Magnetospheric origin of a fast radio burst constrained using scintillation

Nimmo, Kenzie; Pleunis, Ziggy; Beniamini, Paz; Kumar, Pawan; Lanman, Adam E.; Li, D. Z.; Main, Robert; Sammons, Mawson W.; Andrew, Shion; Bhardwaj, Mohit; Chatterjee, Shami; Curtin, Alice P.; Fonseca, Emmanuel; Gaensler, B. M.; Joseph, Ronniy C.; Kader, Zarif; Kaspi, Victoria M.; Lazda, Mattias; Leung, Calvin; Masui, Kiyoshi W.; Mckinven, Ryan; Michilli, Daniele; Pandhi, Ayush; Pearlman, Aaron B.; Rafiei-Ravandi, Masoud; Sand, Ketan R.; Shin, Kaitlyn; Smith, Kendrick; Stairs, Ingrid H.

Magnetospheric origin of a fast radio burst constrained using scintillation

Kenzie Nimmo (), Ziggy Pleunis, Paz Beniamini, Pawan Kumar, Adam E. Lanman, D. Z. Li, Robert Main, Mawson W. Sammons, Shion Andrew, Mohit Bhardwaj, Shami Chatterjee, Alice P. Curtin, Emmanuel Fonseca, B. M. Gaensler, Ronniy C. Joseph, Zarif Kader, Victoria M. Kaspi, Mattias Lazda, Calvin Leung, Kiyoshi W. Masui, Ryan Mckinven, Daniele Michilli, Ayush Pandhi, Aaron B. Pearlman, Masoud Rafiei-Ravandi, Ketan R. Sand, Kaitlyn Shin, Kendrick Smith and Ingrid H. Stairs
Additional contact information
Kenzie Nimmo: Massachusetts Institute of Technology
Ziggy Pleunis: University of Toronto
Paz Beniamini: The Open University of Israel
Pawan Kumar: University of Texas at Austin
Adam E. Lanman: Massachusetts Institute of Technology
D. Z. Li: Princeton University
Robert Main: McGill University
Mawson W. Sammons: McGill University
Shion Andrew: Massachusetts Institute of Technology
Mohit Bhardwaj: Carnegie Mellon University
Shami Chatterjee: Cornell University
Alice P. Curtin: McGill University
Emmanuel Fonseca: West Virginia University
B. M. Gaensler: University of Toronto
Ronniy C. Joseph: McGill University
Zarif Kader: McGill University
Victoria M. Kaspi: McGill University
Mattias Lazda: University of Toronto
Calvin Leung: University of California Berkeley
Kiyoshi W. Masui: Massachusetts Institute of Technology
Ryan Mckinven: McGill University
Daniele Michilli: Massachusetts Institute of Technology
Ayush Pandhi: University of Toronto
Aaron B. Pearlman: McGill University
Masoud Rafiei-Ravandi: McGill University
Ketan R. Sand: McGill University
Kaitlyn Shin: Massachusetts Institute of Technology
Kendrick Smith: Perimeter Institute for Theoretical Physics
Ingrid H. Stairs: University of British Columbia

Nature, 2025, vol. 637, issue 8044, 48-51

Abstract: Abstract Fast radio bursts (FRBs) are microsecond-to-millisecond-duration radio transients1 that originate mostly from extragalactic distances. The FRB emission mechanism remains debated, with two main competing classes of models: physical processes that occur within close proximity to a central engine2–4; and relativistic shocks that propagate out to large radial distances5–8. The expected emission-region sizes are notably different between these two types of models9. Here we present the measurement of two mutually coherent scintillation scales in the frequency spectrum of FRB 20221022A10: one originating from a scattering screen located within the Milky Way, and the second originating from its host galaxy or local environment. We use the scattering media as an astrophysical lens to constrain the size of the observed FRB lateral emission region9 to ≲3 × 104 kilometres. This emission size is inconsistent with the expectation for the large-radial-distance models5–8, and is more naturally explained by an emission process that operates within or just beyond the magnetosphere of a central compact object. Recently, FRB 20221022A was found to exhibit an S-shaped polarization angle swing10, most likely originating from a magnetospheric emission process. The scintillation results presented in this work independently support this conclusion, while highlighting scintillation as a useful tool in our understanding of FRB emission physics and progenitors.

Date: 2025
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DOI: 10.1038/s41586-024-08297-w

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