequency mapping (RFM) or the fan beam model can describe the data.
Methods: using wideband (704–4032 MHz) Murriyang (Parkes) observations of over 100 pulsars, we measured profile widths at multiple intensity levels, fit Gaussian components, and used aberration–retardation effects to estimate emission altitudes. We compared trends in width evolution and emission height with a fan beam model.
Results: similar to other recent studies, we find that while many pulsars show profiles narrowing with increasing frequency, a substantial fraction show the reverse. The Gaussian decomposition of the profiles reveals that the peak locations of the components vary little with frequency. However, the component widths do, in general, narrow with increasing frequency. This argues that propagation effects are responsible for the width evolution of the profiles rather than emission height. Overall, the evolution of the emission height with frequency is unclear and clouded by the assumptions in the model. Spin-down luminosity correlates weakly with profile narrowing but not with emission height.
Conclusions: the classic picture where pulsars emit at a single emission height that decreases with increasing observing frequency cannot explain the diversity in behavior observed here. Instead, pulsar beams likely originate from extended regions at multiple altitudes, with fan beam or patchy structures dominating their frequency evolution. Future models must incorporate realistic plasma physics and multi-altitude emission to capture the range of pulsar behaviors.
Jaroenjittichai, P.
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Johnston, S.
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Dai, S.
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Kerr, M.
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Lower, M.E.
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Manchester, R.N.
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Oswald, L.S.
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Shannon, R.M.
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Sobey, C.
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Weltevrede, P.
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12 December 2025
Jaroenjittichai, P.
b0d28666-dca9-4b57-8684-d817ca85f5f1
Johnston, S.
dbc5d9a1-3194-4f3e-b18d-5639c1f44397
Dai, S.
b6f71614-0285-42a6-9b04-3cc2c2d9f82a
Kerr, M.
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Lower, M.E.
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Manchester, R.N.
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Oswald, L.S.
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Shannon, R.M.
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Sobey, C.
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Weltevrede, P.
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Jaroenjittichai, P., Johnston, S., Dai, S., Kerr, M., Lower, M.E., Manchester, R.N., Oswald, L.S., Shannon, R.M., Sobey, C. and Weltevrede, P.
(2025)
Frequency evolution of pulsar emission: further evidence for the fan beam model.
Astronomy & Astrophysics, 704, [A214].
(doi:10.1051/0004-6361/202555535).
Abstract
Aims: we explore frequency-dependent changes in pulsar radio emission by analyzing their profile widths and emission heights, assessing whether the simple radius-to-frequency mapping (RFM) or the fan beam model can describe the data.
Methods: using wideband (704–4032 MHz) Murriyang (Parkes) observations of over 100 pulsars, we measured profile widths at multiple intensity levels, fit Gaussian components, and used aberration–retardation effects to estimate emission altitudes. We compared trends in width evolution and emission height with a fan beam model.
Results: similar to other recent studies, we find that while many pulsars show profiles narrowing with increasing frequency, a substantial fraction show the reverse. The Gaussian decomposition of the profiles reveals that the peak locations of the components vary little with frequency. However, the component widths do, in general, narrow with increasing frequency. This argues that propagation effects are responsible for the width evolution of the profiles rather than emission height. Overall, the evolution of the emission height with frequency is unclear and clouded by the assumptions in the model. Spin-down luminosity correlates weakly with profile narrowing but not with emission height.
Conclusions: the classic picture where pulsars emit at a single emission height that decreases with increasing observing frequency cannot explain the diversity in behavior observed here. Instead, pulsar beams likely originate from extended regions at multiple altitudes, with fan beam or patchy structures dominating their frequency evolution. Future models must incorporate realistic plasma physics and multi-altitude emission to capture the range of pulsar behaviors.
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Accepted/In Press date: 20 September 2025
e-pub ahead of print date: 12 December 2025
Published date: 12 December 2025
Identifiers
Local EPrints ID: 510168
URI: http://eprints.soton.ac.uk/id/eprint/510168
ISSN: 0004-6361
PURE UUID: 90b7de13-f56b-41f2-86cf-a711629dd9e3
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Date deposited: 19 Mar 2026 17:42
Last modified: 20 Mar 2026 03:11
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Contributors
Author:
P. Jaroenjittichai
Author:
S. Johnston
Author:
S. Dai
Author:
M. Kerr
Author:
M.E. Lower
Author:
R.N. Manchester
Author:
L.S. Oswald
Author:
R.M. Shannon
Author:
C. Sobey
Author:
P. Weltevrede
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